UNITED STATES
SECURITIES AND EXCHANGE COMMISSION
Washington, D.C. 20549
FORM 8-K
CURRENT REPORT
Pursuant to Section 13 OR 15(d)
of The Securities Exchange Act of 1934
Date of Report (Date of earliest event reported): August 8, 2023
(Exact name of registrant as specified in its charter)
| (State or other jurisdiction of incorporation) | (Commission File Number) | (I.R.S. Employer Identification No.) | ||||||||||||
(Address of principal executive offices) (Zip code)
(385 ) 269 - 0203
(Registrant’s telephone number, including area code)
Not Applicable
(Former name or former address, if changed since last report.)
Check the appropriate box below if the Form 8-K filing is intended to simultaneously satisfy the filing obligation of the registrant under any of the following provisions:
Securities registered pursuant to Section 12(b) of the Act:
| Title of each class | Trading symbol(s) | Name of each exchange on which registered | ||||||
Indicate by check mark whether the registrant is an emerging growth company as defined in Rule 405 of the Securities Act of 1933 or (§230.405 of this chapter) or Rule 12b-2 of the Securities Exchange Act of 1934 (§240.12b-2 of this chapter).
Emerging growth company ☐
If an emerging growth company, indicate by check mark if the registrant has elected not to use the extended transition period for complying with any new or revised financial accounting standards provided pursuant to Section 13(a) of the Exchange Act. ☐
Item 2.02. Results of Operations and Financial Condition.
On August 8, 2023, Recursion Pharmaceuticals, Inc. (the Company) issued a press release announcing its results of operations and financial condition for the second quarter June 30, 2023. A copy of the press release is furnished as Exhibit 99.1 and is incorporated herein by reference.
Item 7.01. Regulation FD Disclosure.
On August 8, 2023, the Company issued a press release announcing it has successfully predicted the protein target(s) for approximately 36 billion chemical compounds in the Enamine REAL Space chemical library. The press release is attached as Exhibit 99.2 to this Current Report on Form 8-K and incorporated into this Item 7.01 by reference.
Also on August 8, 2023, the Company released an updated investor presentation. The investor presentation will be used from time to time in meetings with investors. A copy of the presentation is attached hereto as Exhibit 99.3.
The information furnished pursuant to Item 2.02 (including Exhibit 99.1) and 7.01 (including Exhibits 99.2 and 99.3) on this Form 8-K, shall not be deemed “filed” for purposes of Section 18 of the Securities Exchange Act of 1934, as amended (the “Exchange Act”), or otherwise subject to the liabilities of that section, nor shall it be deemed incorporated by reference into any other filing under the Securities Act of 1933, as amended, or the Exchange Act, except as expressly set forth by specific reference in such a filing.
Item 9.01. Financial Statements and Exhibits.
(d) Exhibits.
| Exhibit Number | Description | ||||
| 99.1 | |||||
| 99.2 | |||||
| 99.3 | |||||
| 104 | Cover Page Interactive Data File (embedded within the Inline XBRL document) | ||||
SIGNATURES
Pursuant to the requirements of the Securities Exchange Act of 1934, the registrant has duly caused this report to be signed on its behalf by the undersigned hereunto duly authorized on August 8, 2023.
| RECURSION PHARMACEUTICALS, INC. | ||||||||
| By: | /s/ Michael Secora | |||||||
Michael Secora | ||||||||
Chief Financial Officer | ||||||||
Exhibit 99.1
Recursion Provides Business Updates and Reports Second Quarter 2023 Financial Results
•Deployed new digital chemistry technology, together with NVIDIA, to predict the ligand-protein interactions for approximately 36 billion compounds in the Enamine REAL Space, reported to be the world's largest searchable chemical library
•Added, accelerated or tightened guidance for clinical study readouts or clinical starts; the first clinical readout is expected in Q3 2023
•Delivered value in our pipeline, partnerships and platform through the acquisitions of Cyclica and Valence Discovery
•Announced a $50 million investment and partnership with NVIDIA to accelerate the construction, optimization and deployment of foundation models for biology and chemistry
•Continued advancing large-scale foundation models for drug discovery with our partners at NVIDIA
SALT LAKE CITY, August 8, 2023 — Recursion (Nasdaq: RXRX), a leading clinical stage TechBio company decoding biology to industrialize drug discovery, today reported business updates and financial results for its second quarter ending June 30, 2023.
“As the world continues to undergo a revolution in artificial intelligence and computation, Recursion is leading the TechBio sector with one of the most advanced technology-enabled drug discovery platforms in the industry," said Chris Gibson, Ph.D., Co-Founder and CEO of Recursion. "Our recent acquisitions of Cyclica and Valence and our new partnership with NVIDIA bring industry-leading capabilities to our platform that have already delivered significant value across our pipeline and partnerships. With multiple clinical catalysts in the coming quarters, the extraordinary progress in our technology, and the commitment of our teams, Recursion is making its vision of industrialized drug discovery real day by day.”
Summary of Business Highlights
•Pipeline
◦Cerebral Cavernous Malformation (CCM) (REC-994): Our Phase 2 SYCAMORE clinical trial is a double-blind, placebo-controlled safety, tolerability and exploratory efficacy study of this drug candidate in participants with CCM.
This study was fully enrolled as of June 2023 with 62 participants and all participants who have thus far finished their first year of treatment have enrolled in the long-term extension study. We expect to share Phase 2 proof-of-concept data in H2 2024.
◦Neurofibromatosis Type 2 (NF2) (REC-2282): Our Phase 2/3 POPLAR clinical trial is a two part study of REC-2282 in participants with progressive NF2-mutated meningiomas. Part A of the study is ongoing and is exploring two doses of REC-2282 in approximately 23 adults and 9 adolescents.We expect to share Phase 2 safety, tolerability, pharmacokinetics and preliminary efficacy in H2 2024.
◦Familial Adenomatous Polyposis (FAP) (REC-4881): We have enrolled multiple participants in our TUPELO clinical trial which evaluates REC-4881 in patients with FAP. We are now providing guidance on a data readout and expect to share Phase 2 safety, tolerability, pharmacokinetics and preliminary efficacy in H1 2025.
◦AXIN1 or APC Mutant Cancers (REC-4881): We will evaluate REC-4881 in a Phase 2 biomarker enriched study in patients with unresectable, locally advanced or metastatic cancer with AXIN1 or APC mutations. The IND was accepted by the FDA and we expect to initiate this Phase 2 study in Q4 2023.
◦Clostridioides difficile Infection (REC-3964): Our Phase 1 clinical trial is a first-in-human protocol evaluating single and multiple doses of REC-3964 in healthy volunteers and will assess the safety, tolerability and pharmacokinetic profile of REC-3964. Single ascending dose and multiple ascending dose studies are now complete. REC-3964 has been well tolerated and no safety issues have been identified to date. We expect to share Phase 1 safety and pharmacokinetics data in Q3 2023.
◦RBM39 HR-Proficient Ovarian Cancer: RBM39 (previously identified as Target Gamma) is a novel CDK12-adjacent target identified by the Recursion OS. We believe we can modulate this target to produce a therapeutic effect in HR-proficient ovarian cancer and potentially in other tumor types. This program is in the preclinical stage and IND-enabling studies are progressing.
•Partnerships
◦NVIDIA: In July 2023, we announced a $50 million investment and collaboration with NVIDIA. We will continue to build our own foundation models for biology and chemistry and NVIDIA will assist in optimizing these models, provide priority access to computational resources on NVIDIA’s cloud service DGX Cloud, and potentially host commercially-licensable machine learning and foundation models developed by Recursion on BioNeMo, NVIDIA’s marketplace for generative AI in drug discovery. In this partnership, we will maintain control of our proprietary data and models as well as how and where we could host our technology tools as we expand our business strategy of data as a value driver. Since the announcement in July, we have already deployed our digital chemistry technology together with NVIDIA's computational resources to predict the ligand-protein interactions for approximately 36 billion compounds in the Enamine REAL Space, reported to be the world’s largest searchable chemical library, where we evaluated 2.8 quadrillion target-compound pairs.
◦Roche-Genentech and Bayer: We continue to advance our collaborations to discover potential new therapeutics with our strategic partners Roche-Genentech and Bayer. In the near-term, there is the potential for option exercises associated with partnership programs or option exercises associated with map building initiatives or data sharing.
•Platform
◦Digital Chemistry and Generative AI Capabilities: In May 2023, we acquired Cyclica and Valence Discovery to bolster our digital chemistry and generative AI capabilities and drive value across our pipeline, partnerships, and platform. Shortly after closing these acquisitions, we used Cyclica’s digital chemistry tools to predict the protein-ligand interactions for the over 1 million compounds in our internal, non-partnered chemical library. Now, less than one quarter after the closing of these acquisitions, we worked with our partners at NVIDIA to predict the protein-ligand interactions of approximately 36 billion compounds in the Enamine REAL Space, reported to be the world’s largest searchable chemical library.
◦Accelerating Pipeline and Partnership Value: For our internal pipeline, we have used our digital chemistry tools to deconvolve proteome-wide biological targets to confirm that certain compounds operate through a novel mechanism of action which was previously predicted by our functional phenomics maps. Such proteomic mapping capabilities provide an additional data layer to efficiently identify the most promising novel chemical series.
◦Foundation Model Construction: We continue to use our supercomputer, BioHive-1, to train a proprietary phenomics foundation model. As we have trained on larger quantities of our proprietary data, emergent properties have arisen out of the models and we have seen significant improvements over previous deep learning production models. We are also in the early stages of exploring more powerful and broadly useful foundation models based on our large-scale proprietary multi-omics data, which includes phenomics across 50 human cell types and approximately 1.7 million compounds, multi-timepoint live-cell microscopy, transcriptomics, proteomics, inVivomics, multi-target compound interactions, physicochemical properties, as well as predicted protein-ligand relationships. We may explore commercial licensing of some of our models in collaboration with NVIDIA and their BioNeMo platform in the coming year, though our state-of-the-art models will only be available to our team and close partners.
◦Large Language Models: One year ago, more than 40 employees were dedicated to exploring our maps of biology and chemistry to initiate programs at Recursion. Today, those same employees have been redeployed and our newest internal programs are being initiated autonomously. This efficiency and scale is through the deployment of large language models to map scientific literature in conjunction with our internally derived proprietary maps to identify opportunities for scientific arbitrage in areas of unmet need. These opportunities are then automatically prioritized for confirmation and validation in our highly-automated wetlabs. This is a significant step towards our vision of autonomous drug discovery and biological exploration.
◦Valence Labs - Powered by Recursion: In July 2023 at the International Conference for Machine Learning, we launched Valence Labs, Recursion’s cutting-edge machine learning research center for biology and chemistry in Montréal that aims to promote open-science and academic research. Recursion’s
commitment to open-science helps us recruit and retain the best talent in the field of generative AI, allows us to design and set the standards by which ML and AI are deployed in drug discovery, and may drive additional biopharma companies to consider partnering with Recursion to get access to our proprietary state-of-the-art tools, technology, datasets and programs.
Additional Corporate Updates
•Chief Medical Officer: In May 2023, David Mauro, M.D., Ph.D. joined Recursion as its Chief Medical Officer. Dr. Mauro has over 20 years experience in oncology drug development and has guided more than 25 Investigational New Drug candidates through the translational, preliminary and later stages of development at various companies.
•Chief Legal Officer: In July 2023, Recursion named Nathan Hatfield, J.D., M.B.A. as Chief Legal Officer. Mr. Hatfield has worked at Recursion for over 6 years, previously serving as SVP and Head of Legal. Prior to Recursion, Mr. Hatfield was a securities attorney at the law firm Wilson Sonsini Goodrich & Rosati.
•Toronto Office: In June 2023, we celebrated the opening of our Canadian Headquarters in Toronto with government officials as well as members of the technology and biotechnology communities.
•ESG Reporting: In June 2023, Recursion received a favorable ESG Risk Rating from Morningstar Sustainalytics which ranked Recursion as the #1 biotechnology company out of approximately 400 companies and the #14 pharmaceuticals company out of approximately 900 companies.
Second Quarter 2023 Financial Results
•Cash Position: Cash and cash equivalents were $405.9 million as of June 30, 2023. This cash position does not include the recent $50 million investment from NVIDIA.
•Revenue: Total revenue was $11.0 million for the second quarter of 2023, compared to $7.7 million for the second quarter of 2022. The increase was due to progress made in our Roche-Genentech collaboration.
•Research and Development Expenses: Research and development expenses were $55.1 million for the second quarter of 2023, compared to $38.4 million for the second quarter of 2022. The increase in research and development expenses was due to increased platform costs as we have expanded and upgraded our capabilities.
•General and Administrative Expenses: General and administrative expenses were $28.3 million for the second quarter of 2023, compared to $21.2 million for the second quarter of 2022. The increase in general and administrative expenses was due to an increase in salaries and wages of $3.0 million and increases in software and depreciation expense.
•Net Loss: Net loss was $76.7 million for the second quarter of 2023, compared to a net loss of $65.6 million for the second quarter of 2022.
About Recursion
Recursion is a clinical stage TechBio company leading the space by decoding biology to industrialize drug discovery. Enabling its mission is the Recursion OS, a platform built across diverse technologies that continuously expands one of the world’s largest proprietary biological and chemical datasets. Recursion leverages sophisticated machine-learning algorithms to distill from its dataset a collection of trillions of searchable relationships across biology and chemistry unconstrained by human bias. By commanding massive experimental scale — up to millions of
wet lab experiments weekly — and massive computational scale — owning and operating one of the most powerful supercomputers in the world, Recursion is uniting technology, biology and chemistry to advance the future of medicine.
Recursion is headquartered in Salt Lake City, where it is a founding member of BioHive, the Utah life sciences industry collective. Recursion also has offices in Toronto, Montréal and the San Francisco Bay Area. Learn more at www.Recursion.com, or connect on Twitter and LinkedIn.
Media Contact
Media@Recursion.com
Investor Contact
Investor@Recursion.com
Recursion Pharmaceuticals, Inc.
Condensed Consolidated Statements of Operations (unaudited)
(in thousands, except share and per share amounts)
| Three months ended June 30, | Six months ended June 30, | |||||||||||||||||||
| 2023 | 2022 | 2023 | 2022 | |||||||||||||||||
| Revenue | ||||||||||||||||||||
| Operating revenue | $ | 11,016 | $ | 7,653 | $ | 23,150 | $ | 12,952 | ||||||||||||
| Grant revenue | 1 | 21 | 1 | 55 | ||||||||||||||||
| Total revenue | 11,017 | 7,674 | 23,151 | 13,007 | ||||||||||||||||
| Operating costs and expenses | ||||||||||||||||||||
| Cost of revenue | 9,382 | 14,227 | 21,829 | 22,026 | ||||||||||||||||
| Research and development | 55,060 | 38,439 | 101,737 | 70,880 | ||||||||||||||||
| General and administrative | 28,290 | 21,199 | 51,165 | 42,273 | ||||||||||||||||
| Total operating costs and expenses | 92,732 | 73,865 | 174,731 | 135,179 | ||||||||||||||||
| Loss from operations | (81,715) | (66,191) | (151,580) | (122,172) | ||||||||||||||||
| Other income, net | 4,989 | 631 | 9,527 | 633 | ||||||||||||||||
| Net loss | $ | (76,726) | $ | (65,560) | $ | (142,053) | $ | (121,539) | ||||||||||||
| Per share data | ||||||||||||||||||||
| Net loss per share of Class A, B and Exchangeable common stock, basic and diluted | $ | (0.38) | $ | (0.38) | $ | (0.71) | $ | (0.71) | ||||||||||||
| Weighted-average shares (Class A, B and Exchangeable) outstanding, basic and diluted | 201,415,475 | 172,212,390 | 198,957,804 | 171,455,595 | ||||||||||||||||
Recursion Pharmaceuticals, Inc.
Condensed Consolidated Balance Sheets (unaudited)
(in thousands)
| June 30, | December 31, | |||||||
| 2023 | 2022 | |||||||
| Assets | ||||||||
| Current assets | ||||||||
| Cash and cash equivalents | $ | 405,870 | $ | 549,912 | ||||
| Restricted cash | 3,325 | 1,280 | ||||||
| Other receivables | 3,051 | 2,753 | ||||||
| Other current assets | 18,774 | 15,869 | ||||||
| Total current assets | 431,020 | 569,814 | ||||||
| Restricted cash, non-current | 7,629 | 7,920 | ||||||
| Property and equipment, net | 89,768 | 88,192 | ||||||
| Operating lease right-of-use assets | 34,899 | 33,255 | ||||||
| Intangible assets, net | 42,757 | 1,306 | ||||||
| Goodwill | 60,516 | 801 | ||||||
| Other assets, non-current | 110 | — | ||||||
| Total assets | $ | 666,699 | $ | 701,288 | ||||
| Liabilities and stockholders’ equity | ||||||||
| Current liabilities | ||||||||
| Accounts payable | $ | 2,086 | $ | 4,586 | ||||
| Accrued expenses and other liabilities | 32,873 | 32,904 | ||||||
| Unearned revenue | 73,105 | 56,726 | ||||||
| Notes payable | 676 | 97 | ||||||
| Operating lease liabilities | 5,219 | 5,952 | ||||||
| Total current liabilities | 113,959 | 100,265 | ||||||
| Unearned revenue, non-current | 32,436 | 70,261 | ||||||
| Notes payable, non-current | 1,155 | 536 | ||||||
| Operating lease liabilities, non-current | 45,850 | 44,420 | ||||||
| Deferred tax liabilities | 4,336 | — | ||||||
| Total liabilities | 197,736 | 215,482 | ||||||
| Commitments and contingencies | ||||||||
| Stockholders’ equity | ||||||||
Common stock (Class A, B and Exchangeable) | 2 | 2 | ||||||
| Additional paid-in capital | 1,250,570 | 1,125,360 | ||||||
| Accumulated deficit | (781,609) | (639,556) | ||||||
| Total stockholders’ equity | 468,963 | 485,806 | ||||||
| Total liabilities and stockholders’ equity | $ | 666,699 | $ | 701,288 | ||||
Forward-Looking Statements
This document contains information that includes or is based upon "forward-looking statements" within the meaning of the Securities Litigation Reform Act of 1995, including, without limitation, those regarding the outcomes and benefits expected from the NVIDIA partnership and Cyclica and Valence Discovery acquisitions and the launch of Valence Labs; early and late stage discovery, preclinical, and clinical programs, including timelines for data readouts; licenses and collaborations, including option exercises by partners and additional partnerships; prospective products and their potential future indications and market opportunities; Recursion OS and other technologies; business and financial plans and performance, including cash runway; and all other statements that are not historical facts. Forward-looking statements may or may not include identifying words such as “plan,” “will,” “expect,” “anticipate,” “intend,” “believe,” “potential,” “could,” “continue,” and similar terms. These statements are subject to known or unknown risks and uncertainties that could cause actual results to differ materially from those expressed or implied in such statements, including but not limited to: challenges inherent in pharmaceutical research and development, including the timing and results of preclinical and clinical programs, where the risk of failure is high and failure can occur at any stage prior to or after regulatory approval due to lack of sufficient efficacy, safety considerations, or other factors; our ability to leverage and enhance our drug discovery platform; our ability to obtain financing for development activities and other corporate purposes; the success of our collaboration activities; our ability to obtain regulatory approval of, and ultimately commercialize, drug candidates; our ability to obtain, maintain, and enforce intellectual property protections; cyberattacks or other disruptions to our technology systems; our ability to attract, motivate, and retain key employees and manage our growth; inflation and other macroeconomic issues; and other risks and uncertainties such as those described under the heading “Risk Factors” in our filings with the U.S. Securities and Exchange Commission, including our most recent Quarterly Report on Form 10-Q and our Annual Report on Form 10-K. All forward-looking statements are based on management’s current estimates, projections, and assumptions, and Recursion undertakes no obligation to correct or update any such statements, whether as a result of new information, future developments, or otherwise, except to the extent required by applicable law.
Exhibit 99.2
Recursion Bridges the Protein and Chemical Space with Massive Protein-Ligand Interaction Predictions Spanning 36 Billion Compounds
•Recursion has predicted the protein target(s) for approximately 36 billion chemical compounds in the Enamine REAL Space, reported to be the world’s largest searchable chemical library
•These advances were made possible by NVIDIA DGX Cloud supercomputing and the recent acquisition of Cyclica’s MatchMaker technology
SALT LAKE CITY, August 8, 2023 — Recursion (NASDAQ: RXRX), a leading clinical stage TechBio company decoding biology to industrialize drug discovery, today announced it has successfully screened the Enamine REAL Space chemical library using its MatchMaker technology, recently acquired from Cyclica, to predict the protein target(s) for approximately 36 billion chemical compounds. This accomplishment was made possible by several other enabling discoveries, including the predicted structures derived from the AlphaFold2 database for more than 15,000 human proteins containing more than 80,000 potential binding pockets, as well as the Enamine REAL Space, which is reported to be the world’s largest searchable chemical library comprised of approximately 36 billion make-on-demand molecules. In total, this screen digitally evaluated more than 2.8 quadrillion small molecule-target pairs.
“This achievement represents a significant and exciting step toward achieving our mission of decoding biology and chemistry,” said Chris Gibson, Ph.D., Co-Founder and CEO of Recursion. “Until this point, the groundbreaking progress across biology and chemistry that enabled this moment – namely, AlphaFold, the Enamine virtual chemical library and the rapid advancement of large-scale compute and new machine learning approaches – have largely lived in isolation of one another or have been bridged at relatively small scales. Leveraging Recursion’s machine learning and computational expertise and NVIDIA’s technology, we have layered these advances together to predict how each of the molecules in this vast chemical universe may interact with the protein universe.”
The company generated this massive new data layer of predicted interactions in less than 90 days after closing the acquisition of Cyclica and in under 30 days since initiating the collaboration with NVIDIA.
MatchMaker uses machine learning to assess whether a small molecule is compatible with a specific protein binding pocket, providing a solution that is significantly less computationally intensive and much more scalable than traditional docking and physics-based interaction simulations. Similar to Recursion’s phenomics platform, the scalability of MatchMaker enables a “high-dimensional” view of biochemistry: activity is predicted not just for a single target, but for many at the same time. This enables three core advantages: First, this predicted data layer can be used to determine which wet-lab experiments should be executed to advance programs faster across a wide range of targets and chemical space. Second, this predicted data layer can be used as part of Recursion’s multi-modal dataset to better understand biological activity across programs quickly and at scale. Finally, this approach can pre-screen for more computationally expensive precision modeling techniques implemented by Recursion’s computational and digital chemistry teams, to more efficiently advance programs.
“We are excited to collaborate with Recursion to explore the chemical space and support our mission to accelerate drug discovery,” said Andrey Tolmachev, Ph.D., Founder and Owner of
Enamine. He continued: “This achievement in the 36 Billion REAL Space is just a start of our journey. The chemical knowledge accumulated at Enamine over its 35-years history allows us to explore trillions of relationships without compromising the high success rate of synthesis. We believe the predictions made by Recursion can help us prioritize parts of the chemical universe and provide an opportunity to develop focused chemical spaces and novel compounds around discovered hits quickly.”
Much of the initial testing and infrastructure development for the project was completed using BioHive-1, Recursion’s in-house supercomputer, an NVIDIA DGX SuperPOD, which is ranked among the top 125 most powerful supercomputers in the world across any industry by TOP500 as of June 2023. The final analysis was made possible by NVIDIA’s DGX Cloud, an advanced AI-training-as-a-service solution to which Recursion gained access following its recently announced collaboration with NVIDIA. Recursion worked with urgency to make this effort happen in a short period of time.
“Bringing together powerful data, AI and data-center scale compute, Recursion’s MatchMaker running on NVIDIA DGX Cloud essentially created a time machine for the company’s drug discovery program and sets a new bar for the industry,” said Kimberly Powell, Vice President of Healthcare at NVIDIA. “Within one week, the Recursion team was able to achieve what would have otherwise taken 100,000 years to compute with physics-based methods — setting the stage for a wet-lab, dry-lab flywheel to better predict drug-target interactions and increase a drug’s probability of success in the clinic.”
Recursion plans to leverage this new database of predictions to industrialize its chemistry operations across its pipeline and in service to its partners, enabling significantly greater efficiency in its medicinal chemistry cycles. Further, Recursion plans to continue improving and expanding the number and type of chemical properties and interactions it can predict using in-house tools, tools acquired through the acquisition of Cyclica, and tools being developed by Valence Labs, the semi-autonomous research hub powered by Recursion and formed through the acquisition of Valence Discovery.
About Recursion
Recursion (NASDAQ: RXRX) is a clinical stage TechBio company leading the space by decoding biology to industrialize drug discovery. Enabling its mission is the Recursion OS, a platform built across diverse technologies that continuously expands one of the world’s largest proprietary biological and chemical datasets. Recursion leverages sophisticated machine-learning algorithms to distill from its dataset a collection of trillions of searchable relationships across biology and chemistry unconstrained by human bias. By commanding massive experimental scale — up to millions of wet lab experiments weekly — and massive computational scale — owning and operating one of the most powerful supercomputers in the world, Recursion is uniting technology, biology, and chemistry to advance the future of medicine.
Recursion is headquartered in Salt Lake City, where it is a founding member of BioHive, the Utah life sciences industry collective. Recursion also has offices in Toronto, Montréal and the San Francisco Bay Area. Learn more at www.Recursion.com, or connect on Twitter and LinkedIn.
About Enamine
Headquartered in Kyiv, Ukraine, Enamine combines a CRO profile with the production and multilevel supply of innovative screening libraries, novel building blocks, fragments, and various
functional compounds, including covalent and protein degradation compounds. The company provides integrated support in early drug discovery, including biological screening, hit-to-lead and lead optimization projects. The major assets of the company are the collection of 4 million screening compounds backed up by 36 billion REAL Compounds for hit follow-up, and the dynamically growing catalog of over 300,000 building blocks. Enamine offers collaborative expertise to exclusively design and screen libraries of novel small molecular weight compounds and fragments.
Media Contact
Media@Recursion.com
Investor Contact
Investor@Recursion.com
Forward-Looking Statements
This document contains information that includes or is based upon "forward-looking statements" within the meaning of the Securities Litigation Reform Act of 1995, including, without limitation, those regarding the outcomes and benefits expected from the NVIDIA partnership and Cyclica and Valence Discovery acquisitions and the launch of Valence Labs; early and late stage discovery, preclinical, and clinical programs; licenses and collaborations; prospective products and their potential future indications and market opportunities; the Recursion OS and other technologies, including MatchMaker, the Enamine REAL Space chemical library and NVIDIA’s DGX Cloud; business and financial plans and performance; and all other statements that are not historical facts. Forward-looking statements may or may not include identifying words such as "plan," "will," "expect," "anticipate," "intend," "believe," "potential," "continue," and similar terms. These statements are subject to known or unknown risks and uncertainties that could cause actual results to differ materially from those expressed or implied in such statements, including but not limited to: challenges inherent in pharmaceutical research and development, including the timing and results of preclinical and clinical programs, where the risk of failure is high and failure can occur at any stage prior to or after regulatory approval due to lack of sufficient efficacy, safety considerations, or other factors; our ability to leverage and enhance our drug discovery platform; our ability to obtain financing for development activities and other corporate purposes; the success of our collaboration activities; our ability to obtain regulatory approval of, and ultimately commercialize, drug candidates; our ability to obtain, maintain, and enforce intellectual property protections; cyberattacks or other disruptions to our technology systems; our ability to attract, motivate, and retain key employees and manage our growth; and other risks and uncertainties such as those described under the heading "Risk Factors" in our filings with the U.S. Securities and Exchange Commission, including our most recent Quarterly Report on Form 10-Q and our Annual Report on Form 10-K. All forward-looking statements are based on management's current estimates, projections, and assumptions, and Recursion undertakes no obligation to correct or update any such statements, whether as a result of new information, future developments, or otherwise, except to the extent required by applicable law.
Decoding Biology To Radically Improve Lives End of Q2, 2023
This presentation and any accompanying discussion and documents contain information that includes or is based upon "forward-looking statements" within the meaning of the Securities Litigation Reform Act of 1995. These forward-looking statements are based on our current expectations, estimates and projections about our industry and our company, management's beliefs and certain assumptions we have made. The words “plan,” “anticipate,” “believe,” “continue,” “estimate,” “expect,” “intend,” “may,” “will” and similar expressions are intended to identify forward-looking statements. Forward-looking statements made in this presentation include outcomes and benefits expected from the NVIDIA partnership and Cyclica and Valence Discovery acquisitions and the launch of Valence Labs, outcomes and benefits from licenses and collaborations, including option exercises by partners and additional partnerships; the occurrence or realization of any near or medium term potential milestones, the initiation, timing, progress, results, and cost of our research and development programs and our current and future preclinical and clinical studies, including timelines for data readouts, the potential size of the market opportunity for our drug candidates, our ability to identify viable new drug candidates for clinical development and the accelerating rate at which we expect to identify such candidates, our expectation that the assets that will drive the most value for us are those that we will identify in the future using our datasets and tools, and many others. Forward-looking statements made in this presentation are neither historical facts nor assurances of future performance, are subject to significant risks and uncertainties, and may not occur as actual results could differ materially and adversely from those anticipated or implied in the forward-looking statements. For a discussion of factors that could affect our business, please refer to the "Risk Factors" sections in our filings with the U.S. Securities and Exchange Commission, including our most recent Quarterly Report on Form 10-Q. This presentation does not purport to contain all the information that may be required to make a full analysis of the subject matter. We undertake no obligation to correct or update any forward-looking statements, whether as a result of new information, future events or otherwise. Certain information contained in this presentation relates to or is based on studies, publications, surveys and other data obtained from third-party sources and the company’s own internal estimates and research. While the company believes these third-party sources to be reliable as of the date of this presentation, it has not independently verified, and makes no representation as to the adequacy, fairness, accuracy or completeness of, any information obtained from third-party sources. In addition, all of the market data included in this presentation involves a number of assumptions and limitations, and there can be no guarantee as to the accuracy or reliability of such assumptions. Finally, while the company believes its own internal research is reliable, such research has not been verified by any independent source. Any non-Recursion logos or trademarks included herein are the property of the owners thereof and are used for reference purposes only. Disclaimers 2
Table of Contents 3 Recursion’s value proposition 6 – 13 How we build maps of biology and chemistry to turn drug discovery into a search problem 14 – 21 How we create value using our maps of biology and chemistry 22 – 75 Pipeline 23 – 71 Partnerships 72 – 73 Data 74 – 75 Value driven by our team and our milestones 76 – 80 Additional scientific and business context 81 – 92
Pipeline - Added, accelerated or tightened guidance for clinical studies: • REC-3964 Ph1 C Diff safety in Q3, 2023 • REC-994 Ph2 CCM top-line in H2, 2024 • REC-2282 Ph2 NF2 safety & preliminary efficacy in H2, 2024 • REC-4881 Ph2 FAP safety & preliminary efficacy in H1, 2025 • IND accepted for AXIN1 or APC mutant cancers with Ph2 initiation in Q4, 2023 Partnerships - Sector-leading partnerships across biopharma and tech: • Announced a $50 million investment and partnership with NVIDIA to accelerate the construction, optimization and deployment of foundation models for biology and chemistry • Advancing collaborations with Roche-Genentech and Bayer: $13B in potential milestones across 50+ possible programs plus royalties Platform - Continued building on the strength of our Recursion OS: • Predicted ligand-protein interactions for ~36 billion compounds in Enamine REAL Space (reported to be the world’s largest searchable chemical library) working with partners at NVIDIA • New pipeline programs now exclusively generated via Large Language Model (LLM) workflow • Developing large-scale foundation models for drug discovery, based upon our massive proprietary dataset spanning biology and chemistry Maturing the TechBio value proposition – Q2, 2023 4
5 ~36 Billion Compounds from the Enamine Real Space ~80,000 predicted binding pockets from ~15,000 human proteins ~2.8 Quadrillion potential protein- ligand interactions computed and stored Recursion partnered with to integrate and optimize MatchMaker (acquired via ) for massive scale GPU-based computation on BioHive-1 and the DGXCloud This tool was deployed to predict protein- ligand interaction for ~36 Billion compounds from the Enamine Real Space, less than 90 days post-acquisition of Cyclica and less than 30 days post-partnership with NVIDIA Recursion will use the predicted interactions as a data-layer in its multi-omic dataset for honing mechanistic predictions from its wet- labs and for accelerating SAR cycles through better predictions for its internal pipeline and within its partnerships Quick Update: Bridging Protein and Chemical Space with Massive Protein-Ligand Interaction Predictions Computation at Scale Computation at Speed Computation as a Data-Layer
In Brief: The Recursion Value Proposition
Recursion leading a new TechBio sector at the intersection of technology and biology 7Adapted from Scannell, J et al (2012). Diagnosing the decline in pharmaceutical R&D efficiency. Nat Rev Drug Discov, 11, 191-200. 0.1 1 10 50B 100M 500K 1K 20201962 1970 1980 1990 2000 2010 Compute Power (Transistors per Microprocessor)NMEs per $B spent (inflation adjusted) Moore’s Law: Computing power becomes faster and less expensive over time Eroom’s Law: Drug discovery is becoming slower and more expensive over time Opportunity
TranslationCompound OptimizationHit & Target ValidationPatient Connectivity & Novelty 8 Chemical property predictions Compound selection with ML DMPK experiments Phenomic efficacy InVivomic Prioritization & Digital Tolerability InVivomic Efficacy Preclinical assessment Large Language Models to Query Global Knowledge for Program Ideation, Evaluation & Novelty In-House Wet-Lab & Dry-Lab Experiments to Generate Massive Proprietary Maps of Biology & Chemistry ~2M physical compounds & ~36B compounds with target prediction ~50 human cell types including whole genome CRISPR-based knockouts and secreted factors Predicted target binding Scaled Phenomics Scaled Transcriptomics Chemical tractability The Recursion OS today: Industrializing drug discovery to transform BioTech into TechBio
Data shown is the average of all our programs since late 2017 through 2022. All industry data adapted from Paul, et al. Nature Reviews Drug Discovery. (2010) 9, 203–214 Mapping and navigating the complex systems of biology and chemistry has demonstrated leading indicators of efficiency 9 Screen — Hit ID — Validated Lead — Advanced Candidate — Development Candidate — Industry Recursion Failing faster and earlier to › › spend less › C o st t o IN D ( $ M ) 25 — 20 — 15 — 10 — 5 — 0 — Industry 40 — 30 — 20 — 10 — 0 — › and go faster 100 80 60 51 80% 75% 85% 100 64 25 64% 39% 62% 12 50% St ag e Ti m e t o V al id at ed L e ad ( m o ) Recursion Industry Recursion 8 Industry Recursion
Harnessing value with a multi-pronged capital-efficient business strategy 10 Pipeline Recursion OS Build internal pipeline in indications with potential for accelerated path to approval Pipeline Strategy Precision Oncology Rare Disease Partnerships Data Partnership Strategy Partner in complex therapeutic areas requiring large financial commitment and competitive market dynamics Leverage partner knowledge and clinical development capabilities License subsets of data and key tools Direct generation of new data internally to maximize pipeline and partnership value-drivers Data Strategy Fibrosis Other large, intractable areas of biology Neuroscience* Licensing Augment Recursion OS *Includes a single oncology indication from our Roche and Genentech collaboration.
PreclinicalLate Discovery Oncology Rare & Other Therapeutic Area Indication AXIN1 or APC MUTANT CANCERS (AXIN1 or APC mutant cancers; est. 65K) MYC-DRIVEN ONCOLOGY (MYC; est. 54K4) CLOSTRIDIOIDES DIFFICILE INFECTION (est. 730K) CEREBRAL CAVERNOUS MALFORMATION (CCM; est. 360K1) NEUROFIBROMATOSIS TYPE 2 (NF2; est. 33K2) FAMILIAL ADENOMATOUS POLYPOSIS (APC; est. 50K) CANCER IMMUNOTHERAPY, TARGET ALPHA (Multiple; est. 72K3) Phase 1 Phase 2 Phase 3 11 All populations defined above are US and EU5 incidence unless otherwise noted. EU5 is defined as France, Germany, Italy, Spain and UK. (1) Prevalence for hereditary and sporadic symptomatic population. (2) Annual US and EU5 incidence for all NF2-driven meningiomas. (3) Our program has the potential to address several indications in this space. (4) Our program has the potential to address several indications driven by MYC alterations, totaling 54,000 patients in the US and EU5 annually. We have not finalized a target product profile for a specific indication. More than a dozen additional early discovery and research programs in oncology or with our partners Our pipeline reflects the scale and breadth of our approach CANCER IMMUNOTHERAPY, TARGET DELTA (Multiple; est. 88K3) HR-PROFICIENT OVARIAN CANCER, RBM39 (HR-proficient ovarian cancer; est. 13K)
Fibrosis Neuroscience *and a single oncology indication • $30M upfront and $50M equity investment • Up to or exceeding $1.2B in milestones for up to or exceeding 12 programs • Mid single-digit royalties on net sales • Recursion owns all algorithmic improvements • $150M upfront and up to or exceeding $500M in research milestones and data usage options • Up to or exceeding $300M in possible milestones per program for up to 40 programs • Mid to high single-digit tiered royalties on net sales • Recursion owns or co-owns all algorithmic improvements Our existing partnerships represent some of the most significant scientific collaborations in TechBio across biopharma and tech (Announced Sep 2020; Expanded Dec 2021) (Announced Dec 2021) Trademarks are the property of their respective owners and used for informational purposes only. 12 Computation and ML/AI (Announced July 2023) • $50M equity investment • Partnership on advanced computation (e.g. foundation model development) • Priority access to compute hardware or DGXCloud Resources • Potential to house Recursion Tools on NVIDIA’s BioNeMo Marketplace
13 Relatable and scalable data is a key Recursion differentiator Recursion Data Universe: >25 PB of proprietary biological and chemical data, spanning phenomics, transcriptomics, invivomics, and more • We believe this is one of the largest such datasets fit for the purpose of training large-scale ML models in biology RXRX3: CRISPR knockouts of most of the human genome, 1,600 FDA approved / commercially available bioactive compounds • We believe the largest public dataset of its kind, <1% of Recursion Data Universe, what Recursion can generate in ~1 week MolRec™️: freemium web-based application to explore compound and gene relationships in RXRX3 Start working with RXRX3 and MolRec™️: www.rxrx.ai Phenomics data spanning >200 million experiments and 50 human cell types InVivomics Video Data >450K Transcriptomics Experiments ADMET & More Re cu rs io n D at a U ni ve rs e, > 25 P B <1% Dataset Released Number of Samples Bio/Chem Phenomic Maps RxRx3 2023 2.2M JUMPCP 2023 823,438 Autonomous Driving Waymo Open Dataset 2018 ~105,000 nuScenes 2018 1,000 Image/Object recognition ImageNet (21k) 2009 14M COCO 2014 330,000 ~100 TB ~1 -5 TB ~10 GB -~1 TB
How we build maps of biology and chemistry to turn drug discovery into a search problem
Recursion’s map-based approach is designed to set the standard for drug discovery in the 21st century Platforms drive discovery. Unbiased & target agnostic Literature drives discovery. Informs target-based hypotheses Data are our fuel. Shape our hypotheses Data are an exhaust. Limited to testing hypotheses Virtuous cycles of atoms & bits. Iterative feedback accelerates learning Linear process. Little cross-program learning or iteration Connected data across programs. Relatable high-dimensional data Disparate data generation. Siloed to individual programs and diseases Industrialized to scale. Automation & standardization Bespoke processes. Low-dimensional assays & biomarkers 15
TranslationCompound OptimizationHit & Target ValidationPatient Connectivity & Novelty 16 Chemical property predictions Compound selection with ML DMPK experiments Phenomic efficacy InVivomic Prioritization & Digital Tolerability InVivomic Efficacy Preclinical assessment Large Language Models to Query Global Knowledge for Program Ideation, Evaluation & Novelty In-House Wet-Lab & Dry-Lab Experiments to Generate Massive Proprietary Maps of Biology & Chemistry ~2M physical compounds & ~36B compounds with target prediction ~50 human cell types including whole genome CRISPR-based knockouts and secreted factors Predicted target binding Scaled Phenomics Scaled Transcriptomics Chemical tractability The Recursion OS today: Industrializing drug discovery to transform BioTech into TechBio
17 TranslationCompound OptimizationHit & Target ValidationPatient Connectivity & Novelty State-of-the-art Large Language Models Rapidly scaling to 1000s of new differentiated program ideas Experiments predict Maps of Biology & Chemistry LLMs evaluate complex opportunities at scale Differentiation & Impact Novel map insights and rapid disease research e.g. Uncover which of our 300M+ gene-gene relationships are unique to our Maps Automation & Scale High-throughput LLMs reduce manual research load & human bias e.g. Our 250,000 tokens/min LLM capacity BioHive-1 is a global TOP500 supercomputer Model Accuracy Correct Incorrect GPT-NeoX 47% 53% Dolly2.0 49% 51% GPT4.0 on Azure 80% 20% LLaMA 2 Under evaluation ~2M physical compounds & ~36B compounds with target prediction ~50 human cell types including whole genome CRISPR-based knockouts and secreted factors Our maps encode over 3 trillion relationships & LLMs allow us to quickly distill the most promising novel ideas from this massive search space
18 TranslationCompound OptimizationHit & Target ValidationPatient Connectivity & Novelty Rapidly scaling to 1000s of new differentiated program ideas Hundreds of compound hits per gene from our Maps >100 programs generated in H1, 2023 Automated data package Distilled insights for rapid decision making Predicted target binding Phenomics Transcriptomics Chemical tractability Automatic validation of map insights: we rapidly confirm novel predictions from our maps with automated, standardized, scaled -omics
19 TranslationCompound OptimizationHit & Target ValidationPatient Connectivity & Novelty Chemical property predictions ML predicted protein-ligand interactions for 36 billion compounds and ML predictions for new compounds that become part of our library Compound selection with ML Semi-generative and multi- objective generative chemistry models drive compound design DMPK experiments A highly automated DMPK module executes 3 critical assays across human and rat contexts Phenomic efficacy Compound potency and selectivity are rapidly measured using scaled phenomics Automated loops of in silico predictions & robotic experiments Automated data package Loops of experimental data & ML predictions rapidly accelerate hit to lead and lead optimization
20 TranslationCompound OptimizationHit & Target ValidationPatient Connectivity & Novelty InVivomic Prioritization & Digital Tolerability Rat and mouse studies with ML-based selection of optimal compound and dose from videos Preclinical assessment Best options from Compound Optimization Poorly tolerated compounds kicked back for further Compound Optimization Automated data package Not tolerated Tolerated ML evaluation of mice against >10 liabilities. InVivomic Efficacy InVivomic ML non-invasively enables phenotype induction confirmation and efficacy determination Automated data package InVivomics improves whole organism understanding to rapidly translate programs towards the clinic
21 IND Enabling StudiesTranslationCompound OptimizationHit & Target ValidationPatient Connectivity & Novelty Chemical property predictions Compound selection with ML DMPK experiments Phenomic efficacy InVivomic Prioritization & Digital Tolerability InVivomic Efficacy Preclinical assessment Large Language Models to query global knowledge for program ideation & evaluation Experiments predict Maps of Biology & Chemistry ~2M physical compounds & ~36B compounds with target predictions ~50 human cell types including whole genome CRISPR-based knockouts and secreted factors Predicted target binding Scaled Phenomics Scaled Transcriptomics Chemical tractability LLM-based automated IND generation LLM-based automated patent writing Clinical Development Roadmap: Addition of population-scale data will enable rapid, precise, automated program progression into clinical development at scale Public Population-Scale Patient – OMICS Data Proprietary Population- Scale Patient – OMICS Data
How we create value using our maps of biology and chemistry
Harnessing value with a multi-pronged capital-efficient business strategy 23 Partnerships Pipeline Recursion OS Data Partnership Strategy Partner in complex therapeutic areas requiring large financial commitment and competitive market dynamics Leverage partner knowledge and clinical development capabilities Build internal pipeline in indications with potential for accelerated path to approval Pipeline Strategy License subsets of data and key tools Direct generation of new data internally to maximize pipeline and partnership value-drivers Data Strategy Precision Oncology Rare Disease Fibrosis Other large, intractable areas of biology Neuroscience* Licensing Augment Recursion OS *Includes a single oncology indication from our Roche and Genentech collaboration.
PreclinicalLate Discovery Oncology Rare & Other Therapeutic Area Indication AXIN1 or APC MUTANT CANCERS (AXIN1 or APC mutant cancers; est. 65K) MYC-DRIVEN ONCOLOGY (MYC; est. 54K4) CLOSTRIDIOIDES DIFFICILE INFECTION (est. 730K) CEREBRAL CAVERNOUS MALFORMATION (CCM; est. 360K1) NEUROFIBROMATOSIS TYPE 2 (NF2; est. 33K2) FAMILIAL ADENOMATOUS POLYPOSIS (APC; est. 50K) CANCER IMMUNOTHERAPY, TARGET ALPHA (Multiple; est. 72K3) Phase 1 Phase 2 Phase 3 24 All populations defined above are US and EU5 incidence unless otherwise noted. EU5 is defined as France, Germany, Italy, Spain and UK. (1) Prevalence for hereditary and sporadic symptomatic population. (2) Annual US and EU5 incidence for all NF2-driven meningiomas. (3) Our program has the potential to address several indications in this space. (4) Our program has the potential to address several indications driven by MYC alterations, totaling 54,000 patients in the US and EU5 annually. We have not finalized a target product profile for a specific indication. More than a dozen additional early discovery and research programs in oncology or with our partners Our pipeline reflects the scale and breadth of our approach CANCER IMMUNOTHERAPY, TARGET DELTA (Multiple; est. 88K3) HR-PROFICIENT OVARIAN CANCER, RBM39 (HR-proficient ovarian cancer; est. 13K)
REC-994 for the Treatment of Symptomatic Cerebral Cavernous Malformations (CCM) Target / MOA Superoxide Scavenger Molecule Type Small Molecule Lead Indication(s) Cerebral Cavernous Malformations Status Phase 2 Designation(s) US & EU Orphan Drug Source of Insight Recursion OS
Julia – living with CCM 26 SYCAMORE Clinical Trial : REC-994 for CCM Phase 2 Fully Enrolled Clinical: CCM Symptomatic US + EU5, >1 million patients worldwide live with these lesions today PREVALENCE & STANDARD OF CARE CAUSE LOF mutations in genes CCM1, CCM2 & CCM3, key for maintaining the structural integrity of the vasculature due to unknown mechanisms PATHOPHYSIOLOGY & REASON TO BELIEVE Efficacy in Recursion OS as well as functional validation via scavenging of massive superoxide accumulation in cellular models; reduction in lesion number with chronic administration in mice KEY ELEMENTS • Targeting sporadic and familial symptomatic CCM patients with CCM1, CCM2, and CCM3 mutations • Superoxide scavenger, small molecule • Phase 2 trial initiated in Q1 2022 • US & EU Orphan Drug Designation • Oral dosing ~360,000 Vascular malformations of the CNS leading to focal neurological deficits, hemorrhage and other symptomsNo approved therapy • Most patients receive no treatment or only symptomatic therapy • Surgical resection or stereotactic radiosurgery not always feasible because of location and is not curative >5x larger US patient population than other rare diseases like Cystic Fibrosis (>31k patients) Vascular malformations (cavernomas)
27 • Large unmet need for a novel nonsurgical treatment • Vascular malformations (cavernomas) in the brain and spinal cord • High-risk for hemorrhage creates “ticking time bomb” • Progressive increase in CCM size and number over time in those with familial disease • Debilitating symptoms, including intractable seizure, intracerebral hemorrhage, focal neurological deficits Description “Historically, cavernomas have been managed primarily with observation, surgical resection, and occasionally radiotherapy. However, for a number of reasons, many patients with cavernomas must endure a life with neurologic symptoms” - Ryan Kellogg, MD, Investigator at the University of Virginia Disease Overview : Cerebral Cavernous Malformations (CCM) 27 Clinical: CCM
28 Sources: Angioma Alliance ; Flemming KD, et al . Population-Based Prevalence of Cerebral Cavernous Malformations in Older Adults: Mayo Clinic Study of Aging. JAMA Neurol. 2017 Jul 1;74(7):801-805. doi: 10.1001/jamaneurol.2017.0439. PMID: 28492932; PMCID: PMC5647645 ; Spiegler S, et al Cerebral Cavernous Malformations: An Update on Prevalence, Molecular Genetic Analyses, and Genetic Counselling. Mol Syndromol. 2018 Feb;9(2):60-69. doi: 10.1159/000486292. Epub 2018 Jan 25. PMID: 29593473; PMCID: PMC5836221. ~360,000 Patient Population – Large and Diagnosable No Approved Medical Therapy • >1 million patients worldwide live with these lesions today • Caused by loss of function mutation in one of three genes: CCM1 (60%), CCM2 (20%), and CCM3 (20%) • Inherited autosomal dominant mutation in 30-40%; or sporadic • US symptomatic population is more than 5 times larger than other rare diseases like Cystic Fibrosis (>31k patients) and Spinal Muscular Atrophy (>33k patients) • No approved drugs for CCM • Most patients receive no treatment or only symptomatic therapy • Surgical resection or stereotactic radiosurgery not always feasible because of location of lesion and is not curative Julia – living with CCM Clinical: CCM Disease Overview : Cerebral Cavernous Malformations (CCM) Symptomatic US + EU5 patients 28
29 Disease Overview : CCM is an Under-Appreciated Orphan Disease Non-oncology Orphan Indication Product U.S. + EU5 Prevalence Cerebral cavernous malformation (CCM) REC-994 (Recursion) >1,800,000 (Symptomatic: ~360,000) Idiopathic pulmonary fibrosis (IPF) Esbriet (pirfenidone) >160,000 Cystic fibrosis (CF) VX-669/ VX-445 + Tezacaftor + Ivacaftor - Vertex >55,000 Spinal muscular atrophy (SMA) SPINRAZA (nusinersen) >65,000 Clinical: CCM Sources: Angioma Alliance ; Flemming KD, et al . Population-Based Prevalence of Cerebral Cavernous Malformations in Older Adults: Mayo Clinic Study of Aging. JAMA Neurol. 2017 Jul 1;74(7):801-805. doi: 10.1001/jamaneurol.2017.0439. PMID: 28492932; PMCID: PMC5647645 ; Spiegler S, et al Cerebral Cavernous Malformations: An Update on Prevalence, Molecular Genetic Analyses, and Genetic Counselling. Mol Syndromol. 2018 Feb;9(2):60-69. doi: 10.1159/000486292. Epub 2018 Jan 25. PMID: 29593473; PMCID: PMC5836221; Maher T, et al Global incidence and prevalence of idiopathic pulmonary fibrosis. Respir Res. 2021 Jul 7;22(197). Doi: 10.1186/s12931-021-01791-z. PMID: 34233665. DRG 2022 Solutions, Report: Epidemiology, Cystic Fibrosis. CDC: SMA 29
30 • Symptoms associated with both increased size of lesions, but also inflammation or activation of lesions within the immunopriviledged environment of the brain • Lesions arise from the capillary bed and are not high-pressure (e.g., the lesion growth is unlikely to be primarily driven by the law of Laplace) • The Recursion Vascular Stability Hypothesis: • Eliminating the lesions may not be required for significant patient benefit • Slowing or halting the growth of the lesions while mitigating lesion leakiness and endothelial cell activation to halt the feed-forward inflammatory reaction may mitigate some symptoms and be beneficial to patients Novel therapeutic approach Therapeutic Approach to Cerebral Cavernous Malformations (CCM) 30 Clinical: CCM
CCM – Applied prototyping of the Recursion OS Clinical: CCM Gibson, et al. Strategy for identifying repurposed drugs for the treatment of cerebral cavernous malformation. Circulation, 2015 siCTRL siCCM2 siCCM2 + Simvastatin siCCM2 + Cholecalciferol siCCM2 + REC-994 Using an early version of our Recursion OS in an academic setting, we identified about 39 molecules out of 2,100 screened that according to a machine learning classifier rescued a complex unbiased phenotype associated with CCM2 loss of function. Through a set of follow-on confirmatory assays of increasing complexity, REC-994 stood out as one of two compounds we tested in a 5-month chronic CCM animal model where both compounds demonstrated significant benefit. 31
Healthy REC-994 – Mechanism of Action REC-994 ImpactCCM Clinical: CCM • Endothelial cell activation • Smooth muscle proliferation • Leukocyte adhesion • Platelet aggregation By regulating SOD2, CCM1 (KRIT1) & CCM2 suppress: CCM1 or CCM2 loss of function leads to activated endothelium: • Decreased cell-cell junctional integrity and increased monolayer permeability • Impaired vasodilation • Cavernous angioma formation Dosing of REC-994 restores normal function: • Normalized ROS balance • Restores quiescent endothelial cell state • Stabilizes endothelial barrier function Adapted from REC-994 Investigator Brochure 32
33 Further Confidence : Preclinical Studies Confirm Insight Source: Data above from Gibson, et al. Strategy for identifying repurposed drugs for the treatment of cerebral cavernous malformation. Circulation, 2015 or Recursion internal data (Ccm1 mouse model) Preclinical Studies: REC-994 reduces lesion burden and ameliorates vascular defects in genetic mouse models of CCM Vascular permeability is a clinically relevant feature of CCM lesions REC-994 stabilizes the integrity of vasculature against challenges to permeability Clinical: CCM Reduces lesion number and size in Ccm1 and Ccm2 LOF mouse models1 Completely rescues acetylcholine-induced vasodilation defect2 Rescues dermal permeability defect in CCM2 mice3 Lesion size (mm2) Ccm1 LOF Model ecKO + REC-994 WT ecKO % V as o d ila ti o n Acetylcholine [Log M] 33 Lesion size (mm2) Ccm2 LOF Model * * * DMSO control REC-994 Ccm2 WT Ccm2 ecKO D e rm al P e rm e ab ili ty (A b so rp ti o n , A U ) *
Further Confidence : Clinical Studies Confirming Safety REC-994 Phase 1 Studies - well-tolerated with no dose-dependent adverse events in SAD and MAD Clinical: CCM MAD Study Placebo 50 mg 200 mg 400 mg 800 mg Total Number of TEAEs Total Subjects with ≥ one TEAE 5 4 0 0 10 3 4 3 15 4 Severity Mild Moderate Severe 3 1 0 0 0 0 3 0 0 3 0 0 3 1 0 Relationship to Study Drug None Unlikely Possibly Likely Definitely 3 1 0 0 0 0 0 0 0 0 0 1 0 2 0 2 1 0 0 0 1 2 0 1 0 Total Number of SAEs Total Subject with ≥ one TEAE Discontinued Study Drug Due to AE 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Source: REC-994 for the Treatment of Symptomatic Cerebral Cavernous Malformation (CCM) Phase 1 SAD and MAD Study Results. Oral Presentation at Alliance to Cure Scientific Meeting. 2022 Nov 17 34
35 SYCAMORE Clinical Trial : REC-994 for CCM Phase 2 Fully Enrolled Phase 2 trial initiated in Q1, 2022 Source: https://www.clinicaltrials.gov/ct2/show/NCT05130866?term=recursion&draw=2&rank=3; https://www.SycamoreCCM.com/ Screening & Randomization 1:1:1 Treatment Follow-up Outcome Measures Enrollment Criteria • MRI-confirmed CCM lesion(s) • Familial or sporadic • Symptoms directly related to CCM • Primary: Safety and tolerability • Adverse events & symptoms • Secondary: Efficacy • Clinician-measured outcomes (CGI and PGI) • Imaging of CCM lesions – number, size & rate of change • Impact of acute stroke (mRS, NIHSS) • Patient reported outcomes (SMSS, PROMIS-29, CCM HI, symptom questionnaires) • Exploratory: Biomarkers • Enrollment is complete • Several participants have completed twelve months of treatment and entered long-term extension study • Top-line data expected H2, 2024 Trial Update Clinical: CCM 35 400mg 200mg Placebo Visits: Days 1 & 2 Months 1, 3, 6, 9 & 12 Enroll ~60 Extension Study12 Months Treatment Period
REC-2282 for the Treatment of Progressive Neurofibromatosis Type 2 (NF2) Mutated Meningiomas Target / MOA HDAC Inhibitor Molecule Type Small Molecule Lead Indication(s) NF2 Mutated Meningiomas Status Phase 2/3 Designation(s) Fast Track; US and EU Orphan Drug Source of Insight Recursion OS
37 POPLAR Clinical Trial : REC-2282 for NF2 Part A Underway Clinical: NF2 LOF mutations in NF2 tumor suppressor gene, leading to deficiencies in the tumor suppressor protein merlin PATHOPHYSIOLOGY & REASON TO BELIEVE Efficacy in Recursion OS, cellular, and animal models; suppression of aberrant ERK, AKT, and S6 pathway activation in a Phase 1 PD Study in NF2 patient tumors KEY ELEMENTS • Targeting familial and sporadic NF2 meningioma patients • HDAC inhibitor, small molecule • Oral dosing • Phase 2/3 trial initiated in Q2 2022 • Fast-Track and US & EU Orphan Drug Designation Inherited rare CNS tumor syndrome leading to loss of hearing and mobility, other focal neurologic deficits No approved therapy • There are no approved drugs for NF2 • Surgery is standard of care (when feasible) • Location may make complete resection untenable, leading to hearing loss, facial paralysis, poor balance and visual difficulty Treatable US + EU~33,000 PREVALENCE & STANDARD OF CARE CAUSE Ricki – living with NF2 Intracranial meningiomas
38 Disease Overview : Neurofibromatosis Type 2 (NF2) Source: https://rarediseases.org/rare-diseases/neurofibromatosis-2 Patient Population – Large and Diagnosable No Approved Medical Therapy • Rare autosomal dominant tumor syndrome resulting from biallelic inactivation of the NF2 gene which leads to deficiencies in the tumor suppressor protein merlin • NF2 can be inherited or spontaneous (>50% of patients represent new mutations); up to 1/3 are mosaic • CNS manifestations: meningiomas and vestibular schwannomas; mean age at presentation: ~20 years • No approved drugs for NF2 • Surgery is standard of care (when feasible) • Location may make complete resection untenable, leading to hearing loss, facial paralysis, poor balance and visual difficulty Ricki – living with NF2 Clinical: NF2 38
39 Disease Overview : Neurofibromatosis Type 2 (NF2) Meningiomas • Threatens mortality; if amenable, surgical excision is primary intervention • Many patients have multiple meningiomas that exhibit heterogenous behavior and asynchronous growth • Stasis or shrinkage of tumor could improve prognosis Clinical: NF2 ● Most tumors are benign and slow growing but location in CNS leads to serious morbidity or mortality ● Prognosis is adversely affected by early age at onset, a higher number of meningiomas and having a truncating mutation ~27,000 Patients who have Meningiomas that Harbor NF2 Mutations (Sporadic) ~6,000 NF2 Patients have Meningiomas (Familial) >66,000 Patients have Meningiomas Treatable US + EU5 patients ~33,000 Intracranial Meningioma Source: Pemov, et al. Comparative clinical and genomic analysis of neurofibromatosis type 2-associated cranial and spinal meningiomas. Nature. 2020 Jul 28;10(12563). Doi: https://doi.org/10.1038/s41598-020-69074-z; NORD 39
40 NF2 knockdown cells Healthy Cells REC-2282 REC-2282 identified as rescuing HUVEC cells treated with NF2 C o n tr o l N F2 s iR N A HUVEC, human umbilical vein endothelial cells; NF2, neurofibromatosis type 2; siRNA, small interfering RNA. Insight from OS : REC-2282 Rescued Loss of NF2 Clinical: NF2 40
41 REC-2282 – Mechanism of Action AKT, protein kinase B; eIF4F, eukaryotic initiation factor 4F; HDAC, histone deacetylase; mTor, mammalian target of rapamycin; mTORC1; mammalian target of rapamycin complex 1; NF2, neurofibromatosis type 2; PI3K, phosphoinositide 3-kinase; PP1, protein phosphate 1; Ras, reticular activating system. Clinical: NF2 Orally Bioavailable, CNS-penetrating, Small Molecule HDAC Inhibitor NF2 encodes for the protein Merlin and negatively regulates mTOR signaling 1 2 3 Loss of Merlin leads to increased signaling in the PI3K/AKT/mTOR pathway Oncogenic mTOR signaling arrested with HDAC inhibitors Cell proliferation and survival Normal cell proliferation and survival Cell proliferation and survival Constitutive activation is independent of extracellular factors and does not respond to biochemical signals that would normally regulate activity 41 1 2 3
42 REC-2282 preclinical studies demonstrated clear in-vivo efficacy in multiple NF2 tumor types Shrinks vestibular schwannoma xenografts in nude mice Prevents growth & regrowth of NF2- deficient meningioma model in mice Vehicle % Change tumor vol. REC-2282 % Change tumor vol. % c h an ge in t u m o r vo lu m e fr o m b as e lin e M R I % c h an ge in t u m o r vo lu m e fr o m b as e lin e M R I Further Confidence : Preclinical Studies Confirming Insight Clinical: NF2 https://link.springer.com/article/10.1007/s00280-020-04229-3 2 0% 10% 30% 60% -20% -40% 20% 40% 50% -10% -30% -50% 0% 10% -20% -40% -10% -30% -50% 42 1
• Evaluable Patients: CNS Solid Tumors: NF2 N=5; Non-CNS Solid Tumors: N=10 • PFS: CNS solid tumors = 9.1 months; Non-CNS solid tumors = 1.7 months • Best overall response = SD in 8/15 patients (53%; 95% CI 26.6–78.7) • Longest duration of follow-up without progression: > 27 months (N=1) • Most common AEs: cytopenia, fatigue, nausea Further Confidence : Prior Studies Suggest Potential Therapeutic Benefit 0 1 2 3 4 5 6 7 8 9 10 Overall Non-CNS solid tumors CNS solid tumors Months Progression-Free Survival 9.1m 1.7m 3.6m Clinical: NF2 Well understood clinical safety ... Multiple investigator-initiated studies in oncology indications Lengthy human clinical exposure in NF2 – multiple patients on drug for several years Well-characterized side effect profile … with a drug-like profile Established and scalable API manufacturing process Multiple cGMP batches of 10mg and 50mg tablets have been manufactured Excellent long-term stability 43
44 REC-2282 Appears Well Suited for NF2 vs Other HDAC Inhibitors 1 Sborov DW, et al. A phase 1 trial of the HDAC inhibitor AR-42 in patients with multiple myeloma and T- and B-cell lymphomas. Leuk Lymphoma. 2017 Oct;58(10):2310-2318. 2 Collier KA, et al. A phase 1 trial of the histone deacetylase inhibitor AR-42 in patients with neurofibromatosis type 2-associated tumors and advanced solid malignancies. Cancer Chemother Pharmacol. 2021 May;87(5):599-611. 3 Prescribing Information of Vorinostat/Belinostat/Romidepsin respectively Clinical: NF2 REC-2282 Would be First-In-Class HDAC Inhibitor for Treatment of NF2 Meningiomas 44
POPLAR Clinical Trial : REC-2282 for NF2 Part A Underway Phase 2/3 trial initiated in Q2, 2022 Outcome Measures Enrollment Criteria • MRI-confirmed progressive meningioma • Either of the below • Sporadic meningioma with confirmed NF2 mutation • Confirmed diagnosis of NF2 disease • Primary: Safety and tolerability • Progression-free survival • Time to progression • Duration of response • Overall response rate https://clinicaltrials.gov/ct2/show/NCT05130866 Clinical: NF2 Screening & Randomization 1:1 Treatment Follow-up Agreement on Phase 3 registration plans FDA Mtg Phase 2 (Cohort A) Phase 3 (Cohort B) Interim Analysis ▪ At 50% of events ▪ For Sample size re-estimation (i.e., adaptive design) • Enrollment is progressing • Safety, tolerability, PK, & preliminary efficacy expected in H2, 2024 Trial Update 45 Enroll 60 26 Month Tx Period Extension Study 6-month Tx Period (Interim Analysis) Extension Study 60 mg TIW 40 mg TIW Enroll ~ 20 ▪ Go/No-go to Ph3 ▪ Safety/Tolerability ▪ PK ▪ PFS Cohort A Final Data
REC-4881 for the Treatment of Familial Adenomatous Polyposis (FAP) Target / MOA MEK Inhibitor Molecule Type Small Molecule Lead Indication(s) Familial Adenomatous Polyposis Status Phase 2 Designation(s) Fast Track; US and EU Orphan Drug Source of Insight Recursion OS
47 TUPELO Clinical Trial : REC-4881 for FAP Phase 2 Underway Clinical: FAP Polyps Found in Colon and Upper GI Tract Inactivating mutations in the tumor suppressor gene APC PATHOPHYSIOLOGY & REASON TO BELIEVE KEY ELEMENTS • Targeting classical FAP patients (with APC mutation) • MEK inhibitor, small molecule • Oral dosing • Phase 2 trial initiated in Q3 2022 • Fast-Track and US & EU Orphan Drug Designation Polyps throughout the GI tract with extremely high risk of malignant transformation Efficacy in the Recursion OS showed specific MEK 1/2 inhibitors had an effect in context of APC LOF. Subsequent APCmin mouse model showed potent reduction in polyps and dysplastic adenomas No approved therapy • Colectomy during adolescence (with or without removal of rectum) is standard of care • Post-colectomy, patients still at significant risk of polyps progressing to GI cancer • Significant decrease in quality-of-life post-colectomy (continued endoscopies, surgical intervention) Diagnosed US + EU5~50,000 PREVALENCE & STANDARD OF CARE CAUSE
48 Disease Overview : Familial Adenomatous Polyposis Patient Population – Easily Identifiable Clinical: FAP ~50,000 Diagnosed US + EU5 patients • Autosomal dominant tumor predisposition syndrome caused by a mutation in the APC gene • Classic FAP (germline mutation) : • Hundreds to thousands of polyps in colon and upper GI tract • Extraintestinal manifestations (e.g., desmoid tumors) • 100% likelihood of developing colorectal cancer (CRC) before age 40, if untreated Polyps Found in Colon and Upper GI Tract 48 https://www.hopkinsmedicine.org/health/conditions-and-diseases/familial-adenomatous-polyposis
49 Disease Overview : Familial Adenomatous Polyposis – Standard of Care No Approved Medical Therapy • Standard of care: colectomy during adolescence (with or without removal of rectum) • Post-colectomy, patients still at significant risk of polyps progressing to GI cancer • Significant decrease in quality-of-life post-colectomy: continued endoscopies and surgical intervention Polyps on mucosal membrane of colon Cross section of colon and rectum Multiple polyps in the colon Sigmoidoscope Scope view Clinical: FAP “Despite progress with surgical management, the need for effective therapies for FAP remains high due to continued risk of tumors post-surgery” - Niloy Jewel Samadder, MD, Mayo Clinic https://www.hopkinsmedicine.org/health/conditions-and-diseases/familial-adenomatous-polyposis 49
50 REC-4881 rescued phenotypic defects of cells with APC knockdown 0.1 µM REC-4881 Insight from OS : Rescued Loss of APC, Inhibited Tumor Growth • Compared to thousands of other molecules tested, REC-4881 rescued phenotypic defects substantially better (including better rescue than other MEK inhibitors) for APC specific knockdown • Findings validated in tumor cell lines and spheroids grown from human epithelial tumor cells with APC mutation • 1,000x more selectivity in tumor cell lines with APC mutation • Inhibited growth and organization of spheroids APC knockdown cellsHealthy Cells Clinical: FAP 50
51 Jeon, WJ, et al. (2018). Interaction between Wnt/β-catenin and RAS-ERK pathways and an anti-cancer strategy via degradations of β-catenin and RAS by targeting the Wnt/β-catenin pathway. npj Precision Oncology, 2(5). 3 3 REC-4881 inhibits MEK 1/2 and recovers the destabilization of RAS by the β-Catenin destruction complex, restoring the cell back to a Wnt-off like state 2 1 Orally Bioavailable, Small Molecule MEK Inhibitor Disease State REC-4881 Impact MoA : REC-4881 Blocks Wnt Mutation Induced MAPK Signaling Clinical: FAP 51
52 Further Confidence : Preclinical Studies Confirming Reduction in Polyp Count and High-Grade Dysplasia APC, adenomatosis polyposis coli; ERK, extracellular signal-regulated kinase; FAP, familial adenomatous polyposis. Clinical: FAP ↓ High-Grade Dysplasia 2• In-vivo efficacy in APCmin mouse model • Apcmin = FAP disease model • Mice treated once daily for 8 weeks After 8 weeks of treatment: ↓ Polyp Count1 1 2 To ta l P o ly p C o u n t (+ /- S EM ) H ig h G ra d e A d e n o m as ( % ) 52
53 Note: AE, adverse event; MEK, mitogen-activated protein kinase; NHV, normal healthy volunteer; pERK, phosphorylated extracellular signal-regulated kinase; SAE, serious adverse event. REC-4881-101: Single-center, double-blind, placebo- controlled, dose-escalation study in healthy volunteers • Group 1 (n=13): Food effect crossover (REC-4881 4 mg/PBO [fed/fasted]), followed by single dose REC-4881 8 mg/PBO [fed] • Group 2 (n=12): Matched single ascending dose (REC- 4881 4 mg/PBO; REC-4881 8 mg/PBO; REC-4881 12 mg/PBO) Accomplished Further Confidence : Clinical Data Generated by Recursion Clinical: FAP Recursion formulation yields exposures comparable to Takeda’s formulation (molecule in-licensed from Takeda) No food effect Dose proportional increases in exposure Similar to C20001 study, observed pERK inhibition (i.e., target engagement) at 8 mg and 12 mg doses Acceptable safety profile 53
54 TUPELO Clinical Trial : REC-4881 for FAP Phase 2 Underway Clinical: FAP Phase 2 trial initiated in Q3, 2022 Outcome Measures Enrollment Criteria • Confirmed APC mutation • Post-colectomy/proctocolectomy • No GI cancer present • Polyps in either duodenum (including ampulla of vater) or rectum/pouch • Primary: • Part 1: PK • Part 2: polyp burden (% change from baseline) • Secondary: • Part 1: Safety & tolerability • Part 2: PK; PD; change from baseline in polyp number, histological grade, disease score https://clinicaltrials.gov/ct2/show/NCT05552755, protocol amendments made to enhance quality and accelerate the pace of the trial 54 Screening & Randomization 1:1 Treatment Safety, Tolerability, PK in up to 7 participants Trial Update • Enrolled multiple participants with updated trial design • Safety, tolerability, PK, & preliminary efficacy expected in H1, 2025 PK / PD / Safety RP2D Assessment Dose Expansion (N~30) at RP2D • Futility Assessment • Go/No-Go Option to rollover if eligible 12 mg QD (n ≤ 6) 8 mg QD (n ≤ 6) Part 1 Part 2 4 mg (5 active / 2 pbo)
REC-4881 for the Treatment of Solid Tumors with AXIN1 or APC Mutant Cancers Target / MOA MEK Inhibitor Molecule Type Small Molecule Lead Indication(s) Solid Tumors with AXIN1 or APC Mutant Cancers Status Phase 2 Source of Insight Recursion OS
56 LOF mutations in AXIN1 or APC tumor suppressor genes PATHOPHYSIOLOGY & REASON TO BELIEVE Alterations in the WNT pathway are found in a wide variety of tumors and confer poor prognosis and resistance to standard of care Substantial need for developing therapeutics for patients harboring mutations in AXIN1 or APC, as these mutations are considered undruggable Treatable US + EU5~65,000 PREVALENCE & STANDARD OF CARE CAUSE Efficacy in the Recursion OS and favorable results in PDX models harboring AXIN1 or APC mutations vs wild-type leading to a significant PFS benefit in HCC and Ovarian tumors Gross morphology of HCC KEY ELEMENTS • Targeting AXIN1 or APC mutant cancers • MEK inhibitor, small molecule • Oral dosing • IND accepted by FDA • Expect to initiate Phase 2 study in Q4, 2023 To our knowledge, REC-4881 is the only industry sponsored small molecule therapeutic designed to enroll solid tumor patients harboring mutations in AXIN1 or APC Clinical Program : REC-4881 for AXIN1 or APC Mutant Cancers Clinical: AXIN1 or APC
57 Disease Overview : AXIN1 or APC Mutant Cancers • Sustained Wnt signaling is a frequent driver event found across a wide variety of solid tumors • Dysregulation of β-catenin destruction complex due to inactivating mutations in AXIN1 or APC leads to sustained Wnt signaling promoting cancer progression and survival1 • AXIN1 or APC mutant solid tumors are considered clinically aggressive and resistant to standard treatments 1 Bugter, J.M., et al. Nat Rev Cancer, 2021, 21, pp.5-21 Gross morphology of HCC tumor Clinical: AXIN1 or APC “Nothing in HCC has immediate therapeutic relevance and the most common mutations are TERT, TP53, and Wnt (CTNNB1/AXIN1/APC) and combined these alterations define almost 80% of patients and are not targetable” - KOL, Clinical Investigator, Texas 57
58 • AXIN1 and APC genes covered by commercially available NGS panels and liquid biopsy detection assays • FDA guidance supports utility of ctDNA as patient selection for the detection of alterations for eligibility criteria and as a stratification factor for trials enrolling marker-positive and marker-negative populations3 • Multiple tumor types will inform study design and patient selection Flexible Patient Selection Strategy and Study Design 1 Obtained from cbioportal.org. 2 Represents 2L treatable population estimates; obtained from DRG. 3 https://www.fda.gov/media/158072/download Tumor Type AXIN1 Mutation Frequency1 APC Mutation Frequency1 Treatable Population2 (US+EU5) CRC 3% 70% 27,450 LUAD 4% 11% 14,000 Prostate 2% 11% 6,700 Bladder 3% 8% 5,100 HCC 12% 5% 3,100 Endometrial 8% 12% 2,600 Esophageal 2% 7% 2,600 PDAC 1% 2% 1,500 Ovarian 1% 3% 1,400 TNBC 1% 2% 300 Preclinical data with REC-4881 at clinically relevant exposures in HCC and Ovarian PDX mouse models gives confidence to pursue other mutant cancer types Clinical: AXIN1 or APC Disease Overview : AXIN1 or APC Mutant Cancers 58 ~65,000
REC-4881 Dosage Hypothesis: Rescue of AXIN1 may impact tumor progression and/or restore checkpoint sensitivity in cancers driven by AXIN1 loss Recursion Differentiation: REC-4881 rescues tumor suppressor genes APC and AXIN1 • APC and AXIN1 are negative regulators of Wnt signaling • Both proteins form part of the B-catenin destruction complex. Strong clustering suggests map recapitulation of this biology Insight from OS : Novel Insight around Established MoA Clinical: AXIN1 or APC Heat map from Recursion OS Similar Opposite 59
Further Confidence : Preclinical Studies Confirming Insight Clinical: AXIN1 or APC Note: REC-4881 dosed at 3 mg/kg QD for up to 21 days. 3 mice per treatment per model (3 x 3 x 3) design. 1 Wong, H., et al. Clin Cancer Res, 2012, 18:14, pp.3846-3855 60 -100 -80 -60 -40 -20 0 20 AXIN1 or APC wildtype AXIN1 or APC mutant 0 5 10 15 20 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 Wildtype Time (days elapsed) P ro b a b il it y o f p ro g re s s io n f re e (b y t u m o r d o u b li n g ) Vehicle (n = 52) REC-4881 (n = 45) Median PFS (days) 95% CI 7.0 9.0 (4.70 - 10.43) (6.04 - 13.41) Log-rank p value = 0.23 HR = 0.81 (95% CI 0.55 - 1.21) b 0 5 10 15 20 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 Mutant Time (days elapsed) P ro b a b il it y o f p ro g re s s io n f re e (b y t u m o r d o u b li n g ) Vehicle (n = 33) REC-4881 (n = 33) Median PFS (days) 95% CI 7.0 12.0 (4.19 - 11.70) (7.18 - 20.01) Log-rank p value < 0.001 HR = 0.49 (95% CI 0.29 - 0.83) a • Significantly greater antitumor activity observed with REC- 4881 in mutant models versus wildtype • Majority of mutant models ≥ 60% tumor growth inhibition, which is considered a benchmark for a response in the clinic1 Average Response : ~70% mutant vs ~49% wildtype Median Response: ~72% mutant vs ~48% wildtype Efficacy found in In Vivo Mice Models … 0 5 10 15 20 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 Wildtype Time (days elapsed) P ro b a b il it y o f p ro g re s s io n f re e (b y t u m o r d o u b li n g ) Vehicle (n = 52) REC-4881 (n = 45) Median PFS (days) 95% CI 7.0 9.0 (4.70 - 10.43) (6.04 - 13.41) Log-rank p value = 0.23 HR = 0.81 (95% CI 0.55 - 1.21) b 0 5 10 15 20 0. 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 Mutant Time (days elapsed) P ro b a b il it y o f p ro g re s s io n f re e (b y t u m o r d o u b li n g ) Vehicle (n = 33) REC-4881 (n = 33) Median PFS (days) 95% CI 7.0 12.0 (4.19 - 11.70) (7.18 - 20.01) Log-rank p value < 0.001 HR = 0.49 (95% CI 0.29 - 0.83) a Tu m o r G ro w th (% C h an ge v s V eh ic le ) … Led to Significant Progression Free Survival
Phase 2 Trial Design : REC-4881 for AXIN1 or APC Mutant Cancers Expect Phase 2 initiation in Q4, 2023 Outcome Measures Enrollment Criteria • Unresectable, locally advanced, or metastatic cancers • AXIN1 or APC mutation confirmed by NGS (tissue or blood) • CRC patients must be RAS / RAF wildtype • No MEK inhibitor treatment within 2 months of initial dose • ≥ 1 prior line of therapy • ECOG PS 0-1 • Primary • Safety/tolerability • ORR (RECIST 1.1) • Secondary • PK • Additional efficacy parameters Clinical: AXIN1 or APC AXIN1 (n = 10) APC (n = 10) Screening & Treatment • First clinical trial for an oncology indication at Recursion • IND accepted by FDA Trial Update 61 Futility Assessment AXIN1 (n = 20) APC (n = 20) All patients will receive 12 mg QD Once 10 pts enrolled in each cohort with ≥ 1 scan post-baseline Futility Assessment Enroll 20 Part 1 Part 2
REC-3964 for the Treatment of C. Difficile Infection Target / MOA Selective C. diff Toxin Inhibitor Molecule Type Small Molecule Lead Indication(s) C. Difficile Infection Status Phase 1 Source of Insight Recursion OS
63 Colleen – lived with rCDI C. difficile toxins from colonizing bacterium causes degradation of colon cell junction, toxin transit to bloodstream, and morbidity to host PATHOPHYSIOLOGY & REASON TO BELIEVE Highly recurrent infectious disease with severe diarrhea, colitis, and risk of toxic megacolon, sepsis, and death Diagnosed US + EU5~730,000 PREVALENCE & STANDARD OF CARE CAUSE Recursion OS identified a new chemical entity for recurrent C. difficile infection and potentially prophylaxis via glycosyl transferase inhibition with potential to be orally active KEY ELEMENTS • Phase 1 PK study complete • REC-3964 has been well tolerated and no safety issues have been identified to date • Complete safety and PK data readout expected Q3, 2023 • Selective C. diff toxin inhibitor, small molecule • Non-antibiotic approach with potential for combination with SOC and other therapies • Designed for selective antitoxin pharmacology to target infection • FIH Phase 1 trial initiated in Q3 2022 TRIAL UPDATE Standard of care includes antibiotic therapies which can further impair gut flora, and lead to relapse Clinical Trial : REC-3964 for C. Difficile Phase 1 study complete Clinical: C. Difficile
Source, CDC *NAAT = Nucleic Acid Amplification Test; **rCDI = recurrent CDI • RCDI** occurs in 20-30% of patients treated with standard of care • 40% of those patients will continue to recur with 2+ episodes • >29,000 patients die in the US each year from CDI • Cost burden of up to $4.8bn annually 64 Disease Overview : C. Difficile Infection (CDI) Patient Population – Large, Diagnosable and Easy to Identify Large, Unmet Need with Significant Cost Burden • Symptoms caused by clostridioides difficile tissue-damaging toxins released in the colon • Patients who experience >3 unformed stools are diagnosed via NAAT* for toxin gene or positive stool test for toxins • Patients who are at highest risk are those on antibiotics, and frequently visit hospitals or are living in a nursing home • More than 80% of cases occur among patients age 65 or older Clinical: C. Difficile ~730,000 Diagnosed US + EU5 patients Colleen – lived with rCDI 64
65 Disease Overview : C. Difficile Infection (CDI) Disruption of microbiota and colonization of C. diff Release of C. diff toxins Degradation of colon cell junction & toxin transit to bloodstream Clinical: C. Difficile Source: McCollum, D,, Rodriguez, JM . Detection, Treatment, and Prevention of Clostridium difficile Infection. Clinical Gastroenterology and Hepatology 2012 Mar 19. https://doi.org/10.1016/j.cgh.2012.03.008 65 1 2 3
REC-3964 identified as a NCE that demonstrated strong rescue in HUVEC cells treated with C. diff toxin Insight from OS : REC-3964 Rescued Cells Treated with C. Difficile Toxins C. diff toxin B phenotype Healthy Control Disease State Healthy Cells REC-3964 0.1 µM Clinical: C. Difficile 66
REC-3964 : Selective Inhibitor of C. Difficile Toxins Clinical: C. Difficile The glucosyltransferase locks Rho family GTPases in the inactive state C.diff toxins bind to cell surface receptors and trigger endocytic event 1 Autocatalytic cleavage event releases C.diff toxin's glucoyltransferase enzymatic domain into the cytosol of the infected cell 2 3 3 1 2 Inactivation of Rho GTPases alters cytoskeletal dynamics, induces apoptosis, and impairs barrier function which drives the pathological effects of C.diff infection 4 4 REC-3964 is Recursion’s 1st Small Molecule NCE to Reach the Clinic 67Adapted from Awad et al. 2014
Adapted from Awad, MM. et al. (2014). Clostridium difficile virulence factors: Insights into an anaerobic spore-forming pathogen. Gut Microbes. 5(5), 579-593. REC-3964 : Selective Inhibitor of C. Difficile Toxins Clinical: C. Difficile 3 1 2 4 REC-3964 binds and blocks catalytic activity of the toxin’s innate glucosyltransferase, but not the host's 5 5 REC-3964 is Recursion’s 1st Small Molecule NCE to Reach the Clinic 68
Further Confidence : Preclinical Studies Confirmed Recursion OS Insight ✓ REC-3964 restores gut epithelial barrier integrity, which when disrupted causes inflammation and diarrhea REC-3964 rescues barrier integrity with increasing concentrations REC-3964 improved probability of survival in a hamster model of C. difficile infection ✓ Improved probability of survival beyond treatment completion Clinical: C. Difficile Healthy Monolayer (100%) Toxin-Damaged Monolayer (0%) REC-3964 Concentration (Log μM) R e si st an ce ( n o rm al iz e d % ) 69
70 Clinical Trial : REC-3964 for C. Difficile Phase 1 study complete Phase 1 FIH SAD/MAD Trial initiated in Q3 2022 Trial Design • Randomized, Double-blind Trial Population • Healthy Subjects • SAD (n = 56) • MAD (n = 50) Primary Objectives ✓ Assess the safety & tolerability of SAD and MAD of REC-3964 ✓ Evaluate the PK profile of REC-3964 after single and multiple doses Clinical: C. Difficile • REC-3964 has been well tolerated and no safety issues have been identified to date • Expect to share complete safety and PK data readout in Q3, 2023 Trial Update 70 • Evaluating the potential of conducting a PoC study in patients • Exploring partnering opportunities Next Steps
RBM39: Novel CDK12-Adjacent Target for HR-Proficient Ovarian Cancer 71 RBM39 CDK12 2.5μM 1.0μM REC-65029 0.1μM 0.25μM CDK13 REC-65029 Similar Opposite BRCA-proficient ovarian cancer PDX Preclinical: HR-Proficient Ovarian Cancer Identify potential first-in-class tumor-targeted precision therapeutic NCE with novel MOA capable of potentially treating HR-proficient ovarian cancer Inhibition of target RBM39 (previously referred to as Target γ) may mimic the inhibition of CDK12 while mitigating toxicity related to CDK13 inhibition A Recursion-generated NCE showed single agent efficacy that is enhanced in combination with Niraparib in a BRCA-proficient PDX model IND-enabling studies are progressing GOAL INSIGHT FROM OS FURTHER CONFIDENCE NEXT STEPS Vehicle Niraparib REC-204 100 mpk REC-204 100 mpk + Niraparib OV0273 (PDX) in-vivo efficacy Survival data Note: in the OV0273 PDX model, mice were treated with a representative lead molecule REC-1170204 (100 mg/kg, BID, PO) ± Niraparib (40 mg/kg, QD, PO) for 32 days. Single agent REC-1170204 or in combination with Niraparib resulted in a statistically significant response vs either Niraparib or vehicle arms. In addition, there was a statistically significant improvement in survival > 30 days post final dose. *p<0.05, ** p<0.01, **** p<0.0001
72 Partnerships Recursion OS Partnership Strategy Partner in complex therapeutic areas requiring large financial commitment and competitive market dynamics Leverage partner knowledge and clinical development capabilities Fibrosis Other large, intractable areas of biology Neuroscience* Pipeline Build internal pipeline in indications with potential for accelerated path to approval Pipeline Strategy Precision Oncology Rare Disease Data License subsets of data and tools Direct generation of new data internally to maximize pipeline and partnership value-drivers Data Strategy Licensing Augment Recursion OS *Includes a single oncology indication from our Roche and Genentech collaboration. Harnessing value with a multi-pronged capital-efficient business strategy
Fibrosis Neuroscience *and a single oncology indication • $30M upfront and $50M equity investment • Up to or exceeding $1.2B in milestones for up to or exceeding 12 programs • Mid single-digit royalties on net sales • Recursion owns all algorithmic improvements • $150M upfront and up to or exceeding $500M in research milestones and data usage options • Up to or exceeding $300M in possible milestones per program for up to 40 programs • Mid to high single-digit tiered royalties on net sales • Recursion owns or co-owns all algorithmic improvements Our existing partnerships represent some of the most significant scientific collaborations in TechBio across biopharma and tech (Announced Sep 2020; Expanded Dec 2021) (Announced Dec 2021) Trademarks are the property of their respective owners and used for informational purposes only. 73 Computation and ML/AI (Announced July 2023) • $50M equity investment • Partnership on advanced computation (e.g. foundation model development) • Priority access to compute hardware or DGXCloud Resources • Potential to house Recursion Tools on NVIDIA’s BioNeMo Marketplace
Harnessing value with a capital efficient business strategy 74 Partnerships Recursion OS Partnership Strategy Partner in complex therapeutic areas requiring large financial commitment and competitive market dynamics Leverage partner knowledge and clinical development capabilities Fibrosis Other large, intractable areas of biology Neuroscience* Pipeline Build internal pipeline in indications with potential for accelerated path to approval Pipeline Strategy Precision Oncology Rare Disease Data License subsets of data and tools Direct generation of new data internally to maximize pipeline and partnership value-drivers Data Strategy Licensing Augment Recursion OS *Includes a single oncology indication from our Roche and Genentech collaboration.
75 Data that is relatable and scalable is the Recursion differentiator Recursion Data Universe: >25 PB of proprietary biological and chemical data, spanning phenomics, transcriptomics, invivomics, and more • We believe one of the largest biological and chemical datasets fit for the purpose of training large-scale ML models RXRX3: CRISPR knockouts of most of the human genome, 1,600 FDA approved / commercially available bioactive compounds • We believe the largest public dataset of its kind, <1% of Recursion Data Universe, what Recursion can generate in ~1 week MolRec™️: freemium web-based application to explore compound and gene relationships in RXRX3 Start working with RXRX3 and MolRec™️: www.rxrx.ai Phenomics data spanning >200 million experiments and 50 human cell types InVivomics Video Data >450K Transcriptomics Experiments ADMET & More Re cu rs io n D at a U ni ve rs e, > 25 P B <1% Dataset Released Number of Samples Bio/Chem Phenomic Maps RxRx3 2023 2.2M JUMPCP 2023 823,438 Autonomous Driving Waymo Open Dataset 2018 ~105,000 nuScenes 2018 1,000 Image/Object recognition ImageNet (21k) 2009 14M COCO 2014 330,000 ~100 TB ~1 -5 TB ~10 GB -~1 TB
Value driven by our team and our milestones
Advanced degreesEmployees Team Members >550 What it takes to make this happen – a new kind of team and culture >50% ESG Highlights ✓ ESG reporting on Healthcare and Technology Metrics ✓ 100% of electricity powering our Biohive-1 supercomputer comes from renewable sources ✓ Learn more about Recursion’s ESG stewardship: www.recursion.com/esg ~43% Female Male ~56% ~1% Non-Binary Parity Pledge Signer gender parity and people of color parity Life Sciences – biology, chemistry, development, etc. Technology – data science, software engineering, automation, etc. Strategic Operations Community Impact Committed to ESG Excellence Founding Partner, Life Science Accelerator Founding Member, Life Science Collective 77 Data shown reflective of Q2 2023 and includes Cyclica and Valence acquisitions, gender statistics include participating individuals
Trademarks are the property of their respective owners and used for informational purposes only. Our leadership team brings together experience & innovation to lead TechBio 78 Board of Directors Dean Li, MD PHD Co-Founder of RXRX, President of Merck Research Labs Rob Hershberg, MD PHD Co-Founder/CEO/Chairman of HilleVax, Former EVP/CSO/CBO of Celgene Blake Borgeson, PHD Co-Founder of RXRX Terry-Ann Burrell, MBA CFO & Treasurer, Beam Therapeutics Zavain Dar Co-Founder & Partner of Dimension R Martin Chavez, PHD Chairman of RXRX, Board Member of Alphabet, Vice-Chairman of 6th Street, Former CFO/CIO of GS Zachary Bogue, JD Co-Founder & Partner of Data Collective Chris Gibson, PHD Co-Founder & CEO STRICTLY CONFIDENTIAL 78 Tina Larson President & COO Executive Team Heather Kirkby, MBA Chief People Officer Ben Mabey Chief Technology Officer Kristen Rushton, MBA SVP of Business Operations Michael Secora, PHD Chief Financial Officer Chris Gibson, PHD Co-Founder & CEO Shafique Virani, MD FRCS Chief Business Officer Nathan Hatfield, JD MBA Chief Legal Officer Laura Schaevitz, PHD SVP and Head of Research David Mauro, MD PHD Chief Medical Officer
Strong Financials ~$406M in cash at the end of Q2, 2023 (does not include $50M NVIDIA investment) Near-Term • Potential option exercises for partnership programs • Potential option exercises for map building initiatives or data sharing • Potential for additional partnership(s) in large, intractable areas of biology and / or technological innovation • Ph1 clinical trial readout for C. difficile Infection program expected Q3, 2023 • Ph2 trial initiation for AXIN1 or APC mutant cancers program expected in Q4, 2023 • Potential to accelerate value creation with proprietary foundation models for biology and chemistry • Potential to open-source data and tools for non- commercial use and license data and tools to biopharma and other commercial users What to watch for at Recursion Medium-Term • Multiple Ph2 readouts for AI-discovered programs • CCM top-line data expected H2, 2024 • NF2 & FAP safety & preliminary efficacy expected H2, 2024 & H1, 2025, respectively • Potential for additional INDs and clinical starts • Potential option exercises for partnership programs • Potential option exercises for map building initiatives or data sharing • Potential additional partnership(s) in large, intractable areas of biology and / or technological innovation • Recursion OS moves towards autonomous map building and navigation with digital and micro-synthetic chemistry Upcoming Potential Milestones 79Cash refers to cash and cash equivalents
Impact 80
Additional scientific and business context
Images adapted from Jayatunga, M., et al. Nature Reviews Drug Discovery 2022. The biopharmaceutical industry faces pressure amidst declining efficiency in drug discovery 82 Top-20 Pharma Companies AI-Native Drug Discovery Companies AI-enabled drug discovery efforts have proliferated alongside the declining efficiency of traditional approaches 705 768 708 602 575 641 686 709 519 439 393 333 0 500 1,000 1,500 2,000 2,500 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 Discovery / Preclinical Phase I Phase II Phase III 6 2 4 6 10 18 23 28 56 121 119 158 0 50 100 150 200 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 N u m b er o f C lin ic al a n d P re cl in ic al A ss e ts N u m b er o f C lin ic al a n d P re cl in ic al A ss e ts
83 We build biological and chemical datasets to map relationships across scales and understand the connectivity of the system Image adapted from D’Orazio, M., et al. Nature Scientific Reports 2022. RNA Level Transcriptomics DNA Level (Population-Scale) Genomics Protein Level Proteomics Metabolites Level Metabolomics Organism Level InVivomics Cell Level Phenotypes Phenomics Built and scaled AspirationalExploratory Like digital maps of Earth, connections within and between layers add useful context. Similarly, Recursion is mapping different multiomic layers of biology and identifying connections within and between layers to better understand biology at scale.
50 different human cell types small molecule library, we believe this scale is on par with some large pharma companies hiPSC-derived cells produced since 2022, we believe that we are one of the largest hiPSC- derived cell producers ~1.7 Million ~850 Billion Diverse Biological and Chemical Inputs Robotic Automation at Scale Up to 2.2 Million wet-lab experiments per week profiling genes and compounds, we believe we are one of the largest phenomics (human cellular image-based) data producers Digitization of Biology and Chemistry >25 Petabytes of proprietary high- dimensional data as of this filing, we believe this is one of the largest relatable in vitro biological and chemical datasets ML-Based Analysis Top 500 supercomputer across any industry (TOP500 List, Jun 2023), we leverage vast neural networks and multiomics approaches to extract features and drive insights relatable hypotheses across multiple biological and chemical contexts ML-Based RelationshipsHigh-Dimensional Validation 24K Up to 84 Top 500 >25 Petabytes2.2 Million / Week near whole exomes per week, we believe we are one of the largest transcriptomics data producers ~4 Trillion Novel Insights at Scale Enables quality, relatability and scale of data Recursion OS Metrics shown reflective of Q2 2023 unless otherwise indicated
This is a whole-genome arrayed CRISPR knock-out Map generated in primary human endothelial cells Every gene is represented in a pairwise way (each is present in columns and rows) Dark Red indicates phenotypic similarity according to our neural networks while Dark Blue indicates phenotypic anti- similarity (which in our experience often suggests negative regulation) We can add the phenotypes of hundreds of thousands of small molecules at multiple doses and query and interact with these maps using a web application Thousands of examples of known biology and chemistry 85 All Human Genes with Significant Effects in this Cellular Context → A ll H u m an G en es w it h S ig n if ic an t Ef fe ct s in t h is C el lu la r C o n te xt → Genome-scale mapping
One such example – the JAK / STAT pathway clustered by strength of interaction, including both similar genes (red) and opposite genes (blue) Can wade into areas of novel biology and chemistry… 86 JAK1 TNKS1BP1 PPP1R9B PHF13 SOCS3 PRKCH MEGF8 ASB7 SLC39A1 DOCK9 ZMYM3 FAM49B STK24 YWHAB IL6ST IL6R STAT3 IL6 JA K 1 IL 6 ST A T3 IL 6 R IL 6 ST YW H A B ST K 2 4 FA M 4 9 B ZM YM 3 TN K S1 B P 1 P P P 1 R 9 B P H F1 3 SO C S3 P R K C H M EG F8 A SB 7 SL C 3 9 A 1 D O C K 9
Maps reveal known and novel biology Trademarks are the property of their respective owners and used for informational purposes only. 87 INTS9 INTS11 INTS4 INTS7 INTS2 INTS8 INTS1 INTS6 C7orf26 INTS10 INTS13 INTS14 IN TS 1 4 IN TS 1 3 IN TS 1 0 C 7 o rf 2 6 IN TS 6 IN TS 1 IN TS 8 IN TS 2 IN TS 7 IN TS 4 IN TS 1 1 IN TS 9 Phenomics TVN (below diagram) vs. Centerscale (above diagram) Similar Opposite • In 2022, new independent research identified a previously unknown gene, C7orf26, as part of the Integrator complex • Maps jointly developed by Recursion and Genentech replicated this same result • Demonstrates accuracy and consistency across different map building approaches
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1 Includes approximately 500,000 compounds from Bayer’s proprietary library. 2 ‘Predicted Relationships’ refers to the number of Unique Perturbations that have been predicted using our maps. Biology and chemistry are complex – data that is reliable, relatable, and scalable is the Recursion differentiator 89 Year 2018 2019 2020 2021 2022 Total Phenomics Experiments (Millions) 8 24 56 115 175 Total Transcriptomics Experiments (Thousands) NA NA 2 91 258 Data (PB) 1.8 4.3 6.8 12.9 21.2 Cell Types 12 25 36 38 48 Unique Compounds Physically Housed at Recursion1 (Millions) 0.02 0.1 0.7 1.0 1.7 In Silico Chemistry Library (Billions) NA 0.02 3 12 >1,000 Predicted Biological and Chemical Relationships2 (Trillions) NA NA 0.01 0.2 3.1
• Recursion demonstrated that CRISPR-Cas9 editing induces chromosome arm-scale truncations across the genome • Creates a proximity bias in CRISPR screens which can confound some gene-gene relationships • Recursion demonstrated a correction method leveraging public CRISPR-Cas9 knockout screens to mitigate bias • Read “High-resolution genome-wide mapping of chromosome-arm-scale truncations induced by CRISPR-Cas9 editing” at www.biorxiv.org • Already in the top 5% of research outputs in online engagement www.altmetric.com CRISPR proximity bias revealed using genome-wide phenomics screens
Drug Prediction Correct? Hydroxychloroquine x ✓ Lopinavir x ✓ Ritonavir x ✓ Remdesivir ✓ ✓ Baricitinib ✓ ✓ Tofacitinib ✓ ✓ Ivermectin x ✓ Fluvoxamine x ✓ Dexamethasone x x COVID-19 research 91https://www.biorxiv.org/content/10.1101/2020.04.21.054387v1 • Recursion conducted several AI-enabled experiments in April 2020 to investigate therapeutic potential for COVID-19 - Included FDA-approved drugs, EMA-approved drugs, and compounds in late-stage clinical trials for the modulation of the effect of SARS-CoV-2 on human cells • Experiments were compiled into the RxRx19 dataset (860+ GB of data) and made publicly available to accelerate the development of methods and pandemic treatments. • Recursion OS correctly predicted 8 of 9 clinical trials associated with early and late-stage COVID-19
Program 1 Program 1 Program 1 Program 1 Program 1 Program 1 Program 1 Transformational collaborations provide multiple potential value inflection points Illustrative example of potential value inflection points Clinical and Approval Milestones Pre-Clinical Milestones Upfront Fee Programs 2 through N Programs 2 through N Programs 2 through N Programs 2 through N Programs 2 through N Collaboration Timeline Programs 2 through N Programs 2 through N Royalties & Commercial Milestones Programs 2 through N Value Program 1 Program 1 Program 1 Program 1 Program 1 Program 1 Program 1 Programs 2 through N Programs 2 through N Technical and Map-Based Milestones Programs 2 through N Programs 2 through N 92