Translation - Cell Therapies of the Future with Dan Goodman

Cell Therapies of the Future with Dan Goodman

11/09/22 • 98 min

Episode Summary

Chimeric antigen receptors, or CARs, repurpose the build-in targeting and homing signals of our immune system to direct T cells to find and eliminate cancers. Although CAR-T cells have transformed the care of liquid tumors in the circulating blood, like B cell leukemia and lymphoma, CAR-T therapy has shown limited efficacy against solid tumors. To unlock the full potential of CAR-T therapies, better receptor designs are needed. Unfortunately, the space of potential designs is too large to check one by one. To design better CARs, Dan and his co-author Camillia Azimi developed CAR Pooling, an approach to multiplex CAR designs by testing many at once with different immune costimulatory domains. They select the CARs that exhibit the best anti-tumor response and develop novel CARs that endow the T cells with better anti-tumor properties. Their methods and designs may help us develop therapies for refractory, treatment-resistant cancers, and may enable CAR-T cells to cure infectious diseases, autoimmunity, and beyond.

About the Author

During his PhD in George Church’s lab at Harvard Medical School, Dan studied interactions between bacterial transcription and translation, built and measured libraries of tunable synthetic biosensors, and constructed a new version of the E. coli genome capable of incorporating new synthetic amino acids into its proteins. He also built a high-throughput microbial genome design and analysis software platform called Millstone.
As a Jane Coffin Childs Postdoctoral Fellow at UCSF, Dan is currently applying these high-throughput synthetic approaches to engineer T cells for the treatment of cancer and autoimmune disease. He is also working in the Bluestone, Roybal, and Marson labs.

Key Takeaways

By genetically engineering the chimeric antigen receptor (CAR), T cells can be programmed to target new proteins that are markers of cancer, infectious diseases, and other important disorders.
However, to realize this vision, more powerful CARs with better designs are needed - current CAR-T therapies have their restraints, including limited performance against solid tumors and lack of persistence and long-term efficacy in patients.
An important part of the CAR response is “costimulation,” which is mediated by the 4-1BB or CD28 intracellular domains in all CARs currently in the clinic. Better designs of costimulatory domains could unlock the next-generation of CAR-T therapies.
Since there are so many possibilities for costimulatory domain designs, it’s difficult to test them all in the lab.
Based on his experience in the Church Lab, Dan has developed tools to “multiplex” biological experiments; that is, to test multiple biological hypotheses in the same experiment and increase the screening power.
Dan and his co-author Camillia Azimi developed “CAR Pooling”, a multiplexed approach to test many CAR designs at once.
Using CAR Pooling, Dan tested 40 CARs with different costimulatory domains in pooled assays and identified several novel cosignaling domains from the TNF receptor family that enhance persistence or cytotoxicity over FDA-approved CARs.
To characterize the different CARs, Dan also used RNA-sequencing.

Impact

The CAR Pooling approach may enable new, potent CAR-T therapies that can change the game for solid tumors and other cancers that are currently tough to treat.
Highly multiplexed approaches like CAR Pooling will allow us to build highly complex, programmable systems and design the future of cell engineering beyond CAR-T.
In addition to new therapeutics, high-throughput studies will allow us to understand the “design rules” of synthetic receptors and improve our understanding of basic immunology.

Paper: Pooled screening of CAR T cells identifies diverse immune signaling domains for next-generation immunotherapies

Episode Summary

About the Author

During his PhD in George Church’s lab at Harvard Medical School, Dan studied interactions between bacterial transcription and translation, built and measured libraries of tunable synthetic biosensors, and constructed a new version of the E. coli genome capable of incorporating new synthetic amino acids into its proteins. He also built a high-throughput microbial genome design and analysis software platform called Millstone.
As a Jane Coffin Childs Postdoctoral Fellow at UCSF, Dan is currently applying these high-throughput synthetic approaches to engineer T cells for the treatment of cancer and autoimmune disease. He is also working in the Bluestone, Roybal, and Marson labs.

Key Takeaways

By genetically engineering the chimeric antigen receptor (CAR), T cells can be programmed to target new proteins that are markers of cancer, infectious diseases, and other important disorders.
However, to realize this vision, more powerful CARs with better designs are needed - current CAR-T therapies have their restraints, including limited performance against solid tumors and lack of persistence and long-term efficacy in patients.
An important part of the CAR response is “costimulation,” which is mediated by the 4-1BB or CD28 intracellular domains in all CARs currently in the clinic. Better designs of costimulatory domains could unlock the next-generation of CAR-T therapies.
Since there are so many possibilities for costimulatory domain designs, it’s difficult to test them all in the lab.
Based on his experience in the Church Lab, Dan has developed tools to “multiplex” biological experiments; that is, to test multiple biological hypotheses in the same experiment and increase the screening power.
Dan and his co-author Camillia Azimi developed “CAR Pooling”, a multiplexed approach to test many CAR designs at once.
Using CAR Pooling, Dan tested 40 CARs with different costimulatory domains in pooled assays and identified several novel cosignaling domains from the TNF receptor family that enhance persistence or cytotoxicity over FDA-approved CARs.
To characterize the different CARs, Dan also used RNA-sequencing.

Impact

The CAR Pooling approach may enable new, potent CAR-T therapies that can change the game for solid tumors and other cancers that are currently tough to treat.
Highly multiplexed approaches like CAR Pooling will allow us to build highly complex, programmable systems and design the future of cell engineering beyond CAR-T.
In addition to new therapeutics, high-throughput studies will allow us to understand the “design rules” of synthetic receptors and improve our understanding of basic immunology.

Paper: Pooled screening of CAR T cells identifies diverse immune signaling domains for next-generation immunotherapies

Previous Episode

DNA Origami with Anastasia Ershova

Episode Summary:

DNA is an ideal molecule for storing information in our genomes because it’s stable, programmable, and well understood. The same qualities make DNA a great building block or construction material for nanoscale biomolecular structures that have nothing to do with our genome, like molecular scaffolds created by folding DNA into 2D and 3D shapes. This technology is known as DNA origami.

However, the practical applications of DNA origami are limited by spontaneous growth and poor reaction yields. Anastasia developed a method that uses crisscross DNA polymerization of single-stranded DNA slats or DNA origami tiles to assemble DNA structures in a seed-dependent manner. This work may be useful to produce ultrasensitive, next-generation diagnostics or in programmable biofabrication at the multi-micron scale.

Search Keywords: fifty years, bio, translation, ayush noori, ashton trotman grant, dna origami, dna, monomers, anastasia ershova, structures, diagnostics, proteins, micron scale, nucleation, biology, nanoscale

Episode Notes:

About the Guest

Anastasia is a PhD candidate at Harvard University, currently working on DNA nanotechnology in William Shih's lab at the Wyss Institute and Dana-Farber Cancer Institute.
She received her bachelor’s degree in Natural Sciences from Cambridge University.
During her PhD at Harvard, she co-founded the Molecular Programming Interest Group, an international community of students in the molecular programming, DNA computing and related fields.

Impact

DNA Origami will provide us with a plethora of new information on biology and physics.
By manipulating that data on the nanoscale, we can get answers to a lot of questions in the future.
Quick diagnostics can enable people all over the world to quickly get diagnosis-related answers and seek targeted treatment.

Papers

Next Episode

Demystifying Tech Transfer with Seth Bannon and Ashton Trotman-Grant

Episode Summary:

In this very special episode of Translation, Seth is joined by Ash Trotman-Grant to demystify spinning out from academia. Much of this knowledge has so far only been available to select groups of academics and PhD founders are at a disadvantage – some potentially breakthrough technologies never saw the light of day and didn’t get a chance to have a real impact. We want to bring the power of the tech transfer process back to entrepreneurial scientists.

Enter the Spinout Playbook – your complete guide to spinning out of academia. In this episode, we chat about the Playbook’s content and share useful tips for entrepreneurial academics eager to spin out their research into an impactful company. Ash shares his experience from spinning out Notch Therapeutics and, together with Seth, they offer brilliant insights into navigating the (up until now) stormy waters of the spinout process.

About the Guests

Seth is a Founding Partner at Fifty Years, a venture capital firm backing founders using technology to solve the world’s biggest problems.
Ash is a Synthetic Biologist at Fifty Years and Founder of Notch Therapeutics, a stem cell spin out company from the University of Toronto.
Ash & the Fifty Years team have created the Spinout Playbook, a living document that will help academic founders spin out their companies from universities and negotiate with Tech Transfer Offices – TTOs.

Key Takeaways

A spinout is a company that has been developed from a university's research.
The process of establishing the spinout as a new company involves multiple hurdles, like licensing patents from the tech transfer office, splitting equity among academic and full-time founders, and deciding when to leave academia.
Universities take months to sign agreements and make startups unfundable by taking too much equity.
The final licensing agreement may include counter-productive clauses that prevent the company from succeeding.
University tech transfer offices (TTOs) refuse to negotiate directly with grad students and postdocs.
For Ash, the creation of Notch Therapeutics was his first real step into the entrepreneurship world and the first encounter with the process of spinning out a company.
The Spinout Playbook, the newest Fifty Years initiative, will serve as a comprehensive guide for founders and scientists wishing to spin out a company.

Impact

The Spinout Playbook will help future founders and scientists better navigate the challenges of the process.
Previously only available to a coterie of academics, the know-how of tech transfer will allow great science to see the light of day more easily.
A transparent process can give scientists the tools and information they need to build world-changing companies, which is hard enough by itself.

The Spinout Playbook