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2024 Angelika Amon Young Scientist award winners announced

The Koch Institute at MIT is pleased to announce the winners of the 2024 Angelika Amon Young Scientist Award, Anna Uzonyi and Lukas Teoman Henneberg.

Koch Institute
September 3, 2024

The Koch Institute at MIT is pleased to announce the winners of the 2024 Angelika Amon Young Scientist Award, Anna Uzonyi and Lukas Teoman Henneberg.

The prize was established in 2021 to recognize graduate students in the life sciences or biomedical research from institutions outside the United States who embody Dr. Amon’s infectious enthusiasm for discovery science.

Both of this year’s winners work to unravel the fundamental biology of chromatin, the densely structured complex of DNA, RNA, and proteins that makes up a cell’s genetic material.

Uzonyi is pursuing her PhD at the Weizmann Institute of Science in Israel under the supervision of Schraga Schwartz and Yonatan Stelzer. In her thesis, Uzonyi focuses on deciphering the principles of RNA editing code via large-scale systematic probing.

Henneberg is a doctoral candidate in the Department of Molecular Machines and Signaling, at the Max Planck Institute of Biochemistry in Germany, works under the supervision of Professor Brenda Schulman and Professor Matthias Mann. For his research project, he probes active ubiquitin E3 ligase networks within cells. He works on the development of probes targeting active ubiquitin E3 ligases within cells and utilizing them in mass spectrometry-based workflows to explore the response of these ligase networks to cellular signaling pathways and therapeutics.

This fall, Anna Uzonyi and Lukas Teoman Henneberg, will visit the Koch Institute. The MIT community and Amon Lab alumni are invited to attend their scientific presentations on Thursday, November 14 at 2:00 p.m. in the Luria Auditorium, followed by a 3:30 p.m. reception in the KI Galleries.

Uzonyi will present on “Inosine and m6A: Deciphering the deposition and function of adenosine modifications” and Henneberg will present on “Capturing active cellular destroyers: Probing dynamic ubiquitin E3 ligase networks.

Two Whitehead Institute graduate researchers awarded the 2024 Regeneron Prize for Creative Innovation

Whitehead Institute graduate student researchers Christopher Giuliano (Lourido Lab) and Julian Roessler (Hrvatin Lab) have been awarded the 2024 Regeneron Prize for Creative Innovation.

Merrill Meadow | Whitehead Institute
July 30, 2024

Whitehead Institute graduate student researchers Christopher Giuliano and Julian Roessler have been awarded the 2024 Regeneron Prize for Creative Innovation. In addition, postdoctoral researcher Chen Weng was selected as a finalist in the postdoctoral fellows competition.

The Regeneron Prize, sponsored by global biotechnology company Regeneron Pharmaceuticals, Inc., is a competitive award designed to recognize and honor exceptional talent and originality in biomedical research. Individual graduate students and postdoctoral fellows in the biomedical sciences are nominated by the nation’s top research universities. Then, nominees outline their “Dream Projects” — potentially groundbreaking research projects that they would pursue given unrestricted access to resources and state-of-the-art technology.

The “Dream Project” proposals, presented by the nominees to a selection committee comprised of Regeneron’s leading scientists, are used to evaluate a trainee’s scientific merit, elegance, precision, and creativity. Novel research ideas and out-of-the-box thinking is encouraged — although the proposal must include a strong rationale, basic methodology and design for the project, and a discussion of how its results could advance the field. Both Giuliano and Roessler have been netbet online sports bettingawarded ,000 for their proposals, which can be used in any way the winners choose. In addition, Weng was awarded $5,000 as a finalist, and Regeneron has made a $10,000 grant to the Whitehead Institute as the home institute of the winners to support its seminar series.

This year’s awards are distinctive in that the two winners are from the same institution: Both Giuliano and Roessler are pursuing their PhDs at Massachusetts Institute of Technology (MIT) and conducting their doctoral research at Whitehead Institute.

Giuliano is a researcher in the lab of Whitehead Institute Member Sebastian Lourido, who is also an associate professor of biology at MIT and holds the Landon Clay Career Development Chair at Whitehead Institute. Giuliano’s Dream Project seeks to address the unique challenges posed by genetically based muscle disorders. “An obstacle in using current gene therapies to treat these conditions,” he explains, “is that muscle tissue comprises large syncytial cells, which contain hundreds of nuclei in a shared cytoplasm. Even when a gene therapy is able to reach an individual muscle cell, it often isn’t able to spread to every nucleus within that cell.” However, certain parasites, like Toxoplasma gondii, thrive because they have the capacity to successfully gain access to and manipulate muscle cells. T. gondii, the primary focus of the Lourido lab’s work, may infect nearly one third of all humans. “My project,” Giuliano says, “would identify the specific biological mechanisms used by the parasites to spread their virulence factor proteins throughout the cell. Using genetic screens for protein spread, we would work toward applying these protein features to improve the efficiency of muscle-directed gene therapies, and ultimately test our system in a mouse model of Duchenne muscular dystrophy.”

Roessler is a researcher in the lab of Whitehead Institute Member Siniša Hrvatin, who is also an assistant professor of biology at MIT. While Roessler’s doctoral research focuses on the neuronal circuitry underlying torpor and hibernation in small mammals, his Dream Project seeks to identify the sensory circuitry regulating the “diving reflex” displayed in land- and sea-dwelling mammals, including humans. The diving reflex occurs when an animal’s face is immersed in cold water, prompting an array of organs to reduce their function in ways that, scientists believe, privileges the flow of oxygen to the brain and muscles. “That this reflex has been conserved across millions of years of mammalian evolution suggests an extraordinary genetic advantage,” Roessler says. “Yet, researchers have given comparatively little attention to the neuronal circuits underlying this reflex, and we don’t understand even the fundamental mechanisms by which the nervous system coincidently detects both cold temperature and the presence of water.” Beyond elucidating a foundational aspect of mammalian biology, Roessler’s projects could, if pursued, underpin new interventions for conditions ranging from migraine headaches to cardiac arrhythmia that might be ameliorated by artificial stimulation or inhibition of the diving response.

Weng is a postdoctoral researcher in the lab of Whitehead Institute Member Jonathan Weissman, who is also a professor of biology at MIT, the Landon T. Clay Professor of Biology at Whitehead Institute, and an Investigator of the Howard Hughes Medical Institute. His Dream Project — which proposes a new approach to using single-cell genealogy to understand factors driving cell line evolution — is an extension of his current work. Indeed, this past year he co-developed a technology that details the family trees of human blood cells and provides new insights into the differences between lineages of hematopoietic stem cells. The technology gives researchers unprecedented access to any human cells’ histories — and a path to resolving previously unanswerable questions.

MIT affiliates named 2024 HHMI Investigators

Four faculty members and four others with MIT ties are recognized for pushing the boundaries of science and for creating highly inclusive and collaborative research environments.

School of Science
July 23, 2024

The Howard Hughes Medical Institute (HHMI) today announced its 2024 investigators, four of whom hail from the School of Science at MIT: Steven Flavell, Mary Gehring, Mehrad Jazayeri, and Gene-Wei Li.

Four others with MIT ties were also honored: Jonathan Abraham, graduate of the Harvard/MIT MD-PhD Program; Dmitriy Aronov PhD ’10; Vijay Sankaran, graduate of the Harvard/MIT MD-PhD Program; and Steven McCarroll, institute member of the Broad Institute of MIT and Harvard.

Every three years, HHMI selects roughly two dozen new investigators who have significantly impacted their chosen disciplines to receive a substantial and completely discretionary grant. This funding can be reviewed and renewed indefinitely. The award, which totals roughly $11 million per investigator over the next seven years, enables scientists to continue working at their current institution, paying their full salary while providing financial support for researchers to be flexible enough to go wherever their scientific inquiries take them.

Of the almost 1,000 applicants this year, 26 investigators were selected for their ability to push the boundaries of science and for their efforts to create highly inclusive and collaborative research environments.

“When scientists create environments in which others can thrive, we all benefit,” says HHMI president Erin O’Shea. “These newest HHMI Investigators netbet sports bettingare extraordinary, not only because of their outstanding research endeavors but also because they mentor and empower the next generation of scientists to work alongside them at the cutting edge.”

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Steven Flavell, associate professor of brain and cognitive sciences and investigator in the Picower Institute for Learning and Memory, seeks to uncover the neural mechanisms that generate the internal states of the brain, for example, different motivational and arousal states. Working in the model organism, the C. elegans worm, the lab has used genetic, systems, and computational approaches to relate neural activity across the brain to precise features of the animal’s behavior. In addition, they have mapped out the anatomical and functional organization of the serotonin system, mapping out how it modulates the internal state of C. elegans. As a newly named HHMI Investigator, Flavell will pursue research that he hopes will build a foundational understanding of how internal states arise and influence behavior in nervous systems in general. The work will employ brain-wide neural recordings, computational modeling, expansive research on neuromodulatory system organization, and studies of how the synaptic wiring of the nervous system constrains an animal’s ability to generate different internal states.

“I think that it should be possible to define the basis of internal states in C. elegans in concrete terms,” Flavell says. “If we can build a thread of understanding from the molecular architecture of neuromodulatory systems, to changes in brain-wide activity, to state-dependent changes in behavior, then I think we’ll be in a much better place as a field to think about the basis of brain states in more complex animals.”

Mary Gehring

Mary Gehring, professor of biology and core member and David Baltimore Chair in Biomedical Research at the Whitehead Institute for Biomedical Research, studies how plant epigenetics modulates plant growth and development, with a long-term goal of uncovering the essential genetic and epigenetic elements of plant seed biology. Ultimately, the Gehring Lab’s work provides the scientific foundations for engineering alternative modes of seed development and improving plant resiliency at a time when worldwide agriculture is in a uniquely precarious position due to climate changes.

The Gehring Lab uses genetic, genomic, computational, synthetic, and evolutionary approaches to explore heritable traits by investigating repetitive sequences, DNA methylation, and chromatin structure. The lab primarily uses the model plant A. thaliana, a member of the mustard family and the first plant to have its genome sequenced.

“I’m pleased that HHMI has been expanding its support for plant biology, and gratified that our lab will benefit from its generous support,” Gehring says. “The appointment gives us the freedom to step back, take a fresh look at the scientific opportunities before us, and pursue the ones that most interest us. And that’s a very exciting prospect.”

Mehrad Jazayeri

Mehrdad Jazayeri, a professor of brain and cognitive sciences and an investigator at the McGovern Institute for Brain Research, studies how physiological processes in the brain give rise to the abilities of the mind. Work in the Jazayeri Lab brings together ideas from cognitive science, neuroscience, and machine learning with experimental data in humans, animals, and computer models to develop a computational understanding of how the brain creates internal representations, or models, of the external world.

Before coming to MIT in 2013, Jazayeri received his BS in electrical engineering, majoring in telecommunications, from Sharif University of Technology in Tehran, Iran. He completed his MS in physiology at the University of Toronto and his PhD in neuroscience at New York University.

With his appointment to HHMI, Jazayeri plans to explore how the brain enables rapid learning and flexible behavior — central aspects of intelligence that have been difficult to study using traditional neuroscience approaches.

“This is a recognition of my lab’s past accomplishments and the promise of the exciting research we want to embark on,” he says. “I am looking forward to engaging with this wonderful community and making new friends and colleagues while we elevate our science to the next level.”

Gene-Wei Li,

Gene-Wei Li, associate professor of biology, has been working on quantifying the amount of proteins cells produce and how protein synthesis is orchestrated within the cell since opening his lab at MIT in 2015.

Li, whose background is in physics, credits the lab’s findings to the skills and communication among his research team, allowing them to explore the unexpected questions that arise in the lab.

For example, two of his graduate student researchers found that the coordination between transcription and translation fundamentally differs between the model organisms E. coli and B. subtilis. In B. subtilis, the ribosome lags far behind RNA polymerase, a process the lab termed “runaway transcription.” The discovery revealed that this kind of uncoupling between transcription and translation is widespread across many species of bacteria, a study that contradicted the long-standing dogma of molecular biology that the machinery of protein synthesis and RNA polymerase work side-by-side in all bacteria.

The support from HHMI enables Li and his team the flexibility to pursue the basic research that leads to discoveries at their discretion.

“Having this award allows us to be bold and to do things at a scale that wasn’t possible NetBet sportbefore,” Li says. “The discovery of runaway transcription is a great example. We didn’t have a traditional grant for that.”

Gene-Wei Li named 2024 HHMI Investigator

HHMI award will help Department of Biology faculty unravel the mysteries of precision gene expression across the proteome

Noah Daly | Department of Biology
July 23, 2024

To better understand how cells precisely control the levels of their proteins, Associate Professor Gene-Wei Li utilizes rigorous quantitative analysis to improve our molecular understandings of life. With the support he’ll receive as an HHMI Investigator, Li will explore how genomes are sculpted to allow lifeforms to survive in a competitive environment.

As versatile and durable as cells are, their every function depends on producing precise quantities of proteins. These proteins enable the cells to perform their functions, their organelles to work, and tell the cells when to grow or decompose. Without precise instructions for how much protein they need to generate, organisms would struggle to self-regulate efficiently, rendering them incapable of becoming competitive life forms. These “recipes” for protein production are written into the genetic code of all life. Recent advances in DNA sequencing have identified every protein an organism can produce–every “ingredient” in the genetic cookbook. Despite these significant advances, researchers still don’t know how to read the instructions. 

Since opening his lab at MIT in 2015, Associate Professor of Biology Gene-Wei Li has been working, among other things, on quantifying the amount of proteins cells produce and how that process is orchestrated within the cell. 

“The goal that we hope to achieve,” Li says, “is to read the genomic sequence and accurately tell you not just what types of proteins are made, but also how many of them will be made.” 

Li was recently named a 2024 Howard Hughes Medical Institute Investigator, one of 26 newly appointed Investigators hailing from 19 institutions. Each HHMI Investigator will receive roughly $11 million in support over a seven-year term, potentially renewable indefinitely. This support includes their full salary and benefits, a generous research budget, scientific equipment, and additional resources. 

“I feel grateful for the extremely supportive environment in my department,” Li says. “This award is also a recognition for the hard work and risk-taking by my lab’s current and past trainees.” 

Other MIT School of Science faculty joining the 2024 cohort include Mary Gehring, Professor of Biology and Core Member and David Baltimore Chair in Biomedical Research at the Whitehead Institute; Steven Flavell, Associate Professor of Brain and Cognitive Sciences and Investigator in the Picower Institute for Learning and Memory; and Mehrdad Jazayeri, Professor of Brain and Cognitive Sciences at the McGovern Institute.  

Of the nearly 1,000 researchers who applied to be HHMI investigators this year, successful applicants were selected for their singular accomplishments in scientific research. They receive extensive resources to continue their work at their home institution. HHMI enables scientists to pursue their work with extraordinary freedom, allowing them to expand their current efforts, pivot focus as needed, and execute original ideas. 

One of the hallmarks of Li’s lab is the devoted attention he gives to his students. Each member of the lab receives extensive guidance and mentorship, enabling them to pursue careers in science while sharing their ideas and concerns with fellow lab members and Li. For this inclusive culture, Li was honored by MIT as “Committed to Caring” for 2020-2021. 

“When scientists create environments in which others can thrive, we all benefit,” says HHMI President Erin O’Shea. “These newest HHMI Investigators netbet sports bettingare extraordinary, not only because of their outstanding research endeavors but also because they mentor and empower the next generation of scientists to work alongside them at the cutting edge.”  

In his lab, Li has emphasized the interweaving of individual achievement and the success of the group, creating a space for lab members to learn from one another, freely question their principal investigator, and ultimately make breakthroughs together. 

Discovery through Collaboration 

While Li’s lab was built around the question of quantifying a cell’s protein synthesis–that is, the amounts of all the proteins produced in a cell—his background is in physics. He approaches his work by making quantitative and systematic measurements (mainly with high-throughput DNA sequencing tools) and using that information to uncover fundamental molecular mechanisms in gene expression. 

The Li lab’s early work utilizing this methodology demonstrated that proteins that go on to form complexes are made in the correct ratios to immediately form complexes with few extra copies. 

Li’s team went on to discover that metabolic proteins are synthesized at precise ratios that are conserved across evolutionarily distant species, such as the two bacterial model organisms E. coli and B. subtilis. However, despite their shared output of protein production, the billions of years of evolution gave rise to two completely different ways to control protein quantity. 

In 2020, this line of research produced a study that contradicted the longstanding dogma of molecular biology that the machinery of protein synthesis and RNA polymerase work side by side in bacteria, which it does in E coli

According to Li, two of his graduate student researchers found that, in B. subtilis, the ribosome lags far behind RNA polymerase, a process the lab termed “runaway transcription.” They found that the coordination between transcription and translation is fundamentally different between E. coli and B. subtilis. They then identified bioinformatic signatures, revealing that this kind of uncoupling between transcription and translation is widespread across many species of bacteria. The students, Grace Johnson, a former graduate student in the Department of Biology, and Jean-Benoît Lalanne, a former graduate student in the Department of Physics, were the lead authors of the paper, which appeared in Nature

 “This is very exciting stuff, but all the credit goes to my grad students,” Li chuckles. 

Finding the Room to Be Bold 

The support from Howard Hughes Medical Institute enables Li and his team the flexibility to pursue the basic research that leads to discoveries. 

“Having this award really allows us to be bold and to do things at a scale that wasn’t possible before. The discovery of runaway transcription is a great example of this,” Li says.  

Li plans on using the funds made available from HHMI to help determine how functionally related genes differ in their expression and how signals are encoded in the genome at the DNA and RNA levels. According to Li, the collection of high-quality and system-wide data is essential to making discoveries in his field. 

“I’m incredibly grateful to HHMI for encouraging us to pursue this work and follow the science wherever it leads us,” he says. 

Li and his team are as eager as ever to understand life’s coded cookbook. 

“The work of science begins with great people,” Li says. “This award will help ensure our lab continues to be a place where incredible young scientists can work together to achieve miraculous things.” 

Brady Weissbourd named Searle Scholar

With an eye on regenerative medicine, Weissbourd's lab will study how jellyfish manage to constantly integrate new neurons into their nervous system.

David Orenstein | The Picower Institute for Learning and Memory
July 8, 2024

Scientists who dream of a future in which regenerative medicine has advanced enough to enable repairs in human nervous systems currently have more questions than answers. As a recently named Searle Scholar, MIT Assistant Professor Brady Weissbourd will seek to learn some of the needed fundamentals by studying a master of neural regeneration: the jellyfish, Clytia hemisphaerica.

Weissbourd, a faculty member in the Department of Biology and The Picower Institute for Learning and Memory, has helped to pioneer use of the seafaring species in neuroscience research for many reasons. It is transparent for easy imaging, reproduces rapidly, and shares many basic nervous system properties with mammals despite diverging evolutionarily 600 million years ago (just after the development of the earliest nervous systems). Meanwhile, with about 10,000 neurons, the jellyfish fills a gap in the field in terms of that degree of complexity.

But what Weissbourd didn’t appreciate until he began experimenting with the jellyfish was that they are also incredibly good at refreshing and rebuilding their nervous systems with new cells. After becoming the first researcher to develop the ability to genetically manipulate the organism, he started teasing out how its highly distributed nervous system (there is no central brain), was organized to enable its many behaviors. When he ablated a subnetwork of cells to test whether it was indeed responsible for a particular feeding behavior, he found that within a week it had completely regrown. Moreover, he has observed that the jellyfish constantly produce and integrate new cells, even in the absence of major injury.

Looking for the logic

The finding raised a proverbial boatload of intriguing questions that his support of $100,000 a year for the next three years from the Searle Scholars Program will help him pursue.

“Where are these newborn neurons coming from in both the normal and regenerative contexts?” Weissbourd asked. “What rules guide them to the correct locations to rebuild these networks, both to integrate these newborn neurons into the network without messing it up and also to recreate it during regeneration? Are the rules the same or different between these contexts?”

Additionally, by using a combination of techniques such as imaging neural activity during behavior, sequencing gene expression cell by cell, and computational modeling, Weissbourd’s lab has discerned that within their web-like mesh of neurons, jellyfish harbor more than a dozen different functional subnetworks that enable its variety of different behaviors. Can all the subnetworks regenerate? If not, why do some forgo the remarkable ability? Among those that do regenerate, do they all do so the same way? If they employ different means, then learning what those are could provide multiple answers to the question of how new neurons can successfully integrate into existing neural networks.

Building on support provided by a Klingenstein-Simons Fellowship Weissbourd earned last year, he’ll be able to pursue experiments designed to understand the “logic” of how jellyfish manage neural regeneration.

“The ability to understand how nervous systems regenerate has significant implications for regenerative medicine,” Weissbourd said.

A complete 3D ‘wiring diagram’

As part of the new award, Weissbourd also plans to create a major new resource for jellyfish neurobiology to advance not only this project, but also the research of any other scientist who wants to study the organism. Working with collaborator Jeff Lichtman, a professor of molecular and cellular biology at Harvard University, Weissbourd will create a complete 3D reconstruction of a jellyfish’s nervous system at the subcellular resolution enabled by electron microscopy. The resource, which Weissbourd plans to provide openly online, will amount to a full “wiring diagram” of a jellyfish where every circuit connection can be mapped.

Being able to see how every neural circuit is constructed in a whole animal will enable Weissbourd to answer questions about how the circuits are built and therefore how new neurons integrate. Having a complete and detailed view of every circuit will improve the computational models his lab is building to predict how anatomy helps give rise to function and behavior. And given that new neurons are being netbet sports bettingborn, migrating and integrating all the time, Weissbourd said, the imaging will also likely yield a snapshot of neural regeneration in action in its many stages.

Weissbourd said he was grateful for the honor of being named a Searle Scholar, which not only provides support for his lab’s work, but also welcomes him into a new community of young scientists.

“I’m honored and super excited,” Weissbourd said. “I’m excited to interact with the other scholars as well.”

 

Sara Prescott named Pew Scholar in the Biomedical Sciences

Assistant Professor Sara Prescott and her lab plan to test whether and how neurons have a role in airway remodeling, which goes awry in many diseases.

David Orenstein | The Picower Institute for Learning and Memory
June 17, 2024
Whitehead Institute Member Siniša Hrvatin named a 2024 McKnight Scholar

The McKnight Endowment Fund for Neuroscience has selected Whitehead Institute Member Siniša Hrvatin as one of ten early career scientists to receive a 2024 McKnight Scholar Award, supporting his research on mechanisms underlying certain animals’ capacity to enter states of torpor and hibernation.

Merrill Meadow | Whitehead Institute
June 20, 2024
Rudolf Jaenisch receives the ISTT Prize for contributions to transgenic technologies

The International Society for Transgenic Technologies recognized Whitehead Institute Founding Member Rudolf Jaenisch for his exceptional contribution to the field of animal transgenesis over the past five decades.

Merrill Meadow | Whitehead Institute
June 11, 2024
Whitehead Institute Director Ruth Lehmann elected as a Fellow of the Royal Society

Whitehead Institute Director and President Ruth Lehmann has been named a Foreign Member of the Royal Society. The election recognizes her “pioneering studies of the mechanisms underlying the embryonic development and reproduction of the fruit fly Drosophila.” It honors her work establishing the role of messenger RNA localization in specifying the antero-posterior body axis and germ line development and additionally notes her discoveries that revealed the role of lipid-based signaling pathways in the migration of germ cells to the developing gonads.

Lisa Girard | Whitehead Institute
May 22, 2024
Faculty Ömer Yilmaz and Seychelle Vos among MIT faculty selected for Cancer Grand Challenges

Joining three teams backed by a total of $75 million, MIT researchers will tackle some of cancer’s toughest challenges.

Bendta Schroeder | Koch Institute
March 18, 2024

Cancer Grand Challenges recently announced five winning teams for 2024, which included five researchers from MIT: Michael Birnbaum, Regina Barzilay, Brandon DeKosky, Seychelle Vos, and Ömer Yilmaz. Each team is made up of interdisciplinary cancer researchers from across the globe and will be awarded $25 million over five years.

Birnbaum, an associate professor in the Department of Biological Engineering, leads Team MATCHMAKERS and is joined by co-investigators Barzilay, the School of Engineering Distinguished Professor for AI and Health in the Department of Electrical Engineering and Computer Science and the AI faculty lead at the MIT Abdul Latif Jameel Clinic for Machine Learning in Health; and DeKosky, Phillip and Susan Ragon Career Development Professor of Chemical Engineering. All three are also affiliates of the Koch Institute for Integrative Cancer Research At MIT.

Team MATCHMAKERS will take advantage of recent advances in artificial intelligence to develop tools for personalized immunotherapies for cancer patients. Cancer immunotherapies, which recruit the patient’s own immune system against the disease, have transformed treatment for some cancers, but not for all types and not for all patients.

T cells are one target for immunotherapies because of their central role in the immune response. These immune cells use receptors on their surface to recognize protein fragments called antigens on cancer cells. Once T cells attach to cancer antigens, they mark them for destruction by the immune system. However, T cell receptors are exceptionally diverse within one person’s immune system and from person to person, making it difficult to predict how any one cancer patient will respond to an immunotherapy.

Team MATCHMAKERS will collect data on T cell receptors and the different antigens they target and build computer models to predict antigen recognition by different T cell receptors. The team’s overarching goal is to develop tools for predicting T cell recognition with simple clinical lab tests and designing antigen-specific immunotherapies. “If successful, what we learn on our team could help transform prediction of T cell receptor recognition from something that is only possible in a few sophisticated laboratories in the world, for a few people at a time, into a routine process,” says Birnbaum.

“The MATCHMAKERS project draws on MIT’s long tradition of developing cutting-edge artificial intelligence tools for the benefit of society,” comments Ryan Schoenfeld, CEO of The Mark Foundation for Cancer Research. “Their approach to optimizing immunotherapy for cancer and many other diseases is exemplary of the type of interdisciplinary research The Mark Foundation prioritizes supporting.” In addition to The Mark Foundation, the MATCHMAKERS team is funded by Cancer Research UK and the U.S. National Cancer Institute.

Vos, the Robert A. Swanson (1969) Career Development Professor of Life Sciences and HHMI Freeman Hrabowksi Scholar in the Department of Biology, will be a co-investigator on Team KOODAC. The KOODAC team will develop new treatments for solid tumors in children, using protein degradation strategies to target previously “undruggable” drivers of cancers. KOODAC is funded by Cancer Research UK, France’s Institut National Du Cancer, and KiKa (Children Cancer Free Foundation) through Cancer Grand Challenges.

As a co-investigator on team PROSPECT, Yilmaz, who is also a Koch Institute affiliate, will help address early-onset colorectal cancers, an emerging global problem among individuals younger than 50 years. The team seeks to elucidate pathways, risk factors, and molecules involved netbet sports bettingin the disease’s development. Team PROSPECT is supported by Cancer Research UK, the U.S. National Cancer Institute, the Bowelbabe Fund for Cancer Research UK, and France’s Institut National Du Cancer through Cancer Grand Challenges.