2022 Charles A. King Trust Research Fellows<\/strong><\/h2>\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Afshari-Khashayar_headshot-297x300.png\")
Khashayar Afshari, M.D., M.P.H.
\n<\/strong>University of Massachusetts Chan Medical School
\nMentor: Mehdi Rashighi, M.D.<\/a><\/p>\nRoles of cutaneous T peripheral helper cells as a marker for photosensitivity and disease activity in dermatomyositis<\/strong><\/p>\nDr. Afshari will seek to define the underlying mechanisms of photosensitivity and disease pathogenesis in patients with cutaneous Dermatomyositis (DM), an autoimmune disease characterized by skin rash and muscle weakness. Additionally, studies will aim to dissect how skin epithelial and immune cells in DM respond to ultraviolet B exposure and explore novel specific disease markers with potency to be used as therapeutic targets.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Alves-Christiano_headshot-300x300.jpeg\")
\nChristiano Alves, Ph.D.
\n<\/strong>Massachusetts General Hospital
\nMentor: Benjamin Kleinstiver, Ph.D.<\/a><\/p>\nDevelopment of CRISPR-based genetic cures for spinal muscular atrophy<\/strong><\/p>\nDr. Alves will work towards developing strategies to permanently edit the Survival Motor Neuron 2 (SMN2) gene through a one-time CRISPR-based genetic treatment. Success of this project will provide demonstration for the use of CRISPR technologies as a future treatment for Spinal Muscular Atrophy (SMA), the leading genetic cause of infantile death worldwide.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Arrona-Palacios-Arturo_headshot-200x300.jpg\")
Arturo Arrona-Palacios, Ph.D.
\n<\/strong>Brigham and Women\u2019s Hospital
\nMentor: Charles Czeisler, Ph.D., M.D.<\/a><\/p>\nProject Title: Development of a proteomic biomarker for human circadian timing<\/p>\n
Dr. Arrona-Palacios plans to develop and validate a method for measuring internal biological timing in humans. The goal for this project is to develop a robust diagnostic biomarker for circadian timing to improve diagnosis and treatment for patients with circadian rhythm disorders and sleep pathologies and improve personalized medicine.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Simona-Ceglia_headshot-225x300.jpg\")
Simona Ceglia, Ph.D.
\n<\/strong>University of Massachusetts Medical School
\nMentor: Andrea Reboldi, Ph.D.<\/a><\/p>\nA cholesterol byproduct imprints kidney immuno-metabolism in health and disease<\/strong><\/p>\nDr. Ceglia will advance our understanding of glomerulonephritis development by investigating the molecular mechanisms underpinning oxysterol production and function in the kidneys. This work may also lead to the identification of oxysterol regulation as a new target for prevention and treatment of IgA nephropathy.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Chong-Stephen_headshot-219x300.jpg\")
Stephen Chong, Ph.D.
\n<\/strong>Dana-Farber Cancer Institute
\nMentor: Matthew Davids, M.D., M.M.Sc.<\/a><\/p>\nTargeting the phosphorylation Of Bcl-2 family members in venetoclax-resistant lymphoid malignancies<\/strong><\/p>\nDr. Chong will determine if lymphoid malignant cells have enhanced phosphorylation of the anti-apoptotic proteins Bcl-2 and Mcl-1 and will test if this modification is the cause of resistance of the FDA-approved drug venetoclax in chronic lymphocytic leukemia.<\/p>\n
<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Darnell-Alicia_headshot-300x200.jpg\")
Alicia Darnell, Ph.D.
\n<\/strong>Massachusetts Institute of Technology
\nMentor: Matthew Vander Heiden, M.D. Ph.D.<\/a><\/p>\nMetabolic control of protein synthesis by ribosome stalling<\/strong><\/p>\nDr. Darnell will determine the factors that regulate ribosome stalling, which has been linked to neurodegeneration, cancer metastasis, and tumor innervation. This proposal will determine factors that regulate ribosome stalling upon amino acid starvation and identify the consequences of this metabolic form of translational control.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Das-Sunny_headshot-300x272.jpg\")
Sunny Das, Ph.D.
\n<\/strong>Whitehead Institute for Biomedical Research
\nMentor: Robert Weinberg, Ph.D.<\/a><\/p>\nMolecular mechanisms of metastatic colonization of the liver by dormant breast cancer cells<\/strong><\/p>\nDr. Das will study the transition of disseminated breast cancer cells from dormancy to colonization in the liver which will be further compared with patient datasets to identify potential pharmacological targets. The goal of this work is to ultimately develop anti-metastatic therapies and increase progression free- and overall survival in breast cancer patients.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Delgado-Ryan_headshot-225x300.jpg\")
Ryan Delgado, M.D. Ph.D.
\n<\/strong>Harvard Medical School
\nMentor: Constance Cepko, Ph.D.<\/a><\/p>\nThe role of lineage in the temporospatial genesis of retinal bipolar cell subtypes<\/strong><\/p>\nDr. Delgado will improve our understanding of retinal development by optimizing and using an \u201cevolvable\u201d lineage tracer he has developed called SCRIBE (Sequential Combinatorial Recorder for Iterative Barcode Evolution) to record patterns of cell division in developing tissue including the retina and determining whether these patterns might underlie proper retinal development.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Dong-Ying_headshot-300x279.jpeg\")
Ying Dong, Ph.D.
\n<\/strong>Boston Children\u2019s Hospital
\nMentor: Hao Wu, Ph.D.<\/a><\/p>\nMechanistic elucidation of the B cell receptor (BCR) signaling complex by cryo-EM<\/strong><\/p>\nDr. Dong will elucidate the structural assembly of the B cell receptor complex in different conformational states by cryo-electron microscopy and validate the structure using mutagenesis and cell biology. This work will not only provide new insights into B cell signal transduction, but also afford novel therapeutic strategies for the precise treatment of B-cell related diseases.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Hong-Deli_headshot-300x300.png\")
Deli Hong, Ph.D.
\n<\/strong>Dana-Farber Cancer Institute
\nMentor: Matthew Oser, M.D., Ph.D.<\/a><\/p>\nDissecting and therapeutically exploiting synthetic lethality between NOTCH and\u00a0TRIM28 to drive anti-tumor immunity in SCLC<\/strong><\/p>\nDr. Hong will study mechanisms underlying NOTCH\/TRIM28 synthetic lethality to identify new combination therapeutic strategies to increase immune checkpoint blockade response in small cell lung cancer using genetically engineered mouse models and derived cell lines. If successful, the proposed research could lay the preclinical foundation for a novel therapeutic strategy for the approximately 25% of small cell lung cancer patients that harbor loss-of-function NOTCH mutations.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Kwok-Hui-Si_headshot-263x300.jpg\")
Hui Si Kwok, Ph.D.
\n<\/strong>Harvard University
\nMentor: Brian Liau, Ph.D.<\/a><\/p>\nUnderstanding polycomb repressive complex 2 function and dependencies in EZH2-mutant lymphoma using drug addiction alleles<\/strong><\/p>\nDr. Kwok will leverage drug resistance and addiction mutations as discovery tools to gain critical understanding into the biology of Polycomb repressive complex 2 (PRC2), provide insight into how other PRC2 cancer mutations might likewise operate, and identify new cancer vulnerabilities.<\/p>\n
<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Ding_Liu-295x300.jpg\")
Ding Liu, Ph.D.
\n<\/strong>Harvard University
\nMentor: Catherine Dulac, Ph.D.<\/a><\/p>\nMolecular, circuit and sensory control of the instinctive need for social interactions<\/strong><\/p>\nDr. Liu aims to investigate the neurobiological mechanisms underlying social need. Using cutting edge single-cell RNA sequencing, viral tracing, and optogenetic and behavioral assays, this work will assess and compare the molecular, neural circuit, and sensory characteristics across mouse strains to deepen the understanding of the neural basis of social need and provide new insights into the treatment of social isolation induced mental disorders.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/AneMartinAnduaga_headshot-225x300.jpg\")
Ane Martin Anduaga, Ph.D.
\n<\/strong>Brandeis University
\nMentor: Sebastian Kadener, Ph.D.<\/a><\/p>\nElucidating the role of timeless thermosensitive alternative splicing in temperature compensation<\/strong><\/p>\nDr. Martin Anduaga will elucidate the mechanisms by which temperature compensation of the circadian clock is achieved in eukaryotes. Using molecular and genetic approaches the current proposal seeks to examine this mechanism through determining the contribution of the thermosensitively-regulated isoform of the gene timeless<\/em> (TIMCOLD<\/sup>) and three TIM isoforms of this locus in temperature compensation.<\/p>\n <\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Nozaki-Tadasu_headshot-300x266.jpg\")
Tadasu Nozaki, Ph.D.
\n<\/strong>Harvard University
\nMentor: Nancy Kleckner, Ph.D.<\/a><\/p>\nMolecular and physical mechanisms of homolog pairing in meiotic budding yeast<\/strong><\/p>\nDr. Nozaki will study how meiotic chromosomal homolog pairing occurs to further inform how failures in pairing lead to aneuploidy or genetic diseases. Utilizing an imaging technology that enables 4D tracking, this work will elucidate the molecular mechanisms of a new process called rapid homolog juxtaposition and the basis and relationship between intra-chromosomal synchrony and longitudinal compaction.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Rath-Sneha_headshot-1-203x300.jpg\")
Sneha Rath, Ph.D.
\n<\/strong>Massachusetts General Hospital
\nMentor: Vamsi Mootha, M.D.<\/a><\/p>\nA systems approach to discover sensors and regulators of mitochondrial genome ploidy<\/strong><\/p>\nDr. Rath will leverage bioenergetics, high-throughput genetics, and systems approaches to gain fundamental insight into how cells couple their fitness to mitochondrial genome (mtDNA) abundance and regulate their mtDNA copy number. This work has the potential to illuminate new therapeutic targets and accelerate our search for treatments of both inherited and age-associated mtDNA depletion.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Schmieder-Stefanie_headshot-300x200.jpg\")
Stefanie Schmieder, Ph.D.
\n<\/strong>Boston Children\u2019s Hospital
\nMentor: Wayne I. Lencer, M.D.<\/a><\/p>\nA multiscale approach to study the role of sphingolipids in plasma membrane function and as sensors in innate host defense<\/strong><\/p>\nDr. Schmieder will define how nanodomains in epithelial plasma membranes can transmit signals and elucidate how epithelial cells adapt nanodomain function to defend against pathogen invasion at the host-environment interface using a unique structural lipid library in combination with a high-throughput screen. This project will improve understanding of how microbial danger can be innately sensed by plasma membrane dysfunction and transmitted to induce a protective response.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Talbi-Rajae_headshot-187x300.jpg\")
Rajae Talbi, Ph.D.
\n<\/strong>Brigham and Women\u2019s Hospital
\nMentor: Victor Navarro, Ph.D.<\/a><\/p>\nDeciphering the female-specific hypothalamic pathway underlying the metabolic regulation of fertility by the melanocortin receptor 4<\/strong><\/p>\nDr. Talbi will study reproductive impairment and characterize a novel sex-dependent hypothalamic pathway in the metabolic control of ovulation by melanocortins using genetic mouse models, viral\/pharmacological approaches, and neuroscience techniques. Results from this study will offer new insight and lead to significant clinical improvement of fertility in patients with metabolic disorders.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Uzquiano-Lopez-Ana_headshot-1-300x200.jpg\")
Ana Uzquiano Lopez, Ph.D.
\n<\/strong>Harvard University
\nMentor: Paola Arlotta, Ph.D.<\/a><\/p>\nMechanisms governing neuronal population size and identity in the human brain<\/strong><\/p>\nDr. Uzquiano Lopez will leverage stem cell-derived brain organoids and genetic tools to investigate how the relative proportions of different neuronal populations are established in the cortex, and to discover the mechanisms that contribute to callosal projection neuron expansion and diversification. This work will shed light on fundamental processes underlying human cerebral cortex assembly, which has enabled major evolutionary adaptations of the human brain.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Xiong-Xiaozhe_headshot-1-235x300.jpg\")
Xiaozhe Xiong, Ph.D.
\n<\/strong>Boston Children\u2019s Hospital
\nMentor: Min Dong, Ph.D.<\/a><\/p>\nInsight into a novel enterococcus pore-forming toxin family<\/strong><\/p>\nDr. Xiong will study the colonization and pathogenesis of Enterococcus<\/em> by determining whether the uncharacterized family of Enterococcus <\/em>pore-forming toxins (Epx) are active toxins specifically targeting human cells, what their host factors are, and explore the physiological functions of Epxs during the pathogenesis process using structural analysis of Epxs, genome-wide CRISPRCas9 screens, and animal infection models.<\/p>\n <\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Zhang-Xingjie-Stephen_headshot-300x300.jpg\")
Xingjie Zhang, Ph.D.
\n<\/strong>Beth Israel Deaconess Medical Center \/ Harvard Medical School
\nMentor: Mark Andermann, Ph.D.<\/a><\/p>\nCompeting effects of AgRP and POMC neurons on cAMP signaling in downstream neurons in vivo<\/strong><\/p>\nDr. Zhang will apply a recently developed molecular and optical toolset to monitor and manipulate biochemical signaling pathways in mice to understand the how neurons use peptides to communicate with downstream circuits and process hunger and satiety signals. Insights from this work will help fill a substantial knowledge gap in developing treatments for obesity.<\/p>\n
<\/p>\n
<\/p>\n
\n![\"\"](\"https:\/\/hria.org\/wp-content\/uploads\/2022\/10\/Zhang-Yang_headshot-214x300.jpg\")
Yang Zhang, Ph.D.
\n<\/strong>Joslin Diabetes Center
\nMentor: Yu-Hua Tseng, Ph.D.<\/a><\/p>\n
Khashayar Afshari, M.D., M.P.H.\n<\/strong>University of Massachusetts Chan Medical School
\nMentor: Mehdi Rashighi, M.D.<\/a><\/p>\n
Roles of cutaneous T peripheral helper cells as a marker for photosensitivity and disease activity in dermatomyositis<\/strong><\/p>\n Dr. Afshari will seek to define the underlying mechanisms of photosensitivity and disease pathogenesis in patients with cutaneous Dermatomyositis (DM), an autoimmune disease characterized by skin rash and muscle weakness. Additionally, studies will aim to dissect how skin epithelial and immune cells in DM respond to ultraviolet B exposure and explore novel specific disease markers with potency to be used as therapeutic targets.<\/p>\n <\/p>\n <\/p>\n Christiano Alves, Ph.D. Development of CRISPR-based genetic cures for spinal muscular atrophy<\/strong><\/p>\n Dr. Alves will work towards developing strategies to permanently edit the Survival Motor Neuron 2 (SMN2) gene through a one-time CRISPR-based genetic treatment. Success of this project will provide demonstration for the use of CRISPR technologies as a future treatment for Spinal Muscular Atrophy (SMA), the leading genetic cause of infantile death worldwide.<\/p>\n <\/p>\n <\/p>\n Project Title: Development of a proteomic biomarker for human circadian timing<\/p>\n Dr. Arrona-Palacios plans to develop and validate a method for measuring internal biological timing in humans. The goal for this project is to develop a robust diagnostic biomarker for circadian timing to improve diagnosis and treatment for patients with circadian rhythm disorders and sleep pathologies and improve personalized medicine.<\/p>\n <\/p>\n <\/p>\n A cholesterol byproduct imprints kidney immuno-metabolism in health and disease<\/strong><\/p>\n Dr. Ceglia will advance our understanding of glomerulonephritis development by investigating the molecular mechanisms underpinning oxysterol production and function in the kidneys. This work may also lead to the identification of oxysterol regulation as a new target for prevention and treatment of IgA nephropathy.<\/p>\n <\/p>\n <\/p>\n Targeting the phosphorylation Of Bcl-2 family members in venetoclax-resistant lymphoid malignancies<\/strong><\/p>\n Dr. Chong will determine if lymphoid malignant cells have enhanced phosphorylation of the anti-apoptotic proteins Bcl-2 and Mcl-1 and will test if this modification is the cause of resistance of the FDA-approved drug venetoclax in chronic lymphocytic leukemia.<\/p>\n <\/p>\n <\/p>\n <\/p>\n Metabolic control of protein synthesis by ribosome stalling<\/strong><\/p>\n Dr. Darnell will determine the factors that regulate ribosome stalling, which has been linked to neurodegeneration, cancer metastasis, and tumor innervation. This proposal will determine factors that regulate ribosome stalling upon amino acid starvation and identify the consequences of this metabolic form of translational control.<\/p>\n <\/p>\n <\/p>\n Molecular mechanisms of metastatic colonization of the liver by dormant breast cancer cells<\/strong><\/p>\n Dr. Das will study the transition of disseminated breast cancer cells from dormancy to colonization in the liver which will be further compared with patient datasets to identify potential pharmacological targets. The goal of this work is to ultimately develop anti-metastatic therapies and increase progression free- and overall survival in breast cancer patients.<\/p>\n <\/p>\n <\/p>\n The role of lineage in the temporospatial genesis of retinal bipolar cell subtypes<\/strong><\/p>\n Dr. Delgado will improve our understanding of retinal development by optimizing and using an \u201cevolvable\u201d lineage tracer he has developed called SCRIBE (Sequential Combinatorial Recorder for Iterative Barcode Evolution) to record patterns of cell division in developing tissue including the retina and determining whether these patterns might underlie proper retinal development.<\/p>\n <\/p>\n <\/p>\n Mechanistic elucidation of the B cell receptor (BCR) signaling complex by cryo-EM<\/strong><\/p>\n Dr. Dong will elucidate the structural assembly of the B cell receptor complex in different conformational states by cryo-electron microscopy and validate the structure using mutagenesis and cell biology. This work will not only provide new insights into B cell signal transduction, but also afford novel therapeutic strategies for the precise treatment of B-cell related diseases.<\/p>\n <\/p>\n <\/p>\n Dissecting and therapeutically exploiting synthetic lethality between NOTCH and\u00a0TRIM28 to drive anti-tumor immunity in SCLC<\/strong><\/p>\n Dr. Hong will study mechanisms underlying NOTCH\/TRIM28 synthetic lethality to identify new combination therapeutic strategies to increase immune checkpoint blockade response in small cell lung cancer using genetically engineered mouse models and derived cell lines. If successful, the proposed research could lay the preclinical foundation for a novel therapeutic strategy for the approximately 25% of small cell lung cancer patients that harbor loss-of-function NOTCH mutations.<\/p>\n <\/p>\n <\/p>\n Understanding polycomb repressive complex 2 function and dependencies in EZH2-mutant lymphoma using drug addiction alleles<\/strong><\/p>\n Dr. Kwok will leverage drug resistance and addiction mutations as discovery tools to gain critical understanding into the biology of Polycomb repressive complex 2 (PRC2), provide insight into how other PRC2 cancer mutations might likewise operate, and identify new cancer vulnerabilities.<\/p>\n <\/p>\n <\/p>\n <\/p>\n Molecular, circuit and sensory control of the instinctive need for social interactions<\/strong><\/p>\n Dr. Liu aims to investigate the neurobiological mechanisms underlying social need. Using cutting edge single-cell RNA sequencing, viral tracing, and optogenetic and behavioral assays, this work will assess and compare the molecular, neural circuit, and sensory characteristics across mouse strains to deepen the understanding of the neural basis of social need and provide new insights into the treatment of social isolation induced mental disorders.<\/p>\n <\/p>\n <\/p>\n Elucidating the role of timeless thermosensitive alternative splicing in temperature compensation<\/strong><\/p>\n Dr. Martin Anduaga will elucidate the mechanisms by which temperature compensation of the circadian clock is achieved in eukaryotes. Using molecular and genetic approaches the current proposal seeks to examine this mechanism through determining the contribution of the thermosensitively-regulated isoform of the gene timeless<\/em> (TIMCOLD<\/sup>) and three TIM isoforms of this locus in temperature compensation.<\/p>\n <\/p>\n <\/p>\n Molecular and physical mechanisms of homolog pairing in meiotic budding yeast<\/strong><\/p>\n Dr. Nozaki will study how meiotic chromosomal homolog pairing occurs to further inform how failures in pairing lead to aneuploidy or genetic diseases. Utilizing an imaging technology that enables 4D tracking, this work will elucidate the molecular mechanisms of a new process called rapid homolog juxtaposition and the basis and relationship between intra-chromosomal synchrony and longitudinal compaction.<\/p>\n <\/p>\n <\/p>\n A systems approach to discover sensors and regulators of mitochondrial genome ploidy<\/strong><\/p>\n Dr. Rath will leverage bioenergetics, high-throughput genetics, and systems approaches to gain fundamental insight into how cells couple their fitness to mitochondrial genome (mtDNA) abundance and regulate their mtDNA copy number. This work has the potential to illuminate new therapeutic targets and accelerate our search for treatments of both inherited and age-associated mtDNA depletion.<\/p>\n <\/p>\n <\/p>\n A multiscale approach to study the role of sphingolipids in plasma membrane function and as sensors in innate host defense<\/strong><\/p>\n Dr. Schmieder will define how nanodomains in epithelial plasma membranes can transmit signals and elucidate how epithelial cells adapt nanodomain function to defend against pathogen invasion at the host-environment interface using a unique structural lipid library in combination with a high-throughput screen. This project will improve understanding of how microbial danger can be innately sensed by plasma membrane dysfunction and transmitted to induce a protective response.<\/p>\n <\/p>\n <\/p>\n Deciphering the female-specific hypothalamic pathway underlying the metabolic regulation of fertility by the melanocortin receptor 4<\/strong><\/p>\n Dr. Talbi will study reproductive impairment and characterize a novel sex-dependent hypothalamic pathway in the metabolic control of ovulation by melanocortins using genetic mouse models, viral\/pharmacological approaches, and neuroscience techniques. Results from this study will offer new insight and lead to significant clinical improvement of fertility in patients with metabolic disorders.<\/p>\n <\/p>\n <\/p>\n Mechanisms governing neuronal population size and identity in the human brain<\/strong><\/p>\n Dr. Uzquiano Lopez will leverage stem cell-derived brain organoids and genetic tools to investigate how the relative proportions of different neuronal populations are established in the cortex, and to discover the mechanisms that contribute to callosal projection neuron expansion and diversification. This work will shed light on fundamental processes underlying human cerebral cortex assembly, which has enabled major evolutionary adaptations of the human brain.<\/p>\n <\/p>\n <\/p>\n Insight into a novel enterococcus pore-forming toxin family<\/strong><\/p>\n Dr. Xiong will study the colonization and pathogenesis of Enterococcus<\/em> by determining whether the uncharacterized family of Enterococcus <\/em>pore-forming toxins (Epx) are active toxins specifically targeting human cells, what their host factors are, and explore the physiological functions of Epxs during the pathogenesis process using structural analysis of Epxs, genome-wide CRISPRCas9 screens, and animal infection models.<\/p>\n <\/p>\n <\/p>\n Competing effects of AgRP and POMC neurons on cAMP signaling in downstream neurons in vivo<\/strong><\/p>\n Dr. Zhang will apply a recently developed molecular and optical toolset to monitor and manipulate biochemical signaling pathways in mice to understand the how neurons use peptides to communicate with downstream circuits and process hunger and satiety signals. Insights from this work will help fill a substantial knowledge gap in developing treatments for obesity.<\/p>\n <\/p>\n <\/p>\n
\n\n
\n<\/strong>Massachusetts General Hospital
\nMentor: Benjamin Kleinstiver, Ph.D.<\/a><\/p>\n
\nArturo Arrona-Palacios, Ph.D.
\n<\/strong>Brigham and Women\u2019s Hospital
\nMentor: Charles Czeisler, Ph.D., M.D.<\/a><\/p>\n
\nSimona Ceglia, Ph.D.
\n<\/strong>University of Massachusetts Medical School
\nMentor: Andrea Reboldi, Ph.D.<\/a><\/p>\n
\nStephen Chong, Ph.D.
\n<\/strong>Dana-Farber Cancer Institute
\nMentor: Matthew Davids, M.D., M.M.Sc.<\/a><\/p>\n
\nAlicia Darnell, Ph.D.
\n<\/strong>Massachusetts Institute of Technology
\nMentor: Matthew Vander Heiden, M.D. Ph.D.<\/a><\/p>\n
\nSunny Das, Ph.D.
\n<\/strong>Whitehead Institute for Biomedical Research
\nMentor: Robert Weinberg, Ph.D.<\/a><\/p>\n
\nRyan Delgado, M.D. Ph.D.
\n<\/strong>Harvard Medical School
\nMentor: Constance Cepko, Ph.D.<\/a><\/p>\n
\nYing Dong, Ph.D.
\n<\/strong>Boston Children\u2019s Hospital
\nMentor: Hao Wu, Ph.D.<\/a><\/p>\n
\nDeli Hong, Ph.D.
\n<\/strong>Dana-Farber Cancer Institute
\nMentor: Matthew Oser, M.D., Ph.D.<\/a><\/p>\n
\nHui Si Kwok, Ph.D.
\n<\/strong>Harvard University
\nMentor: Brian Liau, Ph.D.<\/a><\/p>\n
\nDing Liu, Ph.D.
\n<\/strong>Harvard University
\nMentor: Catherine Dulac, Ph.D.<\/a><\/p>\n
\nAne Martin Anduaga, Ph.D.
\n<\/strong>Brandeis University
\nMentor: Sebastian Kadener, Ph.D.<\/a><\/p>\n
\nTadasu Nozaki, Ph.D.
\n<\/strong>Harvard University
\nMentor: Nancy Kleckner, Ph.D.<\/a><\/p>\n
\nSneha Rath, Ph.D.
\n<\/strong>Massachusetts General Hospital
\nMentor: Vamsi Mootha, M.D.<\/a><\/p>\n
\nStefanie Schmieder, Ph.D.
\n<\/strong>Boston Children\u2019s Hospital
\nMentor: Wayne I. Lencer, M.D.<\/a><\/p>\n
\nRajae Talbi, Ph.D.
\n<\/strong>Brigham and Women\u2019s Hospital
\nMentor: Victor Navarro, Ph.D.<\/a><\/p>\n
\nAna Uzquiano Lopez, Ph.D.
\n<\/strong>Harvard University
\nMentor: Paola Arlotta, Ph.D.<\/a><\/p>\n
\nXiaozhe Xiong, Ph.D.
\n<\/strong>Boston Children\u2019s Hospital
\nMentor: Min Dong, Ph.D.<\/a><\/p>\n
\nXingjie Zhang, Ph.D.
\n<\/strong>Beth Israel Deaconess Medical Center \/ Harvard Medical School
\nMentor: Mark Andermann, Ph.D.<\/a><\/p>\n
\nYang Zhang, Ph.D.
\n<\/strong>Joslin Diabetes Center
\nMentor: Yu-Hua Tseng, Ph.D.<\/a><\/p>\n