基本信息
views: 36
Career Trajectory
Bio
Honors & Awards
George Beadle Award, GSA (2019)
Elected Member, American Academy of Science (2015)
Stanford B. Ascherman Professor, Stanford (2011)
Pioneer Award, Human Proteome Organization (2009)
CT Medal of Science, Connection Academy of Science (2007)
Pew Scholar Award, Pew Foundation (1987-1991)
We are presently in an omics revolution in which genomes and other omes can be readily characterized. Our laboratory uses a variety of approaches to analyze genomes and regulatory networks. Our research focuses on yeast, an ideal model organism ideally suited to genetic analysis, and humans.
1) Transcriptomes
To annotate genomes, we developed RNA sequencing for annotation the yeast and human transcriptomes. We discovered that the eukaryotic transcriptome is much more complex than previously appreciated and that embryonic stem cells have more transcript isoforms than differentiated cells.
2) Transcription Factor Binding Networks
We have also developed methods for mapping transcription factor binding sites through the genome. We used this to develop regulatory maps and have been using this to help decipher the combinatorial regulatory code which factors work together to regulate which genes. Using this approach we have mapped out pathways crucial for metabolism and inflammation.
3) Integrated Regulatory Networks
In addition to transcriptional factor binding networks we have also been mapping phosphorylation and metabolite-protein interaction networks. These studies have revealed novel global regulators and key points in integrated regulatory networks.
4) Variation
We have been analyzing differences between individuals and species at two levels: DNA sequence variation and regulatory information variations. We developed paired end sequencing for humans and found that humans have extensive structural variation (SV), i.e. deletions, insertions and inversions. This is likely to be a major cause of phenotypic variation and human disease. In addition, by mapping binding sites difference among different yeast strains and humans, we have found that individuals differ much more in their regulatory information than in coding sequence differences. We can correlate these differences with those in SNPS and SVs, thereby associating noncoding DNA differences with regulatory information.
5) Human Disease
Finally, we are applying omics approaches of genome sequencing, transcriptomics proteomics metabolomics, DNA methylation and microbiome assays to the analysis of human disease. These integrative omics approaches are being applied to help understand the molecular basis of disease and the development of diagnostics and therapeutics.
George Beadle Award, GSA (2019)
Elected Member, American Academy of Science (2015)
Stanford B. Ascherman Professor, Stanford (2011)
Pioneer Award, Human Proteome Organization (2009)
CT Medal of Science, Connection Academy of Science (2007)
Pew Scholar Award, Pew Foundation (1987-1991)
We are presently in an omics revolution in which genomes and other omes can be readily characterized. Our laboratory uses a variety of approaches to analyze genomes and regulatory networks. Our research focuses on yeast, an ideal model organism ideally suited to genetic analysis, and humans.
1) Transcriptomes
To annotate genomes, we developed RNA sequencing for annotation the yeast and human transcriptomes. We discovered that the eukaryotic transcriptome is much more complex than previously appreciated and that embryonic stem cells have more transcript isoforms than differentiated cells.
2) Transcription Factor Binding Networks
We have also developed methods for mapping transcription factor binding sites through the genome. We used this to develop regulatory maps and have been using this to help decipher the combinatorial regulatory code which factors work together to regulate which genes. Using this approach we have mapped out pathways crucial for metabolism and inflammation.
3) Integrated Regulatory Networks
In addition to transcriptional factor binding networks we have also been mapping phosphorylation and metabolite-protein interaction networks. These studies have revealed novel global regulators and key points in integrated regulatory networks.
4) Variation
We have been analyzing differences between individuals and species at two levels: DNA sequence variation and regulatory information variations. We developed paired end sequencing for humans and found that humans have extensive structural variation (SV), i.e. deletions, insertions and inversions. This is likely to be a major cause of phenotypic variation and human disease. In addition, by mapping binding sites difference among different yeast strains and humans, we have found that individuals differ much more in their regulatory information than in coding sequence differences. We can correlate these differences with those in SNPS and SVs, thereby associating noncoding DNA differences with regulatory information.
5) Human Disease
Finally, we are applying omics approaches of genome sequencing, transcriptomics proteomics metabolomics, DNA methylation and microbiome assays to the analysis of human disease. These integrative omics approaches are being applied to help understand the molecular basis of disease and the development of diagnostics and therapeutics.
Research Interests
Papers共 1353 篇Author StatisticsCo-AuthorSimilar Experts
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bioRxiv : the preprint server for biology (2024)
Arash Alavi,Kexin Cha, Delara P Esfarjani, Bhavesh Patel, Jennifer Li Pook Than, Aaron Y Lee, Camille Nebeker,Michael Snyder,Amir Bahmani
medrxiv(2024)
FRONTIERS IN ALLERGY (2024)
Stress (Amsterdam, Netherlands)no. 1 (2024): 2321610-2321610
Foozhan Tahmasebinia,Yinglu Tang, Rushi Tang, Yi Zhang,Songjie Chen,Michael Snyder,Boxiang Liu,Zhihao Wu
Journal of Biological Chemistryno. 3 (2024)
Ashkan Dehghani Zahedani,Tracey McLaughlin,Arvind Veluvali,Nima Aghaeepour, Amir Hosseinian, Saransh Agarwal,Jingyi Ruan, Shital Tripathi, Mark Woodward, Noosheen Hashemi,Michael Snyder
npj Digital Medicineno. 1 (2024)
Marcel Weinreich,Harry McDonough, Nancy Yacovzada,Iddo Magen,Yahel Cohen,Calum Harvey, Sarah Gornall,Sarah Boddy,James Alix, Nima Mohseni,Julian M Kurz,Kevin P Kenna, Sai Zhang,Alfredo Iacoangeli, Ahmad Al-Khleifat,Michael P Snyder,Esther Hobson,Ammar Al-Chalabi,Eran Hornstein, Eran Elhaik,Pamela J Shaw,Christopher McDermott,Johnathan Cooper-Knock
bioRxiv : the preprint server for biology (2024)
crossref(2024)
Xin Zhou,Xiaotao Shen,Jethro S. Johnson,Daniel J. Spakowicz,Melissa Agnello,Wenyu Zhou,Monica Avina,Alexander Honkala,Faye Chleilat, Shirley Jingyi Chen,Kexin Cha,Shana Leopold,Chenchen Zhu,Lei Chen,Lin Lyu,Daniel Hornburg,Si Wu,Xinyue Zhang,Chao Jiang,Liuyiqi Jiang,Lihua Jiang,Ruiqi Jian,Andrew W. Brooks, Meng Wang,Kevin Contrepois, Peng Gao,Sophia Miryam Schu euro ssler-Fiorenza Rose,Thi Dong Binh Tran,Hoan Nguyen,Alessandra Celli,Bo -Young Hong,Eddy J. Bautista,Yair Dorsett,Paula B. Kavathas,Yanjiao Zhou,Erica Sodergren,George M. Weinstock,Michael P. Snyder
CELL HOST & MICROBEno. 4 (2024): 506-526.e9
Borna Rapčan,Manshu Song,Azra Frkatović-Hodžić,Tea Pribić, Jakov Vuk,Anđelo Beletić,Maja Hanić,Julija Jurić,Petra Tominac,Josip Milas,Vedrana Ivić,Sven Viland, Sara Bonet, Branko Šego,Marija Heffer,Wei Wang,Michael P. Snyder,Gordan Lauc
GEROSCIENCE (2024)
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Author Statistics
#Papers: 1357
#Citation: 153650
H-Index: 183
G-Index: 372
Sociability: 9
Diversity: 4
Activity: 837
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