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      1. Carlos Slim Center for Health Research The Slim Center aims to bring the benefits of genomics-driven medicine to Latin America, gleaning new insights into diseases with relevance to the region.
      2. Gerstner Center for Cancer Diagnostics The Gerstner Center is developing next-generation diagnostic technology for cancer detection and tracking disease progression.
      3. Klarman Cell Observatory The Klarman Cell Observatory is systematically defining mammalian cellular circuits, how they work together to create tissues and organs, and are perturbed to cause disease.
      4. Merkin Institute for Transformative Technologies in Healthcare The Merkin Institute is supporting early-stage ideas aimed at advancing powerful technological approaches for improving how we understand and treat disease.
      5. Novo Nordisk Foundation Center for Genomic Mechanisms of Disease This center is developing new paradigms and technologies to scale the discovery of biological mechanisms of common, complex diseases, by facilitating close collaborations between the ӳý and the Danish research community.
      6. Eric and Wendy Schmidt Center The EWSC is catalyzing a new field of interdisciplinary research at the intersection of data science and life science, aimed at improving human health.
      7. Stanley Center for Psychiatric Research The Stanley Center aims to reduce the burden of serious mental illness by contributing new insights into pathogenesis, identifying biomarkers, and paving the way toward new treatments.
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      1. Art and science connection Explore the connection between art and science and how we bring together artists and ӳý scientists through our artist-in-residence program, gallery exhibitions, and ongoing public conversations.
      2. ӳý Discovery Center Visit our free public educational space that showcases how researchers at the ӳý and their colleagues around the world seek to understand and treat human disease.
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Nucleotide depletion promotes cell fate transitions by inducing DNA replication stress.
Do BT, Hsu PP, Vermeulen SY, et al. Nucleotide depletion promotes cell fate transitions by inducing DNA replication stress. Developmental cell. 2024. doi:10.1016/j.devcel.2024.05.010
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Yap regulates glucose utilization and sustains nucleotide synthesis to enable organ growth.
Cox AG, Tsomides A, Yimlamai D, et al. Yap regulates glucose utilization and sustains nucleotide synthesis to enable organ growth. EMBO J. 2018;37(22). doi:10.15252/embj.2018100294
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Small-Molecule Screen Identifies De Novo Nucleotide Synthesis as a Vulnerability of Cells Lacking SIRT3.
Herrera KNG, Zaganjor E, Ishikawa Y, et al. Small-Molecule Screen Identifies De Novo Nucleotide Synthesis as a Vulnerability of Cells Lacking SIRT3. Cell Rep. 2018;22(8):1945-1955. doi:10.1016/j.celrep.2018.01.076
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Base-specific mutational intolerance near splice sites clarifies the role of nonessential splice nucleotides.
Zhang S, Samocha KE, Rivas MA, et al. Base-specific mutational intolerance near splice sites clarifies the role of nonessential splice nucleotides. Genome Res. 2018;28(7):968-974. doi:10.1101/gr.231902.117
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Histidine catabolism is a major determinant of methotrexate sensitivity.
Kanarek N, Keys HR, Cantor JR, et al. Histidine catabolism is a major determinant of methotrexate sensitivity. Nature. 2018;559(7715):632-636. doi:10.1038/s41586-018-0316-7
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A mechanism for a single nucleotide intron shift.
Fekete E, Flipphi M, Ág N, et al. A mechanism for a single nucleotide intron shift. Nucleic Acids Res. 2017;45(15):9085-9092. doi:10.1093/nar/gkx520
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A stereoelectronic effect in prebiotic nucleotide synthesis.
Choudhary A, Kamer KJ, Powner MW, Sutherland JD, Raines RT. A stereoelectronic effect in prebiotic nucleotide synthesis. ACS Chem Biol. 2010;5(7):655-7. doi:10.1021/cb100093g
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Recent progress toward the templated synthesis and directed evolution of sequence-defined synthetic polymers.
Brudno Y, Liu DR. Recent progress toward the templated synthesis and directed evolution of sequence-defined synthetic polymers. Chem Biol. 2009;16(3):265-76. doi:10.1016/j.chembiol.2009.02.004
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Effects of template sequence and secondary structure on DNA-templated reactivity.
Snyder TM, Tse BN, Liu DR. Effects of template sequence and secondary structure on DNA-templated reactivity. J Am Chem Soc. 2008;130(4):1392-401. doi:10.1021/ja076780u
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Genome-scale DNA methylation mapping of clinical samples at single-nucleotide resolution.
Gu H, Bock C, Mikkelsen TS, et al. Genome-scale DNA methylation mapping of clinical samples at single-nucleotide resolution. Nat Methods. 2010;7(2):133-6. doi:10.1038/nmeth.1414
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In March of 2020, ӳý converted a clinical genetics processing lab into a large-scale COVID-19 testing facility in less than two weeks.

We've screened more than 1,275 cancer cell lines as part of the Cancer Dependency Map (DepMap).

ӳý Genomics Platform sequences a whole human genome every four minutes.

More than 11,000 individuals living with cancer in the United States and Canada have partnered with Count Me In to share their experiences and help accelerate cancer research.

The Drug Repurposing Hub is one of the most comprehensive and up-to-date biologically annotated collections of FDA-approved compounds in the world. Researchers anywhere can explore more than 6,000 drugs in the hub and search for possible new uses for them to jump-start new drug discovery.

In 2021, our sustainability efforts sent more than 80 percent of waste from the Genomics Platform to either a recycling facility or to an incineration plant that generates electricity.

Through ӳý's Scientists in the Classroom program, ӳý researchers visit every 8th grade classroom in Cambridge each year to talk about genetics and evolution.

Every summer, 18 high school students spend six weeks at ӳý working side-by-side with mentors on cutting-edge research.

In November 2022, ӳý’s Genomics Platform sequenced its 500,000th whole human genome, a mere four years after sequencing its 100,000th.

By the end of 2022, ӳý’s COVID-19 testing lab had processed more than 37 million tests.

Working with Addgene, ӳý has shared CRISPR genome-editing reagents with researchers at more than 3,200 institutions in 76 countries.

The NeuroGAP-Psychosis project, a collaboration between the Stanley Center for Psychiatric Research and Harvard T.H. Chan School of Public Health to study the genetics of severe mental illness, has recruited more than 42,000 participants in Ethiopia, Kenya, Uganda, and South Africa.

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