Organization:Icahn Genomics Institute

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Short description: Biomedical and genomics research institute in New York, US
Icahn Genomics Institute
Established2011
Research typeTranslational research
Field of research
gene editing, gene therapy, genomics
DirectorBrian Brown
Address1425 Madison Avenue, New York, NY 10029-6501
LocationNew York City
AffiliationsIcahn School of Medicine at Mount Sinai
Mount Sinai Hospital, New York
Websitehttps://icahn.mssm.edu/research/genomics-institute

The Icahn Genomics Institute is a biomedical and genomics research institute within the Icahn School of Medicine at Mount Sinai in New York City . Its aim is to establish a new generation of medicines that can better treat diseases afflicting the world, including cancer, heart disease and infectious pathogens. To do this, the institute’s doctors and scientists are developing and employing new types of treatments that utilize DNA and RNA based therapies, such as CRISPR, siRNA, RNA vaccines, and CAR T cells, and searching for novel drug targets through the use of functional genomics and data science. The institute is led by Brian Brown, a leading expert in gene therapy, genetic engineering, and molecular immunology.[1]

Goals

The institute’s primary goal is to improve patient care through the use of gene, cell and nucleotide therapies. To achieve this goal, the Institute is formed of a cross-disciplinary mix of clinicians and scientists that include physicians treating patients with novel gene therapies in the Mount Sinai Health System, biologists developing and testing new drugs and drug platforms, and data scientists working to identify causative agents of disease that can be targeted for therapy by building predictive models that better characterize disease. These models are constructed with multiple layers of biological data, including gene expression, metabolite, DNA, and protein information, and are combined with phenotypic and clinical data, predictive modeling, and probabilistic analysis to try to elucidate the complex mechanisms of disease.[2]

Research

Research at the institute falls into six areas:[3]

  • RNA Therapeutics and Nanomedicines
  • Gene, CRISPR, and Cell Engineering
  • Asthma and allergies
  • Viral and Microbial Therapeutics
  • Cancer Gene and Cell Therapy
  • Therapeutic Target Discovery

Notable Academic Publications

Scientists from the institute published a paper in Nature Genetics in 2012 demonstrating the ability to derive enough information from non-DNA sources to identify individuals whose supposedly anonymized biological data is stored in large research databases.[4] The authors reported that measuring RNA levels in tissue allowed them to infer a genetic barcode that could be used to match other materials to that same individual. This was noteworthy as validation of existing concerns among genomics scientists that it may not be possible to prevent the identification of an individual from genetic data even when that data is meant to be anonymous.

In a PLoS Biology paper, institute founding director Eric Schadt led a research team that utilized six different types of data (metabolite concentration, gene expression, DNA variation, DNA-protein binding, protein-metabolite interaction, and protein-protein interaction) to reconstruct networks involved in cell regulation.[5]

In 2013, institute scientists published a paper in the journal Cell reporting findings from a network-based study of late-onset Alzheimer's disease. The researchers constructed gene regulatory networks and discovered a neural structure involved in a pathway associated with onset of the disease.[6]

In January 2014, scientists from the institute’s Division of Psychiatric Genomics including Pamela Sklar published two papers in the journal Nature that explored the genetic complexity of schizophrenia.[7][8] The exome sequencing studies of populations in Bulgaria and Sweden revealed that the disorder is likely caused by a lot of rare genetic mutations rather than a few common mutations.[9][10] The projects also established the world’s largest database on schizophrenia.

In May 2014, institute faculty published proof-of-concept findings to support the clinical development of RNA interference therapy for acute hepatic porphyria which led to the development of givosiran as the first therapy for acute hepatic porphyria, approved by the FDA in 2019.[11][12] Institute researchers and clinicians also led the Phase 3 clinical trials for givosiran.[13]

Institute director, Brian Brown, developed a new CRISPR imaging technology called Perturb-map capable of identifying regulators in tumor microenvironments.[14][15][16] The findings were published in Cell in 2022.[17] Perturb-map was used in this study to identify the cytokine interferon gamma, IFNg, and the tumor growth factor beta receptor, TGFbR, as regulators of two pathways significantly affecting tumor growth, architecture, and immune cell recruitment.[18][19][20]

Institute faculty member Samir Parekh published results of a clinical trial in Blood Advances (2022) focused on second-line treatments for relapsed multiple myeloma patients.[21] The study reported over an 80% response rate in patients treated with T-cell redirection therapy with chimeric antigen receptor (CAR)-T cells and bispecific antibodies (BiAbs) as a second-line treatment after a first-line immunotherapy treatment had failed.[22][23]

Also in 2022, Brian Brown's research published results of a study targeting solid tumors with chimeric antigen receptor (CAR)-T cell therapy, which had previously only been successful in blood cancers.[24] The researchers engineered CAR T cells to target and destroy macrophages, an immune cell supporting tumor growth, in ovarian, lung, and pancreatic tumors in mice models, which successfully shrunk tumors and prolonged survival.[25][26]

Institute faculty member Ivan Marazzi's research team published a Nature paper in 2022 identifying the immune system's role in amyotrophic lateral sclerosis (ALS). The study found immune system dysfunction in patients and mice with ALS, and showed a high concentration of CD8 T cells in spinal cord and blood. The study was among the first publications to describe the immune system's involvement in neurodegeneration.[27][28]

History

The institute was formed in 2011 as the Institute for Genomics and Multiscale Biology, as part of Mount Sinai's Department of Genetics and Genomic Sciences. Eric Schadt was named as founding director.[29] The institute was renamed in 2012 when philanthropist Carl Icahn pledged $200 million to its parent organization, the Icahn School of Medicine at Mount Sinai.[30]

In 2012, the institute received certification for the first CLIA-approved next-generation sequencing lab in New York City.[31][32]

Institute faculty Andrew Kasarskis, Michael Linderman, George Diaz, Ali Bashir, and Randi Zinberg taught the first class in which Mount Sinai medical students were able to fully sequence and analyze their own genomes.[33][34]

Former institute member Joel Dudley was named one of the 100 most creative people in business in a 2014 list compiled by Fast Company.[35] The magazine said it chose Dudley "for splicing information with quality medical care."

In 2014 the institute, in collaboration with Sage Bionetworks, announced a new project aiming to genotype up to 1 million people with the goal of identifying the rare biological mechanisms that keep people healthy when they have genetic variants that should cause disease.[36][37] The Resilience Project aimed to scan the genomes of healthy people age 30 and older who contribute their DNA to the effort with an initial focus on 127 diseases. Scientists anticipated that finding protective mechanisms for Mendelian diseases would be more straightforward than finding ones for complex or multifactorial diseases.[38][39] Based on an analysis of publicly available data from 600,000 human genomes, scientists involved in the Resilience Project estimated that one person in 15,000 has a mechanism protecting against disease-causing genetic variants.[40]

In 2022, institute faculty Pei Wang and Avi Ma'ayan established a Proteogenomic Data Analysis Center funded by the National Cancer Institute. The center's goals included identification of biomarkers and drug targets for cancer and development of computational tools for drug discovery.[41][42]

References

  1. "Icahn Genomics Institute | Icahn School of Medicine". https://icahn.mssm.edu/research/genomics-institute. 
  2. "Icahn Genomics Institute | Icahn School of Medicine". https://icahn.mssm.edu/research/genomics-institute. 
  3. "Icahn Genomics Institute". https://icahn.mssm.edu/research/genomics-institute. 
  4. Schadt, Eric E.; Woo, Sangsoon; Hao, Ke (2012). "Bayesian method to predict individual SNP genotypes from gene expression data". Nature Genetics 44 (5): 603–608. doi:10.1038/ng.2248. PMID 22484626. 
  5. Zhu, Jun; Sova, Pavel; Xu, Qiuwei; Dombek, Kenneth M.; Xu, Ethan Y.; Vu, Heather; Tu, Zhidong; Brem, Rachel B. et al. (2012). "Stitching together Multiple Data Dimensions Reveals Interacting Metabolomic and Transcriptomic Networks That Modulate Cell Regulation". PLOS Biology 10 (4): e1001301. doi:10.1371/journal.pbio.1001301. PMID 22509135. 
  6. "Cell - Integrated Systems Approach Identifies Genetic Nodes and Networks in Late-Onset Alzheimer's Disease". http://www.cell.com/abstract/S0092-8674(13)00387-5. 
  7. O’Donovan, Michael C.; Purcell, Shaun M.; Owen, Michael J.; Sklar, Pamela; Holmans, Peter; McCarroll, Steven A.; Palotie, Aarno; Kirov, George et al. (1 February 2014). "De novo mutations in schizophrenia implicate synaptic networks". Nature 506 (7487): 179–184. doi:10.1038/nature12929. PMID 24463507. Bibcode2014Natur.506..179F. 
  8. Sklar, Pamela; McCarroll, Steven A.; Sullivan, Patrick F.; Hultman, Christina M.; Lander, Eric S.; Scolnick, Edward M.; Gabriel, Stacey; Haggarty, Stephen J. et al. (1 February 2014). "A polygenic burden of rare disruptive mutations in schizophrenia". Nature 506 (7487): 185–190. doi:10.1038/nature12975. PMID 24463508. Bibcode2014Natur.506..185P. 
  9. "Bio-IT World". http://www.bio-itworld.com/2014/1/22/maddening-genetics-schizophrenia.html. 
  10. "Schizophrenia could be caused by a wide variety of DNA mutations". 2014-01-22. https://www.independent.co.uk/news/science/schizophrenia-could-be-caused-by-a-wide-variety-of-dna-mutations-rather-than-one-gene-9078284.html. 
  11. Makiko Yasuda; Lin Gan; Brenden Chen; Senkottuvelan Kadirvel; Chunli Yu; John D Phillips; Maria I New; Abigail Liebow et al. (May 12, 2014). "RNAi-mediated silencing of hepatic Alas1 effectively prevents and treats the induced acute attacks in acute intermittent porphyria mice". Proceedings of the National Academy of Sciences 111 (21): 7777–7782. doi:10.1073/pnas.1406228111. PMID 24821812. Bibcode2014PNAS..111.7777Y. 
  12. "FDA approves first treatment for inherited rare disease". November 20, 2019. https://www.fda.gov/news-events/press-announcements/fda-approves-first-treatment-inherited-rare-disease. 
  13. Manisha Balwani; Eliane Sardh; ENVISION Investigators (June 11, 2020). "Phase 3 Trial of RNAi Therapeutic Givosiran for Acute Intermittent Porphyria". The New England Journal of Medicine 382 (24): 2289–2301. doi:10.1056/NEJMoa1913147. PMID 32521132. 
  14. "Spatial CRISPR Genomics of Tumor Microenvironments". 16 March 2022. https://www.genengnews.com/lung-cancer-2/spatial-crispr-genomics-of-tumor-microenvironments/. 
  15. "Cell Papers on Viruses in Chinese Game Animals, Perturb-map, Tumor-Associated Macrophages". 30 March 2022. https://www.genomeweb.com/scan/cell-papers-viruses-chinese-game-animals-perturb-map-tumor-associated-macrophages#.Y5dUDi-B2X1. 
  16. "CRISPR Imaging Reveals Genes Behind Tumor Immunity". https://www.technologynetworks.com/tn/news/crispr-imaging-reveals-genes-behind-tumor-immunity-359667. 
  17. Dhainaut, Maxime; Rose, Samuel A.; Akturk, Guray; Wroblewska, Aleksandra; Nielsen, Sebastian R.; Park, Eun Sook; Buckup, Mark; Roudko, Vladimir et al. (2022). "Spatial CRISPR genomics identifies regulators of the tumor microenvironment". Cell 185 (7): 1223–1239.e20. doi:10.1016/j.cell.2022.02.015. PMID 35290801. 
  18. "Novel CRISPR Imaging Technology Reveals Genes Controlling Tumor Immunity | Mount Sinai - New York". https://www.mountsinai.org/about/newsroom/2022/novel-crispr-imaging-technology-reveals-genes-controlling-tumor-immunity. 
  19. "Spatial CRISPR Genomics of Tumor Microenvironments". 16 March 2022. https://www.genengnews.com/lung-cancer-2/spatial-crispr-genomics-of-tumor-microenvironments/. 
  20. Dhainaut, Maxime; Rose, Samuel; Akturk, Guray; Wroblewska, Aleksandra; Nielsen, Sebastian; Park, Eun; Buckup, Mark; Roudko, Vladimir et al. (March 31, 2022). "Spatial CRISPR genomics identifies regulators of the tumor microenvironment". Cell 185 (7): 1223–1239.e20. doi:10.1016/j.cell.2022.02.015. PMID 35290801. 
  21. Mouhieddine, Tarek H.; Van Oekelen, Oliver; Melnekoff, David T.; Li, Jeanne; Ghodke-Puranik, Yogita; Lancman, Guido; Thibaud, Santiago; Pan, Darren et al. (2022). "Sequencing T-cell redirection therapies leads to deep and durable responses in relapsed/Refractory myeloma patients". Blood Advances 7 (6): 1056–1064. doi:10.1182/bloodadvances.2022007923. PMID 36018226. 
  22. "Therapies That Engage T Cells Most Effective Against Relapsed or Refractory Multiple Myeloma". 9 November 2022. https://www.insideprecisionmedicine.com/topics/oncology/multiple-myeloma/therapies-that-engage-t-cells-most-effective-against-relapsed-or-refractory-multiple-myeloma/. 
  23. "Myeloma Patients Who Relapse After CAR T-Cell Therapy Have Options". 4 November 2022. https://www.medpagetoday.com/hematologyoncology/myeloma/101588. 
  24. https://aacrjournals.org/cancerimmunolres/article-abstract/10/11/1354/709883/Targeting-Macrophages-with-CAR-T-Cells-Delays?redirectedFrom=fulltext
  25. "Targeting of immune cells slows cancer growth in pre-clinical study". https://www.drugtargetreview.com/news/106055/targeting-of-immune-cells-slows-cancer-growth/. 
  26. "New approach to immunotherapy provokes a robust anti-tumor immune response in preclinical models". 25 October 2022. https://www.news-medical.net/news/20221025/New-approach-to-immunotherapy-provokes-a-robust-anti-tumor-immune-response-in-preclinical-models.aspx. 
  27. Campisi, Laura; Chizari, Shahab; Ho, Jessica S. Y.; Gromova, Anastasia; Arnold, Frederick J.; Mosca, Lorena; Mei, Xueyan; Fstkchyan, Yesai et al. (2022). "Clonally expanded CD8 T cells characterize amyotrophic lateral sclerosis-4". Nature 606 (7916): 945–952. doi:10.1038/s41586-022-04844-5. PMID 35732742. 
  28. "New ALS Research Breakthrough". https://chanzuckerberg.com/blog/ivan-marazzi-als-disease/. 
  29. "Partnering on Multiscale Biology - Bio-IT World". http://www.bio-itworld.com/BioIT_Article.aspx?id=108466. 
  30. "Carl Icahn to Give $200 Million to Mount Sinai School". 2012-11-15. https://www.bloomberg.com/news/2012-11-15/carl-icahn-to-give-200-million-to-mount-sinai-school.html. 
  31. Schadt, E. (2012). "Eric Schadt". Nature Biotechnology 30 (8): 769–770. doi:10.1038/nbt.2331. PMID 22871721. 
  32. "Q&A: Mount Sinai's Milind Mahajan on Running a CLIA-Certified Genomics Core Facility". 8 January 2013. http://www.genomeweb.com/sequencing/qa-mount-sinais-milind-mahajan-running-clia-certified-genomics-core-facility. 
  33. "Mount Sinai School of Medicine Offers First-Ever Course with Whole Genome Sequencing". http://www.prweb.com/releases/2012/10/prweb9990990.htm. 
  34. https://www.clinicalresearchnewsonline.com/news/2014/05/23/for-students-at-the-icahn-school-of-medicine-genomics-is-growing-more-personal
  35. "Joel Dudley". 2014-05-12. http://www.fastcompany.com/3029509/most-creative-people-2014/joel-dudley. 
  36. Friend, S. H.; Schadt, E. E. (2014). "Clues from the resilient". Science 344 (6187): 970–972. doi:10.1126/science.1255648. PMID 24876479. Bibcode2014Sci...344..970F. 
  37. "Welcome | the Resilience Project". http://resilienceproject.me/. 
  38. ""Genetic Heroes" May be Key to Treating Debilitating Diseases". http://www.scientificamerican.com/article/genetic-heroes-may-be-key-to-treating-debilitating-diseases/. 
  39. "How Healthy People Who Should be Sick Could Revolutionize Medicine". http://www.businessinsider.com/unexpected-heroes-resilience-project-2014-5. 
  40. "The Search for Genes That Prevent Disease". 2014-05-29. https://www.theatlantic.com/health/archive/2014/05/searching-for-the-genes-that-prevent-disease/371256/. 
  41. "CPTAC Announces New PCC, PGDAC, and PTRC Teams | Office of Cancer Clinical Proteomics Research". https://proteomics.cancer.gov/news_and_announcements/cptac-announces-new-pcc-pgdac-and-ptrc-teams?cid=eb_govdel. 
  42. "Mount Sinai Designated as National Cancer Institute Proteogenomics Data Analysis Center | Mount Sinai - New York". https://www.mountsinai.org/about/newsroom/2022/mount-sinai-designated-as-national-cancer-institute-proteogenomics-data-analysis-center. 



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