Your search keyword '"Rosenbluh C"' showing total 4 results

1. Somatic mosaicism in schizophrenia brains reveals prenatal mutational processes.

Author

Maury EA, Jones A, Seplyarskiy V, Nguyen TTL, Rosenbluh C, Bae T, Wang Y, Abyzov A, Khoshkhoo S, Chahine Y, Zhao S, Venkatesh S, Root E, Voloudakis G, Roussos P, Park PJ, Akbarian S, Brennand K, Reilly S, Lee EA, Sunyaev SR, Walsh CA, and Chess A

Subjects

Female, Humans, Male, Binding Sites, Case-Control Studies, Chromatin metabolism, CpG Islands, Neurogenesis genetics, Neurons metabolism, Whole Genome Sequencing, Brain embryology, Brain metabolism, Mosaicism, Schizophrenia genetics, Transcription Factors genetics, Transcription Factors metabolism, Germ-Line Mutation

Abstract

Germline mutations modulate the risk of developing schizophrenia (SCZ). Much less is known about the role of mosaic somatic mutations in the context of SCZ. Deep (239×) whole-genome sequencing (WGS) of brain neurons from 61 SCZ cases and 25 controls postmortem identified mutations occurring during prenatal neurogenesis. SCZ cases showed increased somatic variants in open chromatin, with increased mosaic CpG transversions (CpG>GpG) and T>G mutations at transcription factor binding sites (TFBSs) overlapping open chromatin, a result not seen in controls. Some of these variants alter gene expression, including SCZ risk genes and genes involved in neurodevelopment. Although these mutational processes can reflect a difference in factors indirectly involved in disease, increased somatic mutations at developmental TFBSs could also potentially contribute to SCZ.

Published

2024

2. Comprehensive identification of somatic nucleotide variants in human brain tissue.

Author

Wang Y, Bae T, Thorpe J, Sherman MA, Jones AG, Cho S, Daily K, Dou Y, Ganz J, Galor A, Lobon I, Pattni R, Rosenbluh C, Tomasi S, Tomasini L, Yang X, Zhou B, Akbarian S, Ball LL, Bizzotto S, Emery SB, Doan R, Fasching L, Jang Y, Juan D, Lizano E, Luquette LJ, Moldovan JB, Narurkar R, Oetjens MT, Rodin RE, Sekar S, Shin JH, Soriano E, Straub RE, Zhou W, Chess A, Gleeson JG, Marquès-Bonet T, Park PJ, Peters MA, Pevsner J, Walsh CA, Weinberger DR, Vaccarino FM, Moran JV, Urban AE, Kidd JM, Mills RE, and Abyzov A

Subjects

Alleles, Chromosome Mapping, Computational Biology methods, Genomics methods, Germ Cells metabolism, High-Throughput Nucleotide Sequencing, Humans, Organ Specificity genetics, Polymorphism, Single Nucleotide, Brain metabolism, Genetic Association Studies methods, Genetic Variation

Abstract

Background: Post-zygotic mutations incurred during DNA replication, DNA repair, and other cellular processes lead to somatic mosaicism. Somatic mosaicism is an established cause of various diseases, including cancers. However, detecting mosaic variants in DNA from non-cancerous somatic tissues poses significant challenges, particularly if the variants only are present in a small fraction of cells., Results: Here, the Brain Somatic Mosaicism Network conducts a coordinated, multi-institutional study to examine the ability of existing methods to detect simulated somatic single-nucleotide variants (SNVs) in DNA mixing experiments, generate multiple replicates of whole-genome sequencing data from the dorsolateral prefrontal cortex, other brain regions, dura mater, and dural fibroblasts of a single neurotypical individual, devise strategies to discover somatic SNVs, and apply various approaches to validate somatic SNVs. These efforts lead to the identification of 43 bona fide somatic SNVs that range in variant allele fractions from ~ 0.005 to ~ 0.28. Guided by these results, we devise best practices for calling mosaic SNVs from 250× whole-genome sequencing data in the accessible portion of the human genome that achieve 90% specificity and sensitivity. Finally, we demonstrate that analysis of multiple bulk DNA samples from a single individual allows the reconstruction of early developmental cell lineage trees., Conclusions: This study provides a unified set of best practices to detect somatic SNVs in non-cancerous tissues. The data and methods are freely available to the scientific community and should serve as a guide to assess the contributions of somatic SNVs to neuropsychiatric diseases.

Published

2021

3. Intersection of diverse neuronal genomes and neuropsychiatric disease: The Brain Somatic Mosaicism Network.

Author

McConnell MJ, Moran JV, Abyzov A, Akbarian S, Bae T, Cortes-Ciriano I, Erwin JA, Fasching L, Flasch DA, Freed D, Ganz J, Jaffe AE, Kwan KY, Kwon M, Lodato MA, Mills RE, Paquola ACM, Rodin RE, Rosenbluh C, Sestan N, Sherman MA, Shin JH, Song S, Straub RE, Thorpe J, Weinberger DR, Urban AE, Zhou B, Gage FH, Lehner T, Senthil G, Walsh CA, Chess A, Courchesne E, Gleeson JG, Kidd JM, Park PJ, Pevsner J, and Vaccarino FM

Subjects

Brain metabolism, Cell Division genetics, DNA Damage, DNA Mutational Analysis methods, DNA Repair genetics, DNA Replication, Genome, Human, Germ Cells metabolism, Humans, Nerve Net growth & development, Nerve Net metabolism, Neural Stem Cells metabolism, Neurons metabolism, Brain abnormalities, Mental Disorders genetics, Mosaicism, Nervous System Diseases genetics, Neural Stem Cells physiology, Neurons physiology

Abstract

Neuropsychiatric disorders have a complex genetic architecture. Human genetic population-based studies have identified numerous heritable sequence and structural genomic variants associated with susceptibility to neuropsychiatric disease. However, these germline variants do not fully account for disease risk. During brain development, progenitor cells undergo billions of cell divisions to generate the ~80 billion neurons in the brain. The failure to accurately repair DNA damage arising during replication, transcription, and cellular metabolism amid this dramatic cellular expansion can lead to somatic mutations. Somatic mutations that alter subsets of neuronal transcriptomes and proteomes can, in turn, affect cell proliferation and survival and lead to neurodevelopmental disorders. The long life span of individual neurons and the direct relationship between neural circuits and behavior suggest that somatic mutations in small populations of neurons can significantly affect individual neurodevelopment. The Brain Somatic Mosaicism Network has been founded to study somatic mosaicism both in neurotypical human brains and in the context of complex neuropsychiatric disorders., (Copyright © 2017, American Association for the Advancement of Science.)

Published

2017

4. Intersection of diverse neuronal genomes and neuropsychiatric disease: The Brain Somatic Mosaicism Network

Author

Mcconnell, Mj, Moran, Jv, Abyzov, A, Akbarian, S, Bae, T, Cortes-Ciriano, I, Erwin, Ja, Fasching, L, Flasch, Da, Freed, D, Ganz, J, Jaffe, Ae, Kwan, Ky, Kwon, M, Lodato, Ma, Mills, Re, Paquola, Acm, Rodin, Re, Rosenbluh, C, Sestan, N, Sherman, Ma, Shin, Jh, Song, S, Straub, Re, Thorpe, J, Weinberger, Dr, Urban, Ae, Zhou, B, Gage, Fh, Lehner, T, Senthil, G, Walsh, Ca, Chess, A, Courchesne, E, Gleeson, Jg, Kidd, Jm, Park, Pj, Pevsner, J, Vaccarino, Fm, Barton, Ar, Bekiranov, S, Bohrson, Cl, Burbulis, Ie, Chronister, W, Coppola, G, Daily, K, D'Gama, Am, Emery, Sb, Frisbie, Tj, Gao, T, Gulyás-Kovács, A, Haakenson, M, Keil, Jm, Kopera, Hc, Lam, Mm, Lee, Ea, Marques-Bonet, T, Mathern, Gw, Moldovan, Jb, Oetjens, Mt, Omberg, L, Peters, Ma, Pochareddy, S, Pramparo, T, Ratan, A, Sanavia, T, Shi, L, Skarica, M, Wang, J, Wang, M, Wang, Y, Wierman, M, Wolpert, M, Woodworth, M, Zhao, X, and Zhou, W

Subjects

DNA Replication, 0301 basic medicine, DNA Repair, Brain Somatic Mosaicism, Somatic cell, DNA Mutational Analysis, Genomics, Disease, Biology, Article, Germline, 03 medical and health sciences, Neural Stem Cells, Humans, Copy-number variation, Neurons, Genetics, Multidisciplinary, Genome, Human, Mosaicism, Mental Disorders, Brain, Phenotype, Germ Cells, 030104 developmental biology, Human genome, Nerve Net, Nervous System Diseases, Cell Division, Neurotypical, DNA Damage

Abstract

BACKGROUND Elucidating the genetic architecture of neuropsychiatric disorders remains a major scientific and medical challenge. Emerging genomic technologies now permit the analysis of somatic mosaicism in human tissues. The measured frequencies of single-nucleotide variants (SNVs), small insertion/deletion (indel) mutations, structural variants [including copy number variants (CNVs), inversions, translocations, and whole-chromosome gains or losses], and mobile genetic element insertions (MEIs) indicate that each neuron may harbor hundreds of somatic mutations. Given the long life span of neurons and their central role in neural circuits and behavior, somatic mosaicism represents a potential mechanism that may contribute to neuronal diversity and the etiology of numerous neuropsychiatric disorders. ADVANCES Somatic mutations that confer cellular proliferative or cellular survival phenotypes have been identified in patients with cortical malformations. These data have led to the hypothesis that somatic mutations may also confer phenotypes to subsets of neurons, which could increase the risk of developing certain neuropsychiatric disorders. Genomic technologies, including advances in long-read, next-generation DNA sequencing technologies, single-cell genomics, and cutting-edge bioinformatics, can now make it possible to determine the types and frequencies of somatic mutations within the human brain. However, a comprehensive understanding of the contribution of somatic mosaicism to neurotypical brain development and neuropsychiatric disease requires a coordinated, multi-institutional effort. The National Institute of Mental Health (NIMH) has formed a network of 18 investigative teams representing 15 institutions called the Brain Somatic Mosaicism Network (BSMN). Each research team will use an array of genomic technologies to exploit well-curated human tissue repositories in an effort to define the frequency and pattern of somatic mutations in neurotypical individuals and in schizophrenia, autism spectrum disorder, bipolar disorder, Tourette syndrome, and epilepsy patient populations. Collectively, these efforts are estimated to generate a community resource of more than 10,000 DNA-sequencing data sets and will enable a cross-platform integrated analysis with other NIMH initiatives, such as the PsychENCODE project and the CommonMind Consortium. OUTLOOK A fundamental open question in neurodevelopmental genetics is whether and how somatic mosaicism may contribute to neuronal diversity within the neurotypical spectrum and in diseased brains. Healthy individuals may harbor known pathogenic somatic mutations at subclinical frequencies, and the local composition of neural cell types may be altered by mutations conferring prosurvival phenotypes in subsets of neurons. By extension, the neurotypical architecture of somatic mutations may confer circuit-level differences that would not be present if every neuron had an identical genome. Given the apparent abundance of somatic mutations within neurons, an in-depth understanding of how different types of somatic mosaicism affect neural function could yield mechanistic insight into the etiology of neurodevelopmental and neuropsychiatric disorders. The BSMN will examine large collections of postmortem brain tissue from neurotypical individuals and patients with neuropsychiatric disorders. By sequencing brain DNA and single neuronal genomes directly, rather than genomic DNA derived from peripheral blood or other somatic tissues, the BSMN will test the hypothesis that brain somatic variants contribute to neuropsychiatric disease. Notably, it is also possible that some inherited germline variants confer susceptibility to disease, which is later exacerbated by somatic mutations. Confirming such a scenario could increase our understanding of the genetic risk architecture of neuropsychiatric disease and may, in part, explain discordant neuropsychiatric phenotypes between identical twins. Results from these studies may lead to the discovery of biomarkers and genetic targets to improve the treatment of neuropsychiatric disease and may offer hope for improving the lives of patients and their families.

Published

2017