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40 results on '"Sasani, Thomas A"'

1. Poxviruses capture host genes by LINE-1 retrotransposition

Author

Fixsen, Sarah M, Cone, Kelsey R, Goldstein, Stephen A, Sasani, Thomas A, Quinlan, Aaron R, Rothenburg, Stefan, and Elde, Nels C

Subjects
Microbiology, Biological Sciences, Genetics, Biodefense, Emerging Infectious Diseases, Small Pox, Rare Diseases, Infectious Diseases, 2.1 Biological and endogenous factors, Infection, Evolution, Molecular, Gene Transfer, Horizontal, Phylogeny, Poxviridae, RNA, Messenger, Viruses, Retroelements, vaccinia virus, horizontal gene transfer, adaptive evolution, poxvirus, Human, evolutionary biology, human, infectious disease, microbiology, viruses, Biochemistry and Cell Biology, Biological sciences, Biomedical and clinical sciences, Health sciences
Abstract

Horizontal gene transfer (HGT) provides a major source of genetic variation. Many viruses, including poxviruses, encode genes with crucial functions directly gained by gene transfer from hosts. The mechanism of transfer to poxvirus genomes is unknown. Using genome analysis and experimental screens of infected cells, we discovered a central role for Long Interspersed Nuclear Element-1 retrotransposition in HGT to virus genomes. The process recapitulates processed pseudogene generation, but with host messenger RNA directed into virus genomes. Intriguingly, hallmark features of retrotransposition appear to favor virus adaption through rapid duplication of captured host genes on arrival. Our study reveals a previously unrecognized conduit of genetic traffic with fundamental implications for the evolution of many virus classes and their hosts.

Published
2022

18. Germline mutation rates in young adults predict longevity and reproductive lifespan

Author

Cawthon, Richard M., primary, Meeks, Huong D., additional, Sasani, Thomas A., additional, Smith, Ken R., additional, Kerber, Richard A., additional, O’Brien, Elizabeth, additional, Baird, Lisa, additional, Dixon, Melissa M., additional, Peiffer, Andreas P., additional, Leppert, Mark F., additional, Quinlan, Aaron R., additional, and Jorde, Lynn B., additional

Published
2019
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26. Nanopore sequencing and assembly of a human genome with ultra-long reads

Author

Jain, Miten, primary, Koren, Sergey, additional, Miga, Karen H, additional, Quick, Josh, additional, Rand, Arthur C, additional, Sasani, Thomas A, additional, Tyson, John R, additional, Beggs, Andrew D, additional, Dilthey, Alexander T, additional, Fiddes, Ian T, additional, Malla, Sunir, additional, Marriott, Hannah, additional, Nieto, Tom, additional, O'Grady, Justin, additional, Olsen, Hugh E, additional, Pedersen, Brent S, additional, Rhie, Arang, additional, Richardson, Hollian, additional, Quinlan, Aaron R, additional, Snutch, Terrance P, additional, Tee, Louise, additional, Paten, Benedict, additional, Phillippy, Adam M, additional, Simpson, Jared T, additional, Loman, Nicholas J, additional, and Loose, Matthew, additional

Published
2018
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31. Overlooked roles of DNA damage and maternal age in generating human germline mutations.

Author

Ziyue Gao, Moorjani, Priya, Sasani, Thomas A., Pedersen, Brent S., Quinlan, Aaron R., Jorde, Lynn B., Amster, Guy, and Przeworski, Molly

Subjects
GERM cells, GENETIC mutation, PATERNAL age effect, DNA replication, GENE expression
Abstract

The textbook view that most germline mutations in mammals arise from replication errors is indirectly supported by the fact that there are both more mutations and more cell divisions in the male than in the female germline. When analyzing large de novo mutation datasets in humans, we find multiple lines of evidence that call that view into question. Notably, despite the drastic increase in the ratio of male to female germ cell divisions after the onset of spermatogenesis, even young fathers contribute three times more mutations than young mothers, and this ratio barely increases with parental age. This surprising finding points to a substantial contribution of damage-induced mutations. Indeed, C-to-G transversions and CpG transitions, which together constitute over one-fourth of all base substitution mutations, show genomic distributions and sex-specific age dependencies indicative of double-strand break repair and methylation-associated damage, respectively. Moreover, we find evidence that maternal age at conception influences the mutation rate both because of the accumulation of damage in oocytes and potentially through an influence on the number of postzygotic mutations in the embryo. These findings reveal underappreciated roles of DNA damage and maternal age in the genesis of human germline mutations. [ABSTRACT FROM AUTHOR]

Published
2019
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32. Additional file 4: of Discovery of rare, diagnostic AluYb8/9 elements in diverse human populations

Author

Feusier, Julie, Witherspoon, David, W. Scott Watkins, ClĂŠment Goubert, Sasani, Thomas, and Jorde, Lynn

Subjects
3. Good health
Abstract

FASTA sequences of 68 Alu elements. This file contains high-quality sequence from Sanger sequencing of 68 Alu elements. The nucleotides are color-coded for Alu, TSD, A and B boxes, SRP9/14 sites, and pol III termination signals (DOCX 34 kb)

35. Additional file 4: of Discovery of rare, diagnostic AluYb8/9 elements in diverse human populations

Author

Feusier, Julie, Witherspoon, David, W. Scott Watkins, ClĂŠment Goubert, Sasani, Thomas, and Jorde, Lynn

Subjects
3. Good health
Abstract

FASTA sequences of 68 Alu elements. This file contains high-quality sequence from Sanger sequencing of 68 Alu elements. The nucleotides are color-coded for Alu, TSD, A and B boxes, SRP9/14 sites, and pol III termination signals (DOCX 34 kb)

38. A familial, telomere-to-telomere reference for human de novo mutation and recombination from a four-generation pedigree.

Author

Porubsky D, Dashnow H, Sasani TA, Logsdon GA, Hallast P, Noyes MD, Kronenberg ZN, Mokveld T, Koundinya N, Nolan C, Steely CJ, Guarracino A, Dolzhenko E, Harvey WT, Rowell WJ, Grigorev K, Nicholas TJ, Oshima KK, Lin J, Ebert P, Watkins WS, Leung TY, Hanlon VCT, McGee S, Pedersen BS, Goldberg ME, Happ HC, Jeong H, Munson KM, Hoekzema K, Chan DD, Wang Y, Knuth J, Garcia GH, Fanslow C, Lambert C, Lee C, Smith JD, Levy S, Mason CE, Garrison E, Lansdorp PM, Neklason DW, Jorde LB, Quinlan AR, Eberle MA, and Eichler EE

Abstract

Using five complementary short- and long-read sequencing technologies, we phased and assembled >95% of each diploid human genome in a four-generation, 28-member family (CEPH 1463) allowing us to systematically assess de novo mutations (DNMs) and recombination. From this family, we estimate an average of 192 DNMs per generation, including 75.5 de novo single-nucleotide variants (SNVs), 7.4 non-tandem repeat indels, 79.6 de novo indels or structural variants (SVs) originating from tandem repeats, 7.7 centromeric de novo SVs and SNVs, and 12.4 de novo Y chromosome events per generation. STRs and VNTRs are the most mutable with 32 loci exhibiting recurrent mutation through the generations. We accurately assemble 288 centromeres and six Y chromosomes across the generations, documenting de novo SVs, and demonstrate that the DNM rate varies by an order of magnitude depending on repeat content, length, and sequence identity. We show a strong paternal bias (75-81%) for all forms of germline DNM, yet we estimate that 17% of de novo SNVs are postzygotic in origin with no paternal bias. We place all this variation in the context of a high-resolution recombination map (~3.5 kbp breakpoint resolution). We observe a strong maternal recombination bias (1.36 maternal:paternal ratio) with a consistent reduction in the number of crossovers with increasing paternal (r=0.85) and maternal (r=0.65) age. However, we observe no correlation between meiotic crossover locations and de novo SVs, arguing against non-allelic homologous recombination as a predominant mechanism. The use of multiple orthogonal technologies, near-telomere-to-telomere phased genome assemblies, and a multi-generation family to assess transmission has created the most comprehensive, publicly available "truth set" of all classes of genomic variants. The resource can be used to test and benchmark new algorithms and technologies to understand the most fundamental processes underlying human genetic variation., Competing Interests: Conflicts of interest E.E.E. is a scientific advisory board (SAB) member of Variant Bio, Inc. C.Lee is an SAB member of Nabsys and Genome Insight. D.P. has previously disclosed a patent application (no. EP19169090) relevant to Strand-seq. Z.K., C.N., E.D., C.F., C.Lambert, T.M., W.J.R., and M.A.E. are employees and shareholders of PacBio. Z.K. is a private shareholder in Phase Genomics. The other authors declare no competing interests.

Published
2024
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39. Decoding chromosome organization using CheC-PLS: chromosome conformation by proximity labeling and long-read sequencing.

Author

Xu K, Zhang Y, Baldwin-Brown J, Sasani TA, Phadnis N, Miller MP, and Rog O

Abstract

Genomic approaches have provided detailed insight into chromosome architecture. However, commonly deployed techniques do not preserve connectivity-based information, leaving large-scale genome organization poorly characterized. Here, we developed CheC-PLS: a proximity-labeling technique that indelibly marks, and then decodes, protein-associated sites. CheC-PLS tethers dam methyltransferase to a protein of interest, followed by Nanopore sequencing to identify methylated bases - indicative of in vivo proximity - along reads >100kb. As proof-of-concept we analyzed, in budding yeast, a cohesin-based meiotic backbone that organizes chromatin into an array of loops. Our data recapitulates previously obtained association patterns, and, importantly, exposes variability between cells. Single read data reveals cohesin translocation on DNA and, by anchoring reads onto unique regions, we define the internal organization of the ribosomal DNA locus. Our versatile technique, which we also deployed on isolated nuclei with nanobodies, promises to illuminate diverse chromosomal processes by describing the in vivo conformations of single chromosomes.

Published
2024
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40. Epistasis between mutator alleles contributes to germline mutation spectra variability in laboratory mice.

Author

Sasani TA, Quinlan AR, and Harris K

Abstract

Maintaining germline genome integrity is essential and enormously complex. Although many proteins are involved in DNA replication, proofreading, and repair [1], mutator alleles have largely eluded detection in mammals. DNA replication and repair proteins often recognize sequence motifs or excise lesions at specific nucleotides. Thus, we might expect that the spectrum of de novo mutations - the frequencies of C>T, A>G, etc. - will differ between genomes that harbor either a mutator or wild-type allele. Previously, we used quantitative trait locus mapping to discover candidate mutator alleles in the DNA repair gene Mutyh that increased the C>A germline mutation rate in a family of inbred mice known as the BXDs [2,3]. In this study we developed a new method to detect alleles associated with mutation spectrum variation and applied it to mutation data from the BXDs. We discovered an additional C>A mutator locus on chromosome 6 that overlaps Ogg1 , a DNA glycosylase involved in the same base-excision repair network as Mutyh [4]. Its effect depended on the presence of a mutator allele near Mutyh , and BXDs with mutator alleles at both loci had greater numbers of C>A mutations than those with mutator alleles at either locus alone. Our new methods for analyzing mutation spectra reveal evidence of epistasis between germline mutator alleles and may be applicable to mutation data from humans and other model organisms.

Published
2023
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