Your search keyword '"Rimma, Shakhbatyan"' showing total 5 results

1. Validation and implementation of whole-exome sequencing bioinformatics processes for clinical applications.

Author

Rimma Shakhbatyan, Himanshu Sharma, Ellen Tsai, Mark J. Bowser, Birgit Funke, and Matthew S. Lebo

Published

2014

2. Comprehensive Diagnostic Testing for Stereocilin

Author

Sami S. Amr, Mark Bowser, Katherine A Lafferty, Lisa Mahanta, Bryan Harrison, Elizabeth Duffy, Trevor J. Pugh, Rimma Shakhbatyan, Sivakumar Gowrisankar, Birgit Funke, Diana Mandelker, and Heidi L. Rehm

Subjects

Genetics, medicine.diagnostic_test, Hearing loss, Pseudogene, Locus (genetics), Biology, Gene dosage, Pathology and Forensic Medicine, medicine, Molecular Medicine, medicine.symptom, Gene, Exome, Genetic testing, STRC

Abstract

Next-generation sequencing (NGS) technologies have revolutionized genetic testing by enabling simultaneous analysis of unprecedented numbers of genes. However, genes with high-sequence homology pose challenges to current NGS technologies. Because diagnostic sequencing is moving toward exome analysis, knowledge of these homologous genes is essential to avoid false positive and negative results. An example is the STRC gene, one of >70 genes known to contribute to the genetic basis of hearing loss. STRC is 99.6% identical to a pseudogene (pSTRC) and therefore inaccessible to standard NGS methodologies. The STRC locus is also known to be a common site for large deletions. Comprehensive diagnostic testing for inherited hearing loss therefore necessitates a combination of several approaches to avoid pseudogene interference. We have developed a clinical test that combines standard NGS and NGS-based copy number assessment supplemented with a long-range PCR-based Sanger or MiSeq assay to eliminate pseudogene contamination. By using this combination of assays we could identify biallelic STRC variants in 14% (95% CI, 8%–24%) of individuals with isolated nonsyndromic hearing loss who had previously tested negative on our 70-gene hearing loss panel, corresponding to a detection rate of 11.2% (95% CI, 6%–19%) for previously untested patients. This approach has broad applicability because medically significant genes for many disease areas include genes with high-sequence homology.

Published

2014

3. HIV Integration Site Analysis of Cellular Models of HIV Latency with a Probe-Enriched Next-Generation Sequencing Assay

Author

Rory Kirchner, Robert F. Siliciano, Rimma Shakhbatyan, Vicente Planelles, Michelle M. Kim, Shannan J. Ho Sui, Alberto Bosque, Oliver Hofmann, Jonathan Z. Li, Sara Sunshine, Leandra Mansur, and Sami S. Amr

Subjects

0301 basic medicine, Sequence analysis, Virus Integration, 030106 microbiology, Immunology, HIV integration, HIV Infections, Biology, Microbiology, Deep sequencing, Cell Line, 03 medical and health sciences, Virology, Virus latency, medicine, Humans, Latency (engineering), Gene, Cells, Cultured, Genetics, Chromosome Mapping, Computational Biology, HIV, High-Throughput Nucleotide Sequencing, Sequence Analysis, DNA, medicine.disease, Genome Replication and Regulation of Viral Gene Expression, Virus Latency, 030104 developmental biology, Insect Science, Human genome, DNA Probes

Abstract

Antiretroviral therapy (ART) is successful in the suppression of HIV but cannot target and eradicate the latent proviral reservoir. The location of retroviral integration into the human genome is thought to play a role in the clonal expansion of infected cells and HIV persistence. We developed a high-throughput targeted sequence capture assay that uses a pool of HIV-specific probes to enrich Illumina libraries prior to deep sequencing. Using an expanded clonal population of ACH-2 cells, we demonstrate that this sequence capture assay has an extremely low false-positive rate. This assay assessed four cellular models commonly used to study HIV latency and latency-reversing agents: ACH-2 cells, J-Lat cells, the Bcl-2-transduced primary CD4 + model, and the cultured T CM (central memory) CD4 + model. HIV integration site characteristics and genes were compared between these cellular models and to previously reported patient data sets. Across these cellular models, there were significant differences in integration site characteristics, including orientation relative to that of the host gene, the proportion of clonally expanded sites, and the proportion located within genic regions and exons. Despite a greater diversity of minority integration sites than expected in ACH-2 cells, their integration site characteristics consistently differed from those of the other models and from the patient samples. Gene ontology analysis of highly represented genes from the patient samples found little overlap with HIV-containing genes from the cell lines. These findings show that integration site differences exist among the commonly used cellular models of HIV latency and in comparison to integration sites found in patient samples. IMPORTANCE Despite the success of ART, currently there is no successful therapy to eradicate integrated proviruses. Cellular models of HIV latency are used to test the efficacy of latency-reversing agents, but it is unclear how well these models reflect HIV integration into the human genome in vivo . We have developed a novel probe-based sequence enrichment assay to sequence and analyze integrated HIV. We compared HIV integration site characteristics between four cellular models and to previously described patient data sets. Significant differences were detected in the distribution of HIV integration sites between cellular models of HIV latency and compared to data sets from patient samples. The results from this study have implications for how well these cellular models of HIV infection truly reflect HIV integration in vivo and their applicability in drug discovery for novel latency-reversing agents.

Published

2016

4. Plasmodium cynomolgi genome sequences provide insight into Plasmodium vivax and the monkey malaria clade

Author

Jane M. Carlton, Kazuyuki Tanabe, Takahiro Tougan, Osamu Kaneko, Toshihiro Mita, Shin-Ichiro Tachibana, Steven A. Sullivan, Masanori Yagi, Nirianne Marie Q. Palacpac, John W. Barnwell, Hyunjae R. Kim, Nobuko Arisue, Shota Nakamura, Yasuhiro Yasutomi, Kiyoshi Kita, Ananias A. Escalante, Hajime Honma, Yuko Katakai, Rimma Shakhbatyan, Teruo Yasunaga, Satoru Kawai, Toshihiro Horii, Patrick L. Sutton, and Naohisa Goto

Subjects

Plasmodium vivax, Genes, Protozoan, Simian, Genome, 0302 clinical medicine, single nucleotide polymorphism, genetic variability, Cluster Analysis, Copy-number variation, Clade, Phylogeny, Genetics, 0303 health sciences, biology, Monkey Diseases, article, copy number variation, Cercopithecidae, Haplorhini, cell invasion, 3. Good health, priority journal, Plasmodium knowlesi, Plasmodium cynomolgi, 030231 tropical medicine, Molecular Sequence Data, malaria, gene sequence, gene frequency, Simiae, 03 medical and health sciences, Genetic variation, parasitic diseases, Animals, Genetic variability, multigene family, 030304 developmental biology, nonhuman, Base Sequence, Models, Genetic, gene duplication, nucleotide sequence, Sequence Analysis, DNA, biology.organism_classification, unindexed sequence, microsatellite DNA, erythrocyte, Genome, Protozoan

Abstract

P. cynomolgi, a malaria-causing parasite of Asian Old World monkeys, is the sister taxon of P. vivax, the most prevalent malaria-causing species in humans outside of Africa. Because P. cynomolgi shares many phenotypic, biological and genetic characteristics with P. vivax, we generated draft genome sequences for three P. cynomolgi strains and performed genomic analysis comparing them with the P. vivax genome, as well as with the genome of a third previously sequenced simian parasite, Plasmodium knowlesi. Here, we show that genomes of the monkey malaria clade can be characterized by copy-number variants (CNVs) in multigene families involved in evasion of the human immune system and invasion of host erythrocytes. We identify genome-wide SNPs, microsatellites and CNVs in the P. cynomolgi genome, providing a map of genetic variation that can be used to map parasite traits and study parasite populations. The sequencing of the P. cynomolgi genome is a critical step in developing a model system for P. vivax research and in counteracting the neglect of P. vivax., Nature Genetics, 44(9), pp.1051-1055; 2012

Published

2012

5. Comprehensive diagnostic testing for stereocilin: an approach for analyzing medically important genes with high homology

Author

Diana, Mandelker, Sami S, Amr, Trevor, Pugh, Sivakumar, Gowrisankar, Rimma, Shakhbatyan, Elizabeth, Duffy, Mark, Bowser, Bryan, Harrison, Katherine, Lafferty, Lisa, Mahanta, Heidi L, Rehm, and Birgit H, Funke

Subjects

Cohort Studies, Base Sequence, Gene Dosage, Humans, Intercellular Signaling Peptides and Proteins, Membrane Proteins, Hearing Loss, Sequence Analysis, DNA Primers

Abstract

Next-generation sequencing (NGS) technologies have revolutionized genetic testing by enabling simultaneous analysis of unprecedented numbers of genes. However, genes with high-sequence homology pose challenges to current NGS technologies. Because diagnostic sequencing is moving toward exome analysis, knowledge of these homologous genes is essential to avoid false positive and negative results. An example is the STRC gene, one of70 genes known to contribute to the genetic basis of hearing loss. STRC is 99.6% identical to a pseudogene (pSTRC) and therefore inaccessible to standard NGS methodologies. The STRC locus is also known to be a common site for large deletions. Comprehensive diagnostic testing for inherited hearing loss therefore necessitates a combination of several approaches to avoid pseudogene interference. We have developed a clinical test that combines standard NGS and NGS-based copy number assessment supplemented with a long-range PCR-based Sanger or MiSeq assay to eliminate pseudogene contamination. By using this combination of assays we could identify biallelic STRC variants in 14% (95% CI, 8%-24%) of individuals with isolated nonsyndromic hearing loss who had previously tested negative on our 70-gene hearing loss panel, corresponding to a detection rate of 11.2% (95% CI, 6%-19%) for previously untested patients. This approach has broad applicability because medically significant genes for many disease areas include genes with high-sequence homology.

Published

2014