Your search keyword '"Yao, Jiqiang"' showing total 6 results

1. Normal IgH Repertoire Diversity in an Infant with ADA Deficiency After Gene Therapy.

Author

Baloh, Carolyn H, Baloh, Carolyn H, Borkar, Samiksha A, Chang, Kai-Fen, Yao, Jiqiang, Hershfield, Michael S, Parikh, Suhag H, Kohn, Donald B, Goodenow, Maureen M, Sleasman, John W, Yin, Li, Baloh, Carolyn H, Baloh, Carolyn H, Borkar, Samiksha A, Chang, Kai-Fen, Yao, Jiqiang, Hershfield, Michael S, Parikh, Suhag H, Kohn, Donald B, Goodenow, Maureen M, Sleasman, John W, and Yin, Li

Abstract

PurposeAdenosine deaminase (ADA) deficiency causes severe combined immunodeficiency (SCID) through an accumulation of toxic metabolites within lymphocytes. Recently, ADA deficiency has been successfully treated using lentiviral-transduced autologous CD34+ cells carrying the ADA gene. T and B cell function appears to be fully restored, but in many patients' B cell numbers remain low, and assessments of the immunoglobulin heavy (IgHV) repertoire following gene therapy are lacking.MethodsWe performed deep sequencing of IgHV repertoire in peripheral blood lymphocytes from a child following lentivirus-based gene therapy for ADA deficiency and compared to the IgHV repertoire in healthy infants and adults.ResultsAfter gene therapy, Ig diversity increased over time as evidenced by V, D, and J gene usage, N-additions, CDR3 length, extent of somatic hypermutation, and Ig class switching. There was the emergence of predominant IgHM, IgHG, and IgHA CDR3 lengths after gene therapy indicating successful oligoclonal expansion in response to antigens. This provides proof of concept for the feasibility and utility of molecular monitoring in following B cell reconstitution following gene therapy for ADA deficiency.ConclusionBased on deep sequencing, gene therapy resulted in an IgHV repertoire with molecular diversity similar to healthy infants.

Published

2021

2. Characterization of Capsicum annuum genetic diversity and population structure based on parallel polymorphism discovery with a 30K unigene Pepper GeneChip.

Author

Hill, Theresa A, Hill, Theresa A, Ashrafi, Hamid, Reyes-Chin-Wo, Sebastian, Yao, JiQiang, Stoffel, Kevin, Truco, Maria-Jose, Kozik, Alexander, Michelmore, Richard W, Van Deynze, Allen, Hill, Theresa A, Hill, Theresa A, Ashrafi, Hamid, Reyes-Chin-Wo, Sebastian, Yao, JiQiang, Stoffel, Kevin, Truco, Maria-Jose, Kozik, Alexander, Michelmore, Richard W, and Van Deynze, Allen

Abstract

The widely cultivated pepper, Capsicum spp., important as a vegetable and spice crop world-wide, is one of the most diverse crops. To enhance breeding programs, a detailed characterization of Capsicum diversity including morphological, geographical and molecular data is required. Currently, molecular data characterizing Capsicum genetic diversity is limited. The development and application of high-throughput genome-wide markers in Capsicum will facilitate more detailed molecular characterization of germplasm collections, genetic relationships, and the generation of ultra-high density maps. We have developed the Pepper GeneChip® array from Affymetrix for polymorphism detection and expression analysis in Capsicum. Probes on the array were designed from 30,815 unigenes assembled from expressed sequence tags (ESTs). Our array design provides a maximum redundancy of 13 probes per base pair position allowing integration of multiple hybridization values per position to detect single position polymorphism (SPP). Hybridization of genomic DNA from 40 diverse C. annuum lines, used in breeding and research programs, and a representative from three additional cultivated species (C. frutescens, C. chinense and C. pubescens) detected 33,401 SPP markers within 13,323 unigenes. Among the C. annuum lines, 6,426 SPPs covering 3,818 unigenes were identified. An estimated three-fold reduction in diversity was detected in non-pungent compared with pungent lines, however, we were able to detect 251 highly informative markers across these C. annuum lines. In addition, an 8.7 cM region without polymorphism was detected around Pun1 in non-pungent C. annuum. An analysis of genetic relatedness and diversity using the software Structure revealed clustering of the germplasm which was confirmed with statistical support by principle components analysis (PCA) and phylogenetic analysis. This research demonstrates the effectiveness of parallel high-throughput discovery and application of genome-wide

Published

2013

3. Characterization of Capsicum annuum genetic diversity and population structure based on parallel polymorphism discovery with a 30K unigene Pepper GeneChip.

Author

Hill, Theresa A, Zhang, Jianwei1, Hill, Theresa A, Ashrafi, Hamid, Reyes-Chin-Wo, Sebastian, Yao, JiQiang, Stoffel, Kevin, Truco, Maria-Jose, Kozik, Alexander, Michelmore, Richard W, Van Deynze, Allen, Hill, Theresa A, Zhang, Jianwei1, Hill, Theresa A, Ashrafi, Hamid, Reyes-Chin-Wo, Sebastian, Yao, JiQiang, Stoffel, Kevin, Truco, Maria-Jose, Kozik, Alexander, Michelmore, Richard W, and Van Deynze, Allen

Abstract

The widely cultivated pepper, Capsicum spp., important as a vegetable and spice crop world-wide, is one of the most diverse crops. To enhance breeding programs, a detailed characterization of Capsicum diversity including morphological, geographical and molecular data is required. Currently, molecular data characterizing Capsicum genetic diversity is limited. The development and application of high-throughput genome-wide markers in Capsicum will facilitate more detailed molecular characterization of germplasm collections, genetic relationships, and the generation of ultra-high density maps. We have developed the Pepper GeneChip® array from Affymetrix for polymorphism detection and expression analysis in Capsicum. Probes on the array were designed from 30,815 unigenes assembled from expressed sequence tags (ESTs). Our array design provides a maximum redundancy of 13 probes per base pair position allowing integration of multiple hybridization values per position to detect single position polymorphism (SPP). Hybridization of genomic DNA from 40 diverse C. annuum lines, used in breeding and research programs, and a representative from three additional cultivated species (C. frutescens, C. chinense and C. pubescens) detected 33,401 SPP markers within 13,323 unigenes. Among the C. annuum lines, 6,426 SPPs covering 3,818 unigenes were identified. An estimated three-fold reduction in diversity was detected in non-pungent compared with pungent lines, however, we were able to detect 251 highly informative markers across these C. annuum lines. In addition, an 8.7 cM region without polymorphism was detected around Pun1 in non-pungent C. annuum. An analysis of genetic relatedness and diversity using the software Structure revealed clustering of the germplasm which was confirmed with statistical support by principle components analysis (PCA) and phylogenetic analysis. This research demonstrates the effectiveness of parallel high-throughput discovery and application of genome-wide

Published

2013

4. De novo assembly of the pepper transcriptome (Capsicum annuum): a benchmark for in silico discovery of SNPs, SSRs and candidate genes

Author

Ashrafi, Hamid, Ashrafi, Hamid, Hill, Theresa, Stoffel, Kevin, Kozik, Alexander, Yao, JiQiang, Chin-Wo, Sebastian, Van Deynze, Allen, Ashrafi, Hamid, Ashrafi, Hamid, Hill, Theresa, Stoffel, Kevin, Kozik, Alexander, Yao, JiQiang, Chin-Wo, Sebastian, and Van Deynze, Allen

Abstract

Background Molecular breeding of pepper (Capsicum spp.) can be accelerated by developing DNA markers associated with transcriptomes in breeding germplasm. Before the advent of next generation sequencing (NGS) technologies, the majority of sequencing data were generated by the Sanger sequencing method. By leveraging Sanger EST data, we have generated a wealth of genetic information for pepper including thousands of SNPs and Single Position Polymorphic (SPP) markers. To complement and enhance these resources, we applied NGS to three pepper genotypes: Maor, Early Jalapeño and Criollo de Morelos-334 (CM334) to identify SNPs and SSRs in the assembly of these three genotypes. Results Two pepper transcriptome assemblies were developed with different purposes. The first reference sequence, assembled by CAP3 software, comprises 31,196 contigs from >125,000 Sanger-EST sequences that were mainly derived from a Korean F1-hybrid line, Bukang. Overlapping probes were designed for 30,815 unigenes to construct a pepper Affymetrix GeneChip® microarray for whole genome analyses. In addition, custom Python scripts were used to identify 4,236 SNPs in contigs of the assembly. A total of 2,489 simple sequence repeats (SSRs) were identified from the assembly, and primers were designed for the SSRs. Annotation of contigs using Blast2GO software resulted in information for 60% of the unigenes in the assembly. The second transcriptome assembly was constructed from more than 200 million Illumina Genome Analyzer II reads (80–120 nt) using a combination of Velvet, CLC workbench and CAP3 software packages. BWA, SAMtools and in-house Perl scripts were used to identify SNPs among three pepper genotypes. The SNPs were filtered to be at least 50 bp from any intron-exon junctions as well as flanking SNPs. More than 22,000 high-quality putative SNPs were identified. Using the MISA software, 10,398 SSR markers were also identified within the Illumina transcriptome assembly and primers were

Published

2012

5. De novo assembly of the pepper transcriptome (Capsicum annuum): a benchmark for in silico discovery of SNPs, SSRs and candidate genes

Author

Ashrafi, Hamid, Ashrafi, Hamid, Hill, Theresa, Stoffel, Kevin, Kozik, Alexander, Yao, JiQiang, Chin-Wo, Sebastian, Van Deynze, Allen, Ashrafi, Hamid, Ashrafi, Hamid, Hill, Theresa, Stoffel, Kevin, Kozik, Alexander, Yao, JiQiang, Chin-Wo, Sebastian, and Van Deynze, Allen

Abstract

Background Molecular breeding of pepper (Capsicum spp.) can be accelerated by developing DNA markers associated with transcriptomes in breeding germplasm. Before the advent of next generation sequencing (NGS) technologies, the majority of sequencing data were generated by the Sanger sequencing method. By leveraging Sanger EST data, we have generated a wealth of genetic information for pepper including thousands of SNPs and Single Position Polymorphic (SPP) markers. To complement and enhance these resources, we applied NGS to three pepper genotypes: Maor, Early Jalapeño and Criollo de Morelos-334 (CM334) to identify SNPs and SSRs in the assembly of these three genotypes. Results Two pepper transcriptome assemblies were developed with different purposes. The first reference sequence, assembled by CAP3 software, comprises 31,196 contigs from >125,000 Sanger-EST sequences that were mainly derived from a Korean F1-hybrid line, Bukang. Overlapping probes were designed for 30,815 unigenes to construct a pepper Affymetrix GeneChip® microarray for whole genome analyses. In addition, custom Python scripts were used to identify 4,236 SNPs in contigs of the assembly. A total of 2,489 simple sequence repeats (SSRs) were identified from the assembly, and primers were designed for the SSRs. Annotation of contigs using Blast2GO software resulted in information for 60% of the unigenes in the assembly. The second transcriptome assembly was constructed from more than 200 million Illumina Genome Analyzer II reads (80–120 nt) using a combination of Velvet, CLC workbench and CAP3 software packages. BWA, SAMtools and in-house Perl scripts were used to identify SNPs among three pepper genotypes. The SNPs were filtered to be at least 50 bp from any intron-exon junctions as well as flanking SNPs. More than 22,000 high-quality putative SNPs were identified. Using the MISA software, 10,398 SSR markers were also identified within the Illumina transcriptome assembly and primers were

Published

2012

6. Somatic mutations affect key pathways in lung adenocarcinoma

Author

Ding, Li, Getz, Gad, Wheeler, David A, Mardis, Elaine R, McLellan, Michael D, Cibulskis, Kristian, Sougnez, Carrie, Greulich, Heidi, Muzny, Donna M, Morgan, Margaret B, Fulton, Lucinda, Fulton, Robert S, Zhang, Qunyuan, Wendl, Michael C, Lawrence, Michael S, Larson, David E, Chen, Ken, Dooling, David J, Sabo, Aniko, Hawes, Alicia C, Shen, Hua, Jhangiani, Shalini N, Lewis, Lora R, Hall, Otis, Zhu, Yiming, Mathew, Tittu, Ren, Yanru, Yao, Jiqiang, Scherer, Steven E, Clerc, Kerstin, Metcalf, Ginger A, Ng, Brian, Milosavljevic, Aleksandar, Gonzalez-Garay, Manuel L, Osborne, John R, Meyer, Rick, Shi, Xiaoqi, Tang, Yuzhu, Koboldt, Daniel C, Lin, Ling, Abbott, Rachel, Miner, Tracie L, Pohl, Craig, Fewell, Ginger, Haipek, Carrie, Schmidt, Heather, Dunford-Shore, Brian H, Kraja, Aldi, Crosby, Seth D, Sawyer, Christopher S, Vickery, Tammi, Sander, Sacha, Robinson, Jody, Winckler, Wendy, Baldwin, Jennifer, Chirieac, Lucian R, Dutt, Amit, Fennell, Tim, Hanna, Megan, Johnson, Bruce E, Onofrio, Robert C, Thomas, Roman K, Tonon, Giovanni, Weir, Barbara A, Zhao, Xiaojun, Ziaugra, Liuda, Zody, Michael C., Giordano, Thomas, Orringer, Mark B, Roth, Jack A, Spitz, Margaret R, Wistuba, Ignacio I, Ozenberger, Bradley, Good, Peter J, Chang, Andrew C, Beer, David G, Watson, Mark A, Ladanyi, Marc, Broderick, Stephen, Yoshizawa, Akihiko, Travis, William D, Pao, William, Province, Michael A, Weinstock, George M, Varmus, Harold E, Gabriel, Stacey B, Lander, Eric S, Gibbs, Richard A, Meyerson, Matthew, Wilson, Richard K, Ding, Li, Getz, Gad, Wheeler, David A, Mardis, Elaine R, McLellan, Michael D, Cibulskis, Kristian, Sougnez, Carrie, Greulich, Heidi, Muzny, Donna M, Morgan, Margaret B, Fulton, Lucinda, Fulton, Robert S, Zhang, Qunyuan, Wendl, Michael C, Lawrence, Michael S, Larson, David E, Chen, Ken, Dooling, David J, Sabo, Aniko, Hawes, Alicia C, Shen, Hua, Jhangiani, Shalini N, Lewis, Lora R, Hall, Otis, Zhu, Yiming, Mathew, Tittu, Ren, Yanru, Yao, Jiqiang, Scherer, Steven E, Clerc, Kerstin, Metcalf, Ginger A, Ng, Brian, Milosavljevic, Aleksandar, Gonzalez-Garay, Manuel L, Osborne, John R, Meyer, Rick, Shi, Xiaoqi, Tang, Yuzhu, Koboldt, Daniel C, Lin, Ling, Abbott, Rachel, Miner, Tracie L, Pohl, Craig, Fewell, Ginger, Haipek, Carrie, Schmidt, Heather, Dunford-Shore, Brian H, Kraja, Aldi, Crosby, Seth D, Sawyer, Christopher S, Vickery, Tammi, Sander, Sacha, Robinson, Jody, Winckler, Wendy, Baldwin, Jennifer, Chirieac, Lucian R, Dutt, Amit, Fennell, Tim, Hanna, Megan, Johnson, Bruce E, Onofrio, Robert C, Thomas, Roman K, Tonon, Giovanni, Weir, Barbara A, Zhao, Xiaojun, Ziaugra, Liuda, Zody, Michael C., Giordano, Thomas, Orringer, Mark B, Roth, Jack A, Spitz, Margaret R, Wistuba, Ignacio I, Ozenberger, Bradley, Good, Peter J, Chang, Andrew C, Beer, David G, Watson, Mark A, Ladanyi, Marc, Broderick, Stephen, Yoshizawa, Akihiko, Travis, William D, Pao, William, Province, Michael A, Weinstock, George M, Varmus, Harold E, Gabriel, Stacey B, Lander, Eric S, Gibbs, Richard A, Meyerson, Matthew, and Wilson, Richard K

Abstract

Determining the genetic basis of cancer requires comprehensive analyses of large collections of histopathologically well-classified primary tumours. Here we report the results of a collaborative study to discover somatic mutations in 188 human lung adenocarcinomas. DNA sequencing of 623 genes with known or potential relationships to cancer revealed more than 1,000 somatic mutations across the samples. Our analysis identified 26 genes that are mutated at significantly high frequencies and thus are probably involved in carcinogenesis. The frequently mutated genes include tyrosine kinases, among them the EGFR homologue ERBB4; multiple ephrin receptor genes, notably EPHA3; vascular endothelial growth factor receptor KDR; and NTRK genes. These data provide evidence of somatic mutations in primary lung adenocarcinoma for several tumour suppressor genes involved in other cancers--including NF1, APC, RB1 and ATM--and for sequence changes in PTPRD as well as the frequently deleted gene LRP1B. The observed mutational profiles correlate with clinical features, smoking status and DNA repair defects. These results are reinforced by data integration including single nucleotide polymorphism array and gene expression array. Our findings shed further light on several important signalling pathways involved in lung adenocarcinoma, and suggest new molecular targets for treatment.

Published

2008