1.ERRATUM: Acknowledgments Correction. Bioinformatics Interpretation of Exome Sequencing: Blood Cancer.
Jiwoong KIM ; Yun Gyeong LEE ; Namshin KIM
Genomics & Informatics 2013;11(2):98-98
The funding acknowledgment in this article was partially omitted as published.
2.Bioinformatics Resources of the Korean Bioinformation Center (KOBIC).
Byungwook LEE ; In Sun CHU ; Namshin KIM ; Jinhyuk LEE ; Seon Yong KIM ; Wan Kyu KIM ; Sanghyuk LEE
Genomics & Informatics 2010;8(4):165-169
The Korean Bioinformation Center (KOBIC) is a national bioinformatics research center in Korea. We developed many bioinformatics algorithms and applications to facilitate the biological interpretation of OMICS data. Here we present an introduction to major bioinformatics resources of databases and tools developed at KOBIC. These resources are classified into three main fields: genome, proteome, and literature. In the genomic resources, we constructed several pipelines for next generation sequencing (NGS) data processing and developed analysis algorithms and web-based database servers including miRGator, ESTpass, and CleanEST. We also built integrated databases and servers for microarray expression data such as MDCDP. As for the proteome data, VnD database, WDAC, Localizome, and CHARMM_HM web servers are available for various purposes. We constructed IntoPub server and Patome database in the literature field. We continue constructing and maintaining the bioinformatics infrastructure and developing algorithms.
Computational Biology
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Genome
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Korea
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Proteome
3.Bioinformatics Interpretation of Exome Sequencing: Blood Cancer.
Jiwoong KIM ; Yun Gyeong LEE ; Namshin KIM
Genomics & Informatics 2013;11(1):24-33
We had analyzed 10 exome sequencing data and single nucleotide polymorphism chips for blood cancer provided by the PGM21 (The National Project for Personalized Genomic Medicine) Award program. We had removed sample G06 because the pair is not correct and G10 because of possible contamination. In-house software somatic copy-number and heterozygosity alteration estimation (SCHALE) was used to detect one loss of heterozygosity region in G05. We had discovered 27 functionally important mutations. Network and pathway analyses gave us clues that NPM1, GATA2, and CEBPA were major driver genes. By comparing with previous somatic mutation profiles, we had concluded that the provided data originated from acute myeloid leukemia. Protein structure modeling showed that somatic mutations in IDH2, RASGEF1B, and MSH4 can affect protein structures.
Awards and Prizes
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Computational Biology
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Exome
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Humans
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Leukemia, Myeloid, Acute
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Loss of Heterozygosity
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Polymorphism, Single Nucleotide
4.ChimerDB - Database of Chimeric Sequences in the GenBank.
Namshin KIM ; Seokmin SHIN ; Kwang Hwi CHO ; Sanghyuk LEE
Genomics & Informatics 2004;2(2):61-66
Fusion proteins resulting from chimeric sequences are excellent targets for therapeutic drug development. We developed a database of chimeric sequences by examining the genomic alignment of mRNA and EST sequences in the GenBank. We identified 688 chimeric mRNA and 20,998 chimeric EST sequences. Including EST sequences greatly expands the scope of chimeric sequences even though it inevitably accompanies many artifacts. Chimeric sequences are clustered according to the ECgene ID so that the user can easily find chimeric sequences related to a specific gene. Alignments of chimeric sequences are displayed as custom tracks in the UCSC genome browser. ChimerDB, available at http://genome.ewha.ac.kr/ECgene/ChimerDB/, should be a valuable resource for finding drug targets to treat cancers.
Artifacts
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Databases, Nucleic Acid*
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Genome
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RNA, Messenger
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Trans-Splicing
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Translocation, Genetic
5.Genetic Differences between Physical Injury Patients With and Without Post-traumatic Syndrome: Focus on Secondary Findings and Potential Variants Revealed by Whole Exome Sequencing
Hee-Ju KANG ; Ho-Yeon LEE ; Ki-Tae KIM ; Ju-Wan KIM ; Ju-Yeon LEE ; Sung-Wan KIM ; Jung-Chul KIM ; Il-Seon SHIN ; Namshin KIM ; Jae-Min KIM
Clinical Psychopharmacology and Neuroscience 2021;19(4):683-694
Objective:
Sudden traumatic physical injuries often cause psychological distress, which may be associated with chronic disability. Although considerable effort has been expended to identify genetic predictors of post-traumatic stress disorder (PTSD) after traumatic events, genetic predictors of psychological distress in response to severe physical injuries have been yet to be elucidated using whole exome sequencing (WES). Here, the genetic architecture of post-traumatic syndrome (PTS), which encompasses a broad range of psychiatric disorders after traumatic events including depression, anxiety disorder, acute stress disorder, and PTSD, was explored using WES in severely physically injured patients, focusing on secondary findings and potential PTS-related variants.
Methods:
In total, 141 severely physically injured patients were consecutively recruited, and PTS was evaluated within 1 month of the injury. Secondary findings were analyzed according to PTS status. To identify PTS-related variants, genome-wide association analyses and the optimal sequencing kernel association test were performed.
Results:
Of the 141 patients, 88 (62%) experienced PTS. There were 108 disease-causing variants in severely physically injured patients. As secondary findings, the stress- and inflammation-related signaling pathways were enriched in the PTS patients, while the glucose metabolism pathway was enriched in those without PTS. However, no significant PTS-related variants were identified.
Conclusion
Our findings suggest that genetic alterations in stress and inflammatory pathways might increase the likelihood of PTS immediately after severe physical injury. Future studies with larger samples and longitudinal designs are needed.
6.Effect of Next-Generation Exome Sequencing Depth for Discovery of Diagnostic Variants.
Kyung KIM ; Moon Woo SEONG ; Won Hyong CHUNG ; Sung Sup PARK ; Sangseob LEEM ; Won PARK ; Jihyun KIM ; Kiyoung LEE ; Rae Woong PARK ; Namshin KIM
Genomics & Informatics 2015;13(2):31-39
Sequencing depth, which is directly related to the cost and time required for the generation, processing, and maintenance of next-generation sequencing data, is an important factor in the practical utilization of such data in clinical fields. Unfortunately, identifying an exome sequencing depth adequate for clinical use is a challenge that has not been addressed extensively. Here, we investigate the effect of exome sequencing depth on the discovery of sequence variants for clinical use. Toward this, we sequenced ten germ-line blood samples from breast cancer patients on the Illumina platform GAII(x) at a high depth of ~200x. We observed that most function-related diverse variants in the human exonic regions could be detected at a sequencing depth of 120x. Furthermore, investigation using a diagnostic gene set showed that the number of clinical variants identified using exome sequencing reached a plateau at an average sequencing depth of about 120x. Moreover, the phenomena were consistent across the breast cancer samples.
Breast Neoplasms
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Exome*
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Exons
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Genetic Variation
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Humans
7.Bioinformatics services for analyzing massive genomic datasets
Gunhwan KO ; Pan-Gyu KIM ; Youngbum CHO ; Seongmun JEONG ; Jae-Yoon KIM ; Kyoung Hyoun KIM ; Ho-Yeon LEE ; Jiyeon HAN ; Namhee YU ; Seokjin HAM ; Insoon JANG ; Byunghee KANG ; Sunguk SHIN ; Lian KIM ; Seung-Won LEE ; Dougu NAM ; Jihyun F. KIM ; Namshin KIM ; Seon-Young KIM ; Sanghyuk LEE ; Tae-Young ROH ; Byungwook LEE
Genomics & Informatics 2020;18(1):e8-
The explosive growth of next-generation sequencing data has resulted in ultra-large-scale datasets and ensuing computational problems. In Korea, the amount of genomic data has been increasing rapidly in the recent years. Leveraging these big data requires researchers to use large-scale computational resources and analysis pipelines. A promising solution for addressing this computational challenge is cloud computing, where CPUs, memory, storage, and programs are accessible in the form of virtual machines. Here, we present a cloud computing-based system, Bio-Express, that provides user-friendly, cost-effective analysis of massive genomic datasets. Bio-Express is loaded with predefined multi-omics data analysis pipelines, which are divided into genome, transcriptome, epigenome, and metagenome pipelines. Users can employ predefined pipelines or create a new pipeline for analyzing their own omics data. We also developed several web-based services for facilitating downstream analysis of genome data. Bio-Express web service is freely available at https://www.bioexpress.re.kr/.
8.Bioinformatics services for analyzing massive genomic datasets
Gunhwan KO ; Pan-Gyu KIM ; Youngbum CHO ; Seongmun JEONG ; Jae-Yoon KIM ; Kyoung Hyoun KIM ; Ho-Yeon LEE ; Jiyeon HAN ; Namhee YU ; Seokjin HAM ; Insoon JANG ; Byunghee KANG ; Sunguk SHIN ; Lian KIM ; Seung-Won LEE ; Dougu NAM ; Jihyun F. KIM ; Namshin KIM ; Seon-Young KIM ; Sanghyuk LEE ; Tae-Young ROH ; Byungwook LEE
Genomics & Informatics 2020;18(1):e8-
The explosive growth of next-generation sequencing data has resulted in ultra-large-scale datasets and ensuing computational problems. In Korea, the amount of genomic data has been increasing rapidly in the recent years. Leveraging these big data requires researchers to use large-scale computational resources and analysis pipelines. A promising solution for addressing this computational challenge is cloud computing, where CPUs, memory, storage, and programs are accessible in the form of virtual machines. Here, we present a cloud computing-based system, Bio-Express, that provides user-friendly, cost-effective analysis of massive genomic datasets. Bio-Express is loaded with predefined multi-omics data analysis pipelines, which are divided into genome, transcriptome, epigenome, and metagenome pipelines. Users can employ predefined pipelines or create a new pipeline for analyzing their own omics data. We also developed several web-based services for facilitating downstream analysis of genome data. Bio-Express web service is freely available at https://www.bioexpress.re.kr/.