1.Comprehensive Variant Screening of the UGT Gene Family.
Jason Yongha KIM ; Hyun Sub CHEONG ; Byung Lae PARK ; Lyoung Hyo KIM ; Suhg NAMGOONG ; Ji On KIM ; Hae Deun KIM ; Young Hoon KIM ; Myeon Woo CHUNG ; Soon Young HAN ; Hyoung Doo SHIN
Yonsei Medical Journal 2014;55(1):232-239
PURPOSE: UGT1A1, UGT2B7, and UGT2B15 are well-known pharmacogenes that belong to the uridine diphosphate glucuronyltransferase gene family. For personalized drug treatment, it is important to study differences in the frequency of core markers across various ethnic groups. Accordingly, we screened single nucleotide polymorphisms (SNPs) of these three genes and analyzed differences in their frequency among five ethnic groups, as well as attempted to predict the function of novel SNPs. MATERIALS AND METHODS: We directly sequenced 288 subjects consisting of 96 Korean, 48 Japanese, 48 Han Chinese, 48 African American, and 48 European American subjects. Subsequently, we analyzed genetic variability, linkage disequilibrium (LD) structures and ethnic differences for each gene. We also conducted in silico analysis to predict the function of novel SNPs. RESULTS: A total of 87 SNPs were detected, with seven pharmacogenetic core SNPs and 31 novel SNPs. We observed that the frequencies of UGT1A1 *6 (rs4148323), UGT1A1 *60 (rs4124874), UGT1A1 *93 (rs10929302), UGT2B7 *2 (rs7439366), a part of UGT2B7 *3 (rs12233719), and UGT2B15 *2 (rs1902023) were different between Asian and other ethnic groups. Additional in silico analysis results showed that two novel promoter SNPs of UGT1A1 -690G>A and -689A>C were found to potentially change transcription factor binding sites. Moreover, 673G>A (UGT2B7), 2552T>C, and 23269C>T (both SNPs from UGT2B15) changed amino acid properties, which could cause structural deformation. CONCLUSION: Findings from the present study would be valuable for further studies on pharmacogenetic studies of personalized medicine and drug response.
Asian Continental Ancestry Group/genetics
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European Continental Ancestry Group/genetics
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Female
;
Gene Frequency/genetics
;
Glucuronosyltransferase/*genetics
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Haplotypes/genetics
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Humans
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Linkage Disequilibrium/genetics
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Male
;
Polymorphism, Single Nucleotide/*genetics
2.Association Analysis of TEC Polymorphisms with Aspirin-Exacerbated Respiratory Disease in a Korean Population.
Jin Sol LEE ; Joon Seol BAE ; Byung Lae PARK ; Hyun Sub CHEONG ; Jeong Hyun KIM ; Jason Yongha KIM ; Suhg NAMGOONG ; Ji On KIM ; Choon Sik PARK ; Hyoung Doo SHIN
Genomics & Informatics 2014;12(2):58-63
The tyrosine-protein kinase Tec (TEC) is a member of non-receptor tyrosine kinases and has critical roles in cell signaling transmission, calcium mobilization, gene expression, and transformation. TEC is also involved in various immune responses, such as mast cell activation. Therefore, we hypothesized that TEC polymorphisms might be involved in aspirin-exacerbated respiratory disease (AERD) pathogenesis. We genotyped 38 TEC single nucleotide polymorphisms in a total of 592 subjects, which comprised 163 AERD cases and 429 aspirin-tolerant asthma controls. Logistic regression analysis was performed to examine the associations between TEC polymorphisms and the risk of AERD in a Korean population. The results revealed that TEC polymorphisms and major haplotypes were not associated with the risk of AERD. In another regression analysis for the fall rate of forced expiratory volume in 1 second (FEV1) by aspirin provocation, two variations (rs7664091 and rs12500534) and one haplotype (TEC_BL2_ht4) showed nominal associations with FEV1 decline (p = 0.03-0.04). However, the association signals were not retained after performing corrections for multiple testing. Despite TEC playing an important role in immune responses, the results from the present study suggest that TEC polymorphisms do not affect AERD susceptibility. Findings from the present study might contribute to the genetic etiology of AERD pathogenesis.
Aspirin
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Asthma
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Calcium
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Forced Expiratory Volume
;
Gene Expression
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Haplotypes
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Logistic Models
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Mast Cells
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Phosphotransferases
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Polymorphism, Genetic
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Polymorphism, Single Nucleotide
;
Tyrosine
3.Screening of Dihydropyrimidine Dehydrogenase Genetic Variants by Direct Sequencing in Different Ethnic Groups.
Joong Gon SHIN ; Hyun Sub CHEONG ; Jason Yongha KIM ; Lyoung Hyo KIM ; Chang Soo HAN ; Ji On KIM ; Hae Deun KIM ; Young Hoon KIM ; Myeon Woo CHUNG ; Soon Young HAN ; Hyoung Doo SHIN
Journal of Korean Medical Science 2013;28(8):1129-1133
Dihydropyrimidine dehydrogenase (DPYD) is an enzyme that regulates the rate-limiting step in pyrimidine metabolism, especially catabolism of fluorouracil, a chemotherapeutic agent for cancer. In order to determine the genetic distribution of DPYD, we directly sequenced 288 subjects from five ethnic groups (96 Koreans, 48 Japanese, 48 Han Chinese, 48 African Americans, and 48 European Americans). As a result, 56 polymorphisms were observed, including 6 core polymorphisms and 18 novel polymorphisms. Allele frequencies were nearly the same across the Asian populations, Korean, Han Chinese and Japanese, whereas several SNPs showed different genetic distributions between Asians and other ethnic populations (African American and European American). Additional in silico analysis was performed to predict the function of novel SNPs. One nonsynonymous SNP (+199381A > G, Asn151Asp) was predicted to change its polarity of amino acid (Asn, neutral to Asp, negative). These findings would be valuable for further research, including pharmacogenetic and drug responses studies.
African Americans/genetics
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Alleles
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Amino Acids/metabolism
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Asian Continental Ancestry Group/genetics
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Dihydrouracil Dehydrogenase (NADP)/*genetics
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Ethnic Groups/*genetics
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European Continental Ancestry Group/genetics
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Fluorouracil/metabolism
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Gene Frequency
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Genotype
;
Humans
;
Polymorphism, Single Nucleotide
;
Sequence Analysis, DNA
4.Screening of Dihydropyrimidine Dehydrogenase Genetic Variants by Direct Sequencing in Different Ethnic Groups.
Joong Gon SHIN ; Hyun Sub CHEONG ; Jason Yongha KIM ; Lyoung Hyo KIM ; Chang Soo HAN ; Ji On KIM ; Hae Deun KIM ; Young Hoon KIM ; Myeon Woo CHUNG ; Soon Young HAN ; Hyoung Doo SHIN
Journal of Korean Medical Science 2013;28(8):1129-1133
Dihydropyrimidine dehydrogenase (DPYD) is an enzyme that regulates the rate-limiting step in pyrimidine metabolism, especially catabolism of fluorouracil, a chemotherapeutic agent for cancer. In order to determine the genetic distribution of DPYD, we directly sequenced 288 subjects from five ethnic groups (96 Koreans, 48 Japanese, 48 Han Chinese, 48 African Americans, and 48 European Americans). As a result, 56 polymorphisms were observed, including 6 core polymorphisms and 18 novel polymorphisms. Allele frequencies were nearly the same across the Asian populations, Korean, Han Chinese and Japanese, whereas several SNPs showed different genetic distributions between Asians and other ethnic populations (African American and European American). Additional in silico analysis was performed to predict the function of novel SNPs. One nonsynonymous SNP (+199381A > G, Asn151Asp) was predicted to change its polarity of amino acid (Asn, neutral to Asp, negative). These findings would be valuable for further research, including pharmacogenetic and drug responses studies.
African Americans/genetics
;
Alleles
;
Amino Acids/metabolism
;
Asian Continental Ancestry Group/genetics
;
Dihydrouracil Dehydrogenase (NADP)/*genetics
;
Ethnic Groups/*genetics
;
European Continental Ancestry Group/genetics
;
Fluorouracil/metabolism
;
Gene Frequency
;
Genotype
;
Humans
;
Polymorphism, Single Nucleotide
;
Sequence Analysis, DNA
5.Association Analysis Between FILIP1 Polymorphisms and Aspirin Hypersensitivity in Korean Asthmatics.
Jason Yongha KIM ; Jeong Hyun KIM ; Byung Lae PARK ; Charisse Flerida A PASAJE ; Joon Seol BAE ; Jong Sook PARK ; An Soo JANG ; Soo Taek UH ; Yong Hoon KIM ; Mi Kyeong KIM ; Inseon S CHOI ; Sang Heon CHO ; Byoung Whui CHOI ; Choon Sik PARK ; Hyoung Doo SHIN
Allergy, Asthma & Immunology Research 2013;5(1):34-41
PURPOSE: Aspirin exacerbated respiratory disease (AERD) results in a severe asthma attack after aspirin ingestion in asthmatics. The filamin A interacting protein 1 (FILIP1) may play a crucial role in AERD pathogenesis by mediating T cell activation and membrane rearrangement. We investigated the association of FILIP1 variations with AERD and the fall rate of forced expiratory volume in one second (FEV1). METHODS: A total of 34 common FILIP1 single nucleotide polymorphisms (SNPs) were genotyped in 592 Korean asthmatic subjects that included 163 AERD patients and 429 aspirin-tolerant asthma (ATA) controls. RESULTS: This study found that 5 SNPs (P=0.006-0.01) and 2 haplotypes (P=0.01-0.03) of FILIP1 showed nominal signals; however, corrections for the multiple testing revealed no significant associations with the development of AERD (P corr>0.05). In addition, association analysis of the genetic variants with the fall rate of FEV1, an important diagnostic marker of AERD, revealed no significant evidence (P corr>0.05). CONCLUSIONS: Although further replications and functional evaluations are needed, our preliminary findings suggest that genetic variants of FILIP1 might be not associated with the onset of AERD.
Aspirin
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Asthma
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Contractile Proteins
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Eating
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Forced Expiratory Volume
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Haplotypes
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Humans
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Hypersensitivity
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Membranes
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Microfilament Proteins
;
Negotiating
;
Polymorphism, Single Nucleotide