Johnson Martin R, Wang Kangsheng, Diasio Robert B
Department of Pharmacology and Toxicology and Comprehensive Cancer Center, University of Alabama at Birmingham, Birmingham, Alabama 35294, USA.
Clin Cancer Res. 2002 Mar;8(3):768-74.
A familial approach was used to elucidate the genetic determinants of profound and partial dihydropyrimidine dehydrogenase (DPD; EC 1.3.1.2) deficiency in an Alabama family. In 1988, our laboratory diagnosed profound DPD deficiency in a breast cancer patient with grade IV toxicity after cyclophosphamide/methotrexate/5-fluorouracil chemotherapy (R. B. Diasio et al., J. Clin. Investig., 81: 47-51, 1988). We now report the genetic analysis of archived genomic DNA that reveals that the proband was a compound heterozygote for two different mutations, one in each allele: (a) a G to A mutation in the GT 5' splicing recognition sequence of intron 14, which results in a 165-bp deletion (corresponding to exon 14) in the DPD mRNA (DPYD2A); and (b) a T1679G mutation (now designated DPYD13), which results in a I560S substitution. Sequence analysis revealed segregation of both mutations with the son and the daughter each inheriting one mutation. Phenotype analysis (DPD enzyme activity) confirmed that both children were partially DPD deficient. Plasma uracil and DPD mRNA levels were found to be within normal limits in both children. We conclude that profound DPD deficiency in the proband resulted from a combination of two mutations (one mutation in each allele) and that heterozygosity for either mutation results in partial DPD deficiency. Lastly, we identified two variant alleles reported previously as being associated with DPD enzyme deficiency [T85C resulting in a C29R substitution (DPYD*9A) and A496G (M166V) in a family member with normal DPD enzyme activity]. These data suggest that both variant alleles are unrelated to DPD deficiency and emphasize the need to perform detailed familial genotypic and phenotypic analysis while characterizing this pharmacogenetic syndrome.
采用家族研究方法来阐明阿拉巴马州一个家族中严重和部分二氢嘧啶脱氢酶(DPD;EC 1.3.1.2)缺乏症的遗传决定因素。1988年,我们实验室诊断出一名乳腺癌患者在接受环磷酰胺/甲氨蝶呤/5-氟尿嘧啶化疗后出现IV级毒性,存在严重的DPD缺乏症(R.B.迪亚西奥等人,《临床研究杂志》,81:47 - 51,1988)。我们现在报告对存档基因组DNA的遗传分析,结果显示先证者是两个不同突变的复合杂合子,每个等位基因各有一个突变:(a)内含子14的GT 5'剪接识别序列中的G到A突变,导致DPD mRNA(DPYD2A)中165个碱基对缺失(对应外显子14);(b)T1679G突变(现命名为DPYD13),导致I560S替换。序列分析显示两个突变均与子女分离,儿子和女儿各继承一个突变。表型分析(DPD酶活性)证实两个孩子均存在部分DPD缺乏。发现两个孩子的血浆尿嘧啶和DPD mRNA水平均在正常范围内。我们得出结论,先证者的严重DPD缺乏是由两个突变(每个等位基因一个突变)共同导致的,并且任一突变的杂合性都会导致部分DPD缺乏。最后,我们鉴定出两个先前报道与DPD酶缺乏相关的变异等位基因[T85C导致C29R替换(DPYD*9A)以及在一名DPD酶活性正常家族成员中的A496G(M166V)]。这些数据表明这两个变异等位基因均与DPD缺乏无关,并强调在表征这种药物遗传学综合征时进行详细的家族基因型和表型分析的必要性。
