Baquedano María Sonia, Ciaccio Marta, Marino Roxana, Perez Garrido Natalia, Ramirez Pablo, Maceiras Mercedes, Turjanski Adrian, Defelipe Lucas A, Rivarola Marco A, Belgorosky Alicia
Endocrine Service (M.S.B., M.C., R.M., N.P.G., P.R., M.M., M.A.R., A.B.), Hospital de Pediatria Garrahan, CONICET, Buenos Aires, Argentina; Biological Chemistry Department (A.T., L.A.D.), Instituto de Química Física de los Materiales Medio Ambiente y Energia (INQUIMAE)-CONICET, Facultad de Ciencias Exactas y Naturales, Universidad de Buenos Aires, Buenos Aires, Argentina.
J Clin Endocrinol Metab. 2015 Jan;100(1):E191-6. doi: 10.1210/jc.2014-2676.
3βHSD2 is a bifunctional microsomal NAD+-dependent enzyme crucial for adrenal and gonad steroid biosynthesis, converting Δ5-steroids to Δ4-steroids. 3βHSD2 deficiency is a rare cause of congenital adrenal hyperplasia caused by recessive loss-of-function HSD3B2 mutations.
The aim was to define the pathogenic consequences of a novel missense mutation in the HSD3B2 gene.
We report a 7-month-old 46,XX girl referred because of precocious pubarche and postnatal clitoromegaly. Hormonal profile showed inadequate glucocorticoid levels, increased 17OHP and renin levels, and very high DHEAS levels, suggestive of compensated nonsalt-losing 3βHSD2 deficiency.
Direct sequencing revealed a novel, homozygous, pG250V HSD3B2 mutation. In vitro analysis in intact COS-7 cells showed impaired enzymatic activity for the conversion of pregnenolone to progesterone and dehydroepiandrosterone to androstenedione (20% and 27% of WT at 6 h, respectively). G250V-3βHSD2 decreased the Vmax for progesterone synthesis without affecting the Km for pregnenolone. Western blot and immunofluorescence suggested that p.G250V mutation has no effect on the expression and intracellular localization of the mutant protein. Molecular homology modeling predicted that mutant V250 affected an L239-Q251 loop next to a β-sheet structure in the NAD+-binding domain.
We identified a novel p.G250V mutation of HSD3B2 which causes an incomplete loss of enzymatic activity, explaining the compensated nonsalt loss phenotype. In vitro and in silico experiments provided insight into the structure-function relationship of the 3βHSD2 protein suggesting the importance of the L239-Q251 loop for the catalytic activity of the otherwise stable 3βHSD2 enzyme.
3βHSD2是一种双功能微粒体NAD+依赖性酶,对肾上腺和性腺类固醇生物合成至关重要,可将Δ5-类固醇转化为Δ4-类固醇。3βHSD2缺乏是由隐性功能丧失性HSD3B2突变引起的先天性肾上腺增生的罕见原因。
本研究旨在确定HSD3B2基因中一个新的错义突变的致病后果。
我们报告了一名7个月大的46,XX女孩,因青春期过早出现阴毛和出生后阴蒂肥大前来就诊。激素水平显示糖皮质激素水平不足,17OHP和肾素水平升高,硫酸脱氢表雄酮水平非常高,提示为代偿性非失盐型3βHSD2缺乏。
直接测序发现了一个新的纯合pG250V HSD3B2突变。在完整的COS-7细胞中进行的体外分析显示,孕烯醇酮转化为孕酮以及脱氢表雄酮转化为雄烯二酮的酶活性受损(6小时时分别为野生型的20%和27%)。G250V-3βHSD2降低了孕酮合成的Vmax,但不影响孕烯醇酮的Km。蛋白质免疫印迹和免疫荧光表明,p.G250V突变对突变蛋白的表达和细胞内定位没有影响。分子同源性建模预测,突变体V250影响了NAD+结合域中β-折叠结构旁边的L239-Q251环。
我们鉴定出一种新的HSD3B2 p.G250V突变,该突变导致酶活性不完全丧失,解释了代偿性非失盐表型。体外和计算机模拟实验深入了解了3βHSD2蛋白的结构-功能关系,表明L239-Q251环对原本稳定的3βHSD2酶的催化活性很重要。
