Matabosch Xavier, Rahman Mahbuba, Hughes Beverly, Patel Shailendra B, Watson Gordon, Shackleton Cedric
Children's Hospital Oakland Research Institute, 5700 Martin Luther King Jr Way, Oakland, CA 94609, USA.
J Steroid Biochem Mol Biol. 2009 Aug;116(1-2):61-70. doi: 10.1016/j.jsbmb.2009.04.011. Epub 2009 May 3.
This study has shown that the mouse has a great increase in steroid production during pregnancy in similar fashion to the human. Many steroids were provisionally identified in maternal urine of the wild-type mouse. The major progesterone metabolites appear to be hydroxylated pregnanolones, particularly with hydroxyl groups in the 16alpha position. Rather than estriol being the major end-product of feto-placental steroid synthesis as in the human, the pregnant mouse produces and excretes large amounts of androgen metabolites, ranging in polarity from androstanetriols to androstanepentols. These steroids have 15alpha- or 18-hydroxyl groups with additional hydroxylation at uncharacterized positions. From metabolite data the peak of pregnancy progesterone production appears to be between 7.5 and 14.5 gestational days, while for C(19) metabolites peak excretion is later. The starting-point of the studies was to study pregnancy steroid production by a mouse model for Smith-Lemli-Opitz syndrome, 7-dehydrosterol reductase (DHCR7) deficiency. In human pregnancies with DHCR7 deficient fetuses large amounts of 7- and 8-dehydrosteroids are excreted, products secondary to high fetal 7- and 8-dehydrocholesterol (DHC) accumulation. This agrees with existing evidence that human feto-placental steroid synthesis utilizes little maternal cholesterol as precursor. In contrast, this study has shown that pregnant mice carrying dhcr7 deficient fetuses with relatively high DHC production had essentially undetectable maternal excretions of steroids with Delta(7)- and Delta(8)-unsaturation. As mutant mouse mothers have essentially normal cholesterol production (little or no DHC build-up), this suggests maternal cholesterol is primarily utilized for pregnancy steroid synthesis in the mouse.
这项研究表明,小鼠在孕期类固醇生成量大幅增加,其方式与人类相似。在野生型小鼠的母体尿液中初步鉴定出了多种类固醇。主要的孕酮代谢产物似乎是羟基化孕烷醇酮,尤其是在16α位带有羟基的那些。与人类不同,雌三醇并非胎儿 - 胎盘类固醇合成的主要终产物,怀孕小鼠会产生并排泄大量雄激素代谢产物,其极性范围从雄甾三醇到雄甾戊醇。这些类固醇具有15α - 或18 - 羟基,且在未明确的位置还有额外的羟基化。从代谢产物数据来看,孕期孕酮生成的峰值似乎出现在妊娠第7.5至14.5天之间,而C(19)代谢产物的排泄峰值则较晚。这些研究的出发点是通过一个针对史密斯 - 利姆利 - 奥皮茨综合征(7 - 脱氢胆固醇还原酶(DHCR7)缺乏症)的小鼠模型来研究孕期类固醇生成。在怀有DHCR7缺陷胎儿的人类孕期中,会排泄大量的7 - 和8 - 脱氢类固醇,这些是胎儿7 - 和8 - 脱氢胆固醇(DHC)大量积累后的产物。这与现有证据相符,即人类胎儿 - 胎盘类固醇合成很少利用母体胆固醇作为前体。相比之下,这项研究表明,怀有dhcr7缺陷胎儿且DHC生成量相对较高的怀孕小鼠,其母体中几乎检测不到具有Δ(7) - 和Δ(8) - 不饱和键的类固醇排泄。由于突变小鼠母亲的胆固醇生成基本正常(很少或没有DHC积累),这表明母体胆固醇主要用于小鼠孕期的类固醇合成。