Mouse developmental defects, but not paraganglioma tumorigenesis, upon conditional Complex II loss in early Sox10+ cells

IF 2.5 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY
Elizabeth P. Lewis, Fatimah Al Khazal, Brandon Wilbanks, Naomi M. Gades, Patricia Ortega-Sáenz, José López-Barneo, Igor Adameyko, L. James Maher III
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Abstract

In humans, loss of heterozygosity for defective alleles of any of the four subunits of mitochondrial tricarboxylic acid cycle enzyme succinate dehydrogenase (SDH, also Complex II of the electron transport chain) can lead to paraganglioma tumors in neuroendocrine cells. With the goal of developing mouse models of this rare disorder, we have developed various SDH conditional loss strategies. Based on recent lineage tracing studies, we hypothesized that conditional SDHC loss in early embryogenesis during migration of primordial neural crest cells that form the susceptible chromaffin cells of the adrenal medulla might induce paraganglioma. We triggered low levels of detectable SDHC loss in Sox10+ cells at E11.5 of mouse development. We report that, rather than developing adrenal medulla paraganglioma (pheochromocytoma), offspring survived with evidence of neural crest cell dysfunction. Phenotypes included mild lower extremity gait anomalies suggestive of neural tube closure defects and patches of unpigmented fur consistent with neural crest-derived melanocyte dysfunction. These defects were not observed in mice lacking Sdhc knockout. Our results add to existing data suggesting that, unlike humans, even early embryonic (Sox10-driven) SDHx loss is inadequate to trigger paraganglioma in mice of the genetic backgrounds that have been investigated. Instead, low levels of tricarboxylic acid cycle-deficient neural crest cells cause mild developmental defects in hind limb and melanocyte function. This new model may be of interest for studies of metabolism during early neural crest cell development.

Abstract Image

早期 Sox10+ 细胞中条件性复合体 II 缺失会导致小鼠发育缺陷,但不会导致副神经节瘤肿瘤发生
在人类中,线粒体三羧酸循环酶琥珀酸脱氢酶(SDH,也是电子传递链的复合体 II)四个亚基中任何一个亚基的缺陷等位基因的杂合性缺失都会导致神经内分泌细胞中的副神经节瘤肿瘤。为了开发这种罕见疾病的小鼠模型,我们开发了多种 SDH 条件性缺失策略。根据最近的品系追踪研究,我们推测在胚胎早期形成肾上腺髓质嗜铬细胞的原始神经嵴细胞迁移过程中,条件性 SDHC 缺失可能会诱发副神经管瘤。我们在小鼠发育的 E11.5 阶段,在 Sox10+ 细胞中检测到了低水平的 SDHC 缺失。我们发现,小鼠的后代并没有发展成肾上腺髓质副神经节瘤(嗜铬细胞瘤),而是在神经嵴细胞功能障碍的证据下存活了下来。表型包括轻度下肢步态异常,提示神经管闭合缺陷,以及与神经嵴衍生黑色素细胞功能障碍一致的无色素皮毛斑块。在缺乏 Sdhc 基因敲除的小鼠中没有观察到这些缺陷。我们的研究结果补充了现有的数据,这些数据表明,与人类不同,即使是早期胚胎期(Sox10 驱动的)SDHx 缺失也不足以诱发已研究过的遗传背景小鼠的副神经节瘤。相反,低水平的三羧酸循环缺陷神经嵴细胞会导致后肢和黑色素细胞功能的轻度发育缺陷。这种新模型可能有助于研究神经嵴细胞早期发育过程中的新陈代谢。
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来源期刊
FASEB bioAdvances
FASEB bioAdvances Multiple-
CiteScore
5.40
自引率
3.70%
发文量
56
审稿时长
10 weeks
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