Special Centre for Molecular Medicine, Jawaharlal Nehru University, New Delhi 110067, India.
National Centre for Disease Control, New Delhi, India.
Biochim Biophys Acta Gene Regul Mech. 2023 Mar;1866(1):194891. doi: 10.1016/j.bbagrm.2022.194891. Epub 2022 Nov 14.
Vitamin D receptor (VDR) is a member of the nuclear receptor superfamily. It is a primary regulator of calcium and phosphate homeostasis required for skeleton and bone mineralization. Vitamin D in active form 1α,25 dihydroxyvitamin-D3 mediates its cellular functions by binding to VDR. Active VDR forms heterodimers with partner RXR (retinoid X receptor) to execute its physiological actions. HVDRR (Hereditary Vitamin D-Resistant Rickets) is a rare genetic disorder that occurs because of generalized resistance to the 1α,25(OH)D3. HVDRR is caused by the polymorphic variations in VDR gene leading to defective intestinal calcium absorption and mineralization of newly forming bones. Using point and deletion SNPs of VDR we have studied several HVDRR-associated SNP variants for their subcellular dynamics, transcriptional functions, 'genome bookmarking', heterodimeric interactions with RXR, and receptor stability. We previously reported that VDR is a 'mitotic bookmarking factor' that remains constitutively associated with the mitotic chromatin to inherit 'transcriptional memory', however the mechanistic details remained unclear. We document that 'genome bookmarking' property by VDR is critically impaired by naturally occurring HVDRR-associated point and deletion variants found in patients. Furthermore, these HVDRR-associated SNP variants of VDR were found to be compromised in transcriptional function, nuclear translocation, protein stability and intermolecular interactions with its heterodimeric partner RXR. Intriguingly, majority of these disease-allied functional defects failed to be rescued by RXR. Our findings suggest that the HVDRR-associated SNP variations influence the normal functioning of the receptor, and this derived understanding may help in the management of disease with precisely designed small molecule modulators.
维生素 D 受体(VDR)是核受体超家族的成员。它是调节钙和磷稳态的主要因子,对于骨骼和骨矿化至关重要。活性形式的 1α,25 二羟维生素 D3 通过与 VDR 结合来介导其细胞功能。活性 VDR 与伴侣 RXR(视黄酸 X 受体)形成异二聚体,以执行其生理作用。遗传性维生素 D 抵抗性佝偻病(HVDRR)是一种罕见的遗传性疾病,由于对 1α,25(OH)D3 的普遍抵抗而发生。HVDRR 是由于 VDR 基因的多态性变异导致肠道钙吸收缺陷和新形成的骨骼矿化。我们使用 VDR 的点突变和缺失 SNP 研究了几种 HVDRR 相关的 SNP 变体的亚细胞动力学、转录功能、“基因组书签”、与 RXR 的异二聚体相互作用以及受体稳定性。我们之前报道过,VDR 是一种“有丝分裂书签因子”,它与有丝分裂染色质持续相关,以继承“转录记忆”,然而其机制细节尚不清楚。我们记录到,VDR 的“基因组书签”特性受到患者中发现的天然存在的 HVDRR 相关点突变和缺失变体的严重损害。此外,发现这些 HVDRR 相关的 VDR SNP 变体在转录功能、核易位、蛋白质稳定性以及与异二聚体伴侣 RXR 的分子间相互作用方面受到损害。有趣的是,这些疾病相关的功能缺陷大多数未能被 RXR 挽救。我们的研究结果表明,HVDRR 相关的 SNP 变异会影响受体的正常功能,这一认识可能有助于通过精确设计的小分子调节剂来管理疾病。
