"Single nucleotide polymorphisms of the OPG/RANKL system genes in primary hyperparathyroidism and their relationship with bone mineral density"

<p>Abstract</p> <p>Background</p> <p>Primary hyperparathyroidism (PHPT) affects mainly cortical bone. It is thought that parathyroid hormone (PTH) indirectly regulates the activity of osteoclasts by means of the osteoprotegerin/ligand of the receptor activator of nuclear factor-κβ (OPG/RANKL) system. Several studies have confirmed that <it>OPG </it>(osteoprotegerin) and <it>RANKL </it>(ligand of the receptor activator of nuclear factor-κβ) loci are determinants of bone mineral density (BMD) in the general population. The aim of this study is to analyze the relationship between fractures and BMD and the rs3102735 (163 A/G), rs3134070 (245 T/G) and rs2073618 (1181 G/C) SNPs of the <it>OPG </it>and the rs2277438 SNP of the <it>RANKL</it>, in patients with sporadic PHPT.</p> <p>Methods</p> <p>We enrolled 298 Caucasian patients with PHPT and 328 healthy volunteers in a cross-sectional study. We analyzed anthropometric data, history of fractures or renal lithiasis, biochemical determinants including markers for bone remodelling, BMD measurements in the lumbar spine, total hip, femoral neck and distal radius, and genotyping for the SNPs to be studied.</p> <p>Results</p> <p>Regarding the age of diagnosis, BMI, menopause status, frequency of fractures or renal lithiasis, we found no differences between genotypes in any of the SNPs studied in the PHPT group. Significant lower BMD in the distal radius with similar PTH levels was found in the minor allele homozygotes (GG) compared to heterozygotes and major allele homozygotes in both <it>OPG </it>rs3102735 (163 A/G) and <it>OPG </it>rs3134070 (245 T/G) SNPs in those with PHPT compared to control subjects. We found no differences between genotypes of the <it>OPG </it>rs2073618 (1181 G/C) SNP with regard to BMD in the PHPT subjects. In the evaluation of rs2277438 SNP of the <it>RANKL </it>in PHPT patients, we found a non significant trend towards lower BMD in the 1/3 distal radius and at total hip in the minor allele homocygotes (GG) genotype group versus heterocygotes and major allele homocygotes (AA).</p> <p>Conclusions</p> <p>Our study provides the first evaluation of the relationship between SNPs of the <it>OPG/RANK </it>system and sporadic PHPT. Subjects with PHPT and minor homocygote genotype (GG) for the <it>OPG </it>rs3102735 (163 A/G) and <it>OPG </it>rs3134070 (245 T/G) SNPs have lower BMD in the distal radius, and this association does not appear to be mediated by differences in PTH serum levels.</p

Dose-dependent effects of vitamin D on transdifferentiation of skeletal muscle cells to adipose cells

Fat infiltration within muscle is one of a number of features of vitamin D deficiency, which leads to a decline in muscle functionality. The origin of this fat is unclear, but one possibility is that it forms from myogenic precursor cells present in the muscle, which transdifferentiate into mature adipocytes. The current study examined the effect of the active form of vitamin D3, 1,25-dihydroxyvitamin D3 (1,25(OH)2D3), on the capacity of the C2C12 muscle cell line to differentiate towards the myogenic and adipogenic lineages. Cells were cultured in myogenic or adipogenic differentiation media containing increasing concentrations (0, 10−13, 10−11, 10−9, 10−7 or 10−5 M) of 1,25(OH)2D3 for up to 6 days and markers of muscle and fat development measured. Mature myofibres were formed in both adipogenic and myogenic media, but fat droplets were only observed in adipogenic media. Relative to controls, low physiological concentrations (10−13 and 10−11 M) of 1,25(OH)2D3 increased fat droplet accumulation, whereas high physiological (10−9 M) and supraphysiological concentrations (≥10−7 M) inhibited fat accumulation. This increased accumulation of fat with low physiological concentrations (10−13 and 10−11 M) was associated with a sequential up-regulation of PPARγ2 (PPARG) and FABP4 mRNA, indicating formation of adipocytes, whereas higher concentrations (≥10−9 M) reduced all these effects, and the highest concentration (10−5 M) appeared to have toxic effects. This is the first study to demonstrate dose-dependent effects of 1,25(OH)2D3 on the transdifferentiation of muscle cells into adipose cells. Low physiological concentrations (possibly mimicking a deficient state) induced adipogenesis, whereas higher (physiological and supraphysiological) concentrations attenuated this effect