ESR1 polymorphism (rs2234693) influences femoral bone mass in patients with Turner syndrome

The estrogen receptor-alpha (ER-alpha) IVS1-401 polymorphism identifies a group of women (approximately 20%) who have augmented effects of hormone replacement therapy (HRT) on levels of HDL cholesterol. This study sought to determine if this augmentation extends to HRT regulation of E-selectin and C-reactive protein (CRP) and to explore possible mechanisms by which this polymorphism might influence estrogen action. Serum levels of soluble E-selectin and CRP were measured at baseline and 1 year in 264 postmenopausal women randomized to treatment with oral conjugated equine estrogen (0.625 mg/d), estrogen plus progestin (medroxyprogesterone acetate 2.5 mg/d), or placebo. Women with the ER-alpha IVS1-401 C/C genotype receiving HRT had nearly a 2-fold greater reduction in E-selectin compared with C/T or T/T women (P for interaction=0.02). In contrast, there was no augmentation of the HRT-associated increase in CRP among the C/C women compared with C/T or T/T women (P for interaction=0.54). Of luciferase reporter constructs containing sequences spanning the IVS1-401 T/C polymorphism, expression of the construct containing the C allele was enhanced >10-fold, with cotransfection of a constitutively expressed B-myb vector. In contrast, B-myb resulted in only a 2.5-fold increase in expression of the T allele construct. Women with the ER-alpha IVS1-401 C/C genotype have greater reductions in E-selectin but no further increases in CRP with HRT. The C allele produces a functional binding site for the transcription factor B-myb. The impact of this polymorphism on ER-alpha transcription and other estrogen-sensitive intermediate and clinical end points has not yet been established.

Peak bone mass is an important risk factor for the development of osteoporosis in later life. Previous work has suggested that genetic, intrauterine, and environmental factors all contribute to the regulation of bone mass, but the ways in which they interact with each other to do so remain poorly understood. In this study, we investigated the relationship between peak bone mass and polymorphisms of the vitamin D receptor (VDR), estrogen receptor (ER) a, and collagen type Ialpha1 (COLIA1) genes in relation to other factors such as birth weight, lifestyle diet, and exercise in a population-based cohort of 216 women and 244 men in their early 20s. Stepwise multiple regression analysis showed that body weight was the strongest predictor of bone mineral density (BMD) in women, accounting for 16.4% of the variance in spine BMD and 8.4% of the variance in femoral neck BMD. Other significant predictors were VDR genotype (3.8%) and carbohydrate intake (1.6%) at the spine and vitamin D intake (3.4%) and ER genotype (3.4%) at the femoral neck. Physical activity was the strongest predictor of BMD in men, accounting for 6.7% of the variance at the spine and 5.1% at the hip. Other significant predictors were body weight (5%) and ER PvuII genotype (2.8%) at the spine and weight (3.4%) and alcohol intake (2%) at the femoral neck. Birth weight was not a significant predictor of BMD at either site but COLIA1 genotype significantly predicted birth weight in women, accounting for 4.3% of the variance. We conclude that peak bone mass is regulated by an overlapping but distinct set of environmental and genetic influences that differ in men and women. However, much of the variance in BMD was unexplained by the variables studied here, which suggests that either most of the genes that regulate BMD remain to be discovered or major environmental influences on BMD exist that have not yet been identified.

A protein polymorphism of the GH receptor (GHR) based on the genomic deletion of exon 3 (d3-GHR) has recently been linked to the magnitude of growth response to high-dose recombinant human GH (rhGH) therapy of short children without GH deficiency. This study tests the novel association in two distinct groups of rhGH-treated patients, short girls with Turner syndrome and short children born small for gestational age (SGA). The retrospective study included all children who were treated with rhGH during the last 18 yr at our hospital. Patients with Turner syndrome were defined by the specific karyotype (n = 53), short children born SGA were determined by birth length and/or weight less than -2.0 sd score and a height at start of rhGH therapy less than -2.0 sd score (n = 60). Exclusion criteria were puberty, an age less than 3.5 or more than 14 yr, and GH deficiency. Growth prediction for the first year of therapy was calculated on the basis of rhGH dose, age, weight, height, and gender-adjusted midparental height according to the prediction models by Ranke et al. The GHR-exon 3 locus was genotyped using a PCR multiplex assay. GH, IGF-I, and IGF binding protein 3 (IGFBP-3) were measured by RIA. For growth promotion, a mean rhGH dose of 38 mug/kg.d (sd, +/-8) was administered in Turner syndrome patients and 56 mug/kg.d (sd, +/-11) in short children born SGA. No significant difference in height, spontaneous height velocity, IGF-I, and IGFBP-3 levels was found at the start of rhGH therapy in the three GHR genotype groups studied. At the first year of treatment, girls with Turner syndrome carrying one or two d3-GHR alleles showed a significantly higher increment in height velocity (P = 0.019) and exceeded their growth prediction significantly (P = 0.007), whereas their increments of IGF-I and IGFBP-3, weight, and height were not significantly different. Carriers of d3-GHR in the group of short children born SGA grew significantly faster than predicted (P = 0.023). However, in comparison to the carriers of full-length GHR, gain of height velocity was not significantly higher (P = 0.067). The mean gain of height associated with d3-GHR accounted for approximately 0.75 cm in SGA and 1.5 cm in Turner syndrome during the first year of rhGH therapy. Our data support the theory that there is increased responsiveness to high-dose rhGH in association with the d3-GHR genotype. The magnitude of this effect may depend on the primary origin of the short stature.