Strawbridge R J, Kärvestedt L, Li C, Efendic S, Ostenson C G, Gu H F, Brismar K
Department of Oncology Pathology, Cancer Centrum Karolinska, Karolinska Institutet, Solna, 171 76 Stockholm, Sweden.
Growth Horm IGF Res. 2007 Oct;17(5):392-8. doi: 10.1016/j.ghir.2007.04.005. Epub 2007 May 29.
Growth hormone (GH) signaling via the growth hormone receptor (GHR) forms a major part of the GH-IGF-I axis, which is crucial for controlling metabolism and anabolism. Two common variants of the GHR differ by the presence (full length or GHR(fl)) or absence of exon 3 (exon 3 deleted or GHR(d3)), the function of which is unknown. However, differential response to GH treatment has been observed with carriers of the GHR(d3) variant conferring a greater growth rate. This study investigates these GHR variants in subjects with normal glucose tolerance (NGT) and impaired glucose tolerance (IGT), including Type 2 diabetes mellitus (T2DM). DNA was extracted from blood samples from subjects with NGT (n=158), IGT (n=116) and T2DM (n=194). The T2DM subjects in set 1 (n= 39) were newly diagnosed, whilst those in set 2 (n=155) had a mean duration of 7 years. Set 1 also included NGT and IGT subjects. Genotyping by standard PCR and gel electrophoresis were carried out. A significant difference was observed between T2DM and NGT (p<0.0001) with a significantly lower frequency of GHR(d3) in T2DM (3.6% compared to 17% in NGT). Both sets of T2DM subjects with at least one GHR(d3) allele had significantly higher BMI. In the larger subset of T2DM, GHR(d3) was associated with higher CRP levels as well as age adjusted IGF-I, with a trend of higher C-peptide secretion and impaired lipid levels, indicating a phenotype with metabolic disorder when compared to the GHR(fl/fl) T2DM subjects. In conclusion, homozygosity for the GHR(d3) allele appears to be preventive of T2DM. However, when other factors cause overt T2DM, the GHR(d3) allele confers a phenotype indicative of metabolic disorder. This study supports the hypothesis that the two GHR alleles by their inclusion or exclusion of exon 3 are functionally different.
生长激素(GH)通过生长激素受体(GHR)发出信号,构成了GH-IGF-I轴的主要部分,这对于控制新陈代谢和合成代谢至关重要。GHR的两种常见变体的区别在于是否存在外显子3(存在外显子3即全长或GHR(fl),不存在外显子3即外显子3缺失或GHR(d3)),其功能尚不清楚。然而,已观察到对GH治疗的不同反应,携带GHR(d3)变体的个体生长速率更高。本研究调查了糖耐量正常(NGT)和糖耐量受损(IGT)(包括2型糖尿病(T2DM))的受试者中的这些GHR变体。从NGT受试者(n = 158)、IGT受试者(n = 116)和T2DM受试者(n = 194)的血液样本中提取DNA。第1组的T2DM受试者(n = 39)为新诊断患者,而第2组的受试者(n = 155)平均病程为7年。第1组还包括NGT和IGT受试者。通过标准PCR和凝胶电泳进行基因分型。观察到T2DM和NGT之间存在显著差异(p < 0.0001),T2DM中GHR(d3)的频率显著更低(3.6%,而NGT中为17%)。两组至少携带一个GHR(d3)等位基因的T2DM受试者的BMI均显著更高。在更大的T2DM亚组中,GHR(d3)与更高的CRP水平以及年龄校正后的IGF-I相关,同时有C肽分泌增加和脂质水平受损的趋势,这表明与GHR(fl/fl)的T2DM受试者相比,具有代谢紊乱的表型。总之,GHR(d3)等位基因的纯合性似乎对T2DM有预防作用。然而,当其他因素导致明显的T2DM时,GHR(d3)等位基因赋予一种表明代谢紊乱的表型。本研究支持以下假设:GHR的两个等位基因通过包含或排除外显子3在功能上有所不同。
