Isolation, characterization, and distribution of two cDNAs encoding for growth hormone receptor in rainbow trout (Oncorhynchus mykiss)

Growth hormone (GH) plays important roles in a vast array of physiological processes, including growth, metabolism, and reproduction. In this study, cDNAs for two unique growth hormone receptor variants were cloned and sequenced from rainbow trout. The two cDNAs, one consisting of 2920 bp and the other of 2820 bp, share 87.2% identity in nucleotide sequence and 85.5% identity in deduced amino acid sequence and presumably arose through gene duplication. The cDNAs encode for putative 593- and 594-amino acid growth hormone receptors (designated GHR1 and GHR2, respectively), each containing a single transmembrane domain and other motifs characteristic of the receptor family. Both GHR1 and GHR2 mRNAs were present in all tissues examined. Trout GHR mRNAs are differentially expressed, both in terms of abundance among tissues and in terms of abundance within selected tissues. GHR1 was more abundant than GHR2 in the brain, whereas GHR2 was more abundant than GHR1 in pancreas and spleen. These findings expand our understanding of the evolution of the GH receptor family and suggest that independent mechanisms serve to regulate the tissue-specific expression of GHR mRNAs.     

尼罗罗非鱼生长激素及其受体的cDNA克隆与mRNA表达的雌雄差异

尼罗罗非鱼(Oreochromis niloticus)雌雄鱼生长差异明显,为了探讨其原因,本文采用RT-PCR方法克隆了尼罗罗非鱼生长激素(Growthhormone,GH)及其受体(Growth hormone receptor,GHR)的cDNA序列,并应用半定量RT-PCR方法比较了雌、雄尼罗罗非鱼垂体GHmRNA、肝脏GHRmRNA、肌肉GHRmRNA的表达差异。序列分析表明:GH开放阅读框为615bp,共编码204个氨基酸;GHR开放阅读框为1908bp,共编码635个氨基酸。以RT-PCR方法研究了GH、GHR在各组织的分布情况,结果表明:GH仅在垂体中检测到有表达,而GHR在所检测的18种组织中均有表达,其中以肝脏、肌肉、性腺、下丘脑、胸腺表达量较高。以半定量RT-PCR方法进一步比较了雌、雄尼罗罗非鱼垂体GHmRNA、肝脏GHRmRNA、肌肉GHRmRNA的表达量,结果表明:雄鱼垂体GHmRNA和肝脏GHRmRNA的表达量均显著高于雌鱼,肌肉GHRmRNA的表达量则无显著差异,推测垂体GHmRNA和肝脏GHRmRNA表达的雌雄差异是尼罗罗非鱼雌雄生长差异的主要原因之一。     

大熊猫生长激素受体(GHR) cDNA 的克隆与序列分析

根据已报道的若干物种GHR 基因cDNA 序列设计引物, 利用RT- PCR 技术首次从大熊猫肝脏组织总RNA中扩增出GHR 基因编码区全长cDNA 序列, 克隆于pGEM®-T 载体后进行测序和序列分析。结果表明,大熊猫GHR 的ORF为1 917 bp , 编码638 个氨基酸的前体蛋白, 由18 个氨基酸的信号肽和620 个氨基酸的成熟肽组成,与人、狗、猪GHR 结构相似, 大熊猫GHR 成熟肽由246 个氨基酸的胞外区、24 个氨基酸的跨膜区和350 个氨基酸的胞内区组成, 并具GHR 的特征性结构。序列相似性比较显示, 大熊猫GHR 与哺乳类GHR 具有69 %～93 %的高序列相似性, 与爬行类和鸟类的序列相似性也达到60 % , 而与鱼类的序列相似性较低, 仅为30 %左右。与其它哺乳动物GHR 相比, 大熊猫GHR 在氨基酸序列上也存在明显的特异性。     

Involvement of insulin and growth hormone (GH) during follicular development in the bovine ovary

Insulin and growth hormone (GH) play critical roles in the process of follicular development and maturation. However, the involvement of insulin receptor (IR) and GH receptor (GHR) during follicular development is not well understood. The aim of this study was to investigate the expression of IR and GHR mRNAs in the granulosa cells (GCs) and theca tissues (TCs) of the follicle at different developmental stages (preovulatory dominant follicles, POFs; estrogen-active dominant follicles, EADs; estrogen-inactive dominant follicles, EIDs; and small follicles, SFs), and second, to examine the effects of follicle-stimulating hormone (FSH) and estradiol (E2) on the expression of IR and GHR genes in cultured bovine GCs. Although the concentration of insulin in follicular fluid (FF) was constant at all developmental stages, the GH concentration in FF was significantly increased in the EAD and POF compared with the EID. IR mRNA in GCs and TCs was significantly increased in the POF compared with other follicles. Regarding GHR expression, significant increases of mRNA expression were observed in GCs of EAD compared to those of SF, EID and POF. GHR mRNA in TCs was significantly decreased in the SF compared with other follicles. In cultured GCs, FSH, but not E2, stimulated the expression of IR and GHR genes. Our results suggest that the increase in the expression of GHR may be a turning point for follicles to enter the ovulatory phase during final follicular development and that the insulin system may support the maturation of preovulatory follicles.     

Growth hormone (GH) treatment acts on the endocrine and autocrine/paracrine GH/IGF-axis and on TNF-α expression in bony fish pituitary and immune organs

There exist indications that the growth hormone (GH)/insulin-like growth factor (IGF) axis may play a role in fish immune regulation, and that interactions occur via tumour necrosis factor (TNF)-α at least in mammals, but no systematic data exist on potential changes in GH, IGF-I, IGF-II, GH receptor (GHR) and TNF-α expression after GH treatment. Thus, we investigated in the Nile tilapia the influence of GH injections by real-time qPCR at different levels of the GH/IGF-axis (brain, pituitary, peripheral organs) with special emphasis on the immune organs head kidney and spleen. Endocrine IGF-I served as positive control for GH treatment efficiency. Basal TNF-α gene expression was detected in all organs investigated with the expression being most pronounced in brain. Two consecutive intraperitoneal injections of bream GH elevated liver IGF-I mRNA and plasma IGF-I concentration. Also liver IGF-II mRNA and TNF-α were increased while the GHR was downregulated. In brain, no change occurred in the expression levels of all genes investigated. GH gene expression was exclusively detected in the pituitary where the GH injections elevated both GH and IGF-I gene expression. In the head kidney, GH upregulated IGF-I mRNA to an even higher extent than liver IGF-I while IGF-II and GHR gene expressions were not affected. Also in the spleen, no change occurred in GHR mRNA, however, IGF-I and IGF-II mRNAs were increased. In correlation, in situ hybridisation showed a markedly higher amount of IGF-I mRNA in head kidney and spleen after GH injection. In both immune tissues, TNF-α gene expression showed a trend to decrease after GH treatment. The stimulation of IGF-I and also partially of IGF-II expression in the fish immune organs by GH indicates a local role of the IGFs in immune organ regulation while the differential changes in TNF-α support the in mammals postulated interactions with the GH/IGF-axis which demand for further investigations.     

The effect of GH overexpression on GHR and IGF-I gene regulation in different genotypes of GH-transgenic zebrafish

Most biological actions of growth hormone (GH) are mediated by the insulin-like growth factor I (IGF-I) that is produced after the interaction of the hormone with a specific cell surface receptor, the GH receptor (GHR). Even though the GH excess on fish metabolism is poorly known, several species have been genetically engineered for this hormone in order to improve growth for aquaculture. In some GH-transgenic fish growth has been dramatically increased, while in others high levels of transgene expression have shown inhibition of the growth response. In this study, we used for the first time different genotypes (hemizygous and homozygous) of a GH-transgenic zebrafish (Danio rerio) lineage as a model for studying the GH resistance induced by different GH transgene expression levels. The results obtained here demonstrated that homozygous fish did not grow as expected and have a lower condition factor, which implies a catabolic state. These findings are explained by a decreased IGF-I and GHR gene expression as a consequence of GH resistance. Together, our results demonstrated that homozygous GH-transgenic fish showed similar characteristics to the starvation-induced fish and could be an interesting model for studying the regulation of the GH/GHR/IGF-I axis in fish.     

版纳微型猪近交系 GHR 基因克隆及生物信息学分析简

目的 获得版纳微型猪近交系（BMI）生长激素受体基因（GHR）序列,通过生物信息学分析预测GHR功能并进行GHR mRNA多组织表达谱分析.方法 以版纳微型猪近交系的肝脏组织为材料提取RNA,RT-PCR方法扩增GHR基因编码区序列,将序列连接至pMD18-T载体进行克隆、测序和生物信息学分析;半定量PCR检测GHR mRNA在BMI不同组织中表达量的差异.结果克隆出了BMI GHR 编码区序列,提交GenBank获得登录号KC999114.该基因CDS长1917 bp,编码638个氨基酸.生物信息学分析表明,与长白猪的GHR序列相比BMI存在4处氨基酸替换,分别为p.E381D、p.A409S、p.L556V和p.A580G,均发生在胞内域.GHR基因多组织表达谱分析显示：GHR mRNA几乎在各组织中均有表达,在肌肉中表达量最高,在小肠、心、肝、神经纤维、脾、卵巢中表达量较高,在肺、胃、大脑、胰和肾中的表达量较低.结论 成功克隆了版纳微型猪近交系GHR全长编码区序列,进行了生物信息学功能分析和组织表达谱分析,为进一步阐明版纳微型猪近交系生长矮小机理奠定了基础.     

Characterization of a novel growth hormone receptor-encoding cDNA in rainbow trout and regulation of its expression by nutritional state

To clarify the divergence of the growth hormone receptor (GHR) family, we characterized a novel GHR from a teleost fish (rainbow trout). A 2357-nt cDNA was isolated and found to contain a single initiation site 71 nt from the most 5′ end, an open reading frame of 1971 nt encoding a 657-amino acid protein, and a single polyadenylation site 229 nt from the poly-A tail. Based on structural analysis, the protein was identified as a type 1 GHR (GHR1). The new GHR1 shares 42% and 43% amino acid identity, respectively, with GHR2a and GHR2b, the two type 2 GHRs isolated from trout previously. GHR1 mRNA was found in a wide array of tissues with the highest expression in the liver, red muscle, and white muscle. Fasting animals for 4 weeks reduced steady state levels of GHR1 in the liver, adipose, and red muscle. These findings help clarify the divergence and nomenclature of GHRs and provide insight into the function of duplicated GHR types.     

Effects of starter feeding and early weaning on GHR mRNA expression in liver and rumen of lambs from birth to 84 days of age

The growth hormone receptor (GHR) is associated with animal growth and development. To investigate such effects on GHR gene expression, a total of 102 Hu lambs were randomly allocated to one of three groups (Group 1: starter diet from 7 d of age, weaning at 56 d of age; Group 2: starter diet from 42 d of age, weaning at 56 d of age; Group 3: starter diet from 7 d of age; weaning at 28 d of age). Six lambs from each group were sacrificed every 14 d to investigate the effects of starter feeding and weaning age on GHR mRNA expression in the liver and rumen. The results revealed that GHR mRNA expression was significantly higher in the liver and rumen (p < 0.05) than in other tissues. Early starter feeding up-regulated hepatic GHR mRNA expression on days 14, 28, 42 and 56 and ruminal GHR mRNA expression on days 28, 42, 70, and 84 (p < 0.05). Early weaning up-regulated hepatic GHR mRNA expression on days 56, 70 and 84 and ruminal GHR mRNA expression on days 42, 56, 70 and 84 (p < 0.05). Dietary and weaning regimes and age affected the hepatic and ruminal GHR mRNA expression.     

Chromosome mapping of the growth hormone receptor gene in man and mouse

Pituitary growth hormone (GH) is essential for normal growth and development in animals and GH deficiency leads to dwarfism. This hormone acts via specific high-affinity cell surface receptors found in liver and other tissues. The recent cloning and sequencing of cDNAs encoding human and rabbit GH receptors (GHR) has demonstrated that this receptor is unrelated to any previously described cell membrane receptor or growth factor receptor. We have used the cloned human GHR cDNA to map the GHR locus to the proximal short arm of human chromosome 5, region p13.1----p12, and to mouse chromosome 15 by Southern blot analysis and in situ hybridization. While human chromosome 5 carries several genes for hormone and growth factor receptors, GHR is the only growth-related gene so far mapped to the short arm. Inasmuch as GHR is the first gene with apparently homologous loci on human chromosome 5 and mouse chromosome 15, it identifies a new homologous conserved region. In humans, deficiency of GH receptor activity probably causes Laron-type dwarfism, an autosomal recessive disorder prevalent in Oriental Jews. In mice, the autosomal recessive mutation miniature (mn) is characterized by severe growth failure and early death and has been mapped to chromosome 15. Our assignment of Ghr to mouse chromosome 15 suggests this as a candidate gene for the mn mutation.     

Effect of recombinant growth hormone on expression of growth hormone receptor, insulin-like growth factor mRNA and serum level of leptin in growing pigs

Growth hormone (GH) plays an important role in regulation of animal growth, metabolism and lactation[1]. Numerous studies have shown that exogenous somatotropin (ST) can increase average daily weight gain, improve feed efficiency, stimulate protein deposition and muscle growth and decrease lipid accretion rate[1]. The original somatomedin hypothesis suggested that the effect of GH on postnatal growth was mediated by insulin-like growth hormone factor 1 (IGF-I) which was thought to be deriv…