Growth hormone regulates growth hormone receptor gene transcription in primary human thyroid cells.

In this study the regulation of GH-receptor gene (GHR/GHBP) transcription by different concentrations of GH (0, 12.5, 25, 50, 150, 500 ng/ml) with and without variable TSH concentrations (0.5, 2, 20 mU/l) in primary human thyroid cells cultured in serum-free hormonally-defined medium was studied. The incubation time was 6 h and GHR/GHBP mRNA expression was quantitatively assessed by using PCR amplification at hourly intervals. Correlating with the GH-concentrations added a constant and significant increase of GHR/GHBP gene transcription was found. After the addition of 12.5 ng/ml GH, GHR/GHBP mRNA concentration remained constant over the incubation period of 6 h but in comparison with the experiments where no GH was added there was a significant change of GHR/GHBP mRNA expression. Following the addition of 25 ng/ml GH a slight but further increase of GHR/GHBP transcription products was seen which increased even more in the experiments where higher GH concentrations were used. These data focusing on GHR/GHBP gene transcription derived from cDNA synthesis and quantitative PCR amplification were confirmed by run-on experiments. Furthermore, cycloheximide did not affect these changes supporting the notion that GH stimulates GHR/GHBP gene transcription directly. In a second set of experiments, in combination with variable TSH levels, identical GH concentrations were used and no difference in either GHR/GHBP mRNA levels or in transcription rate (run-on experiments) could be found. In conclusion, we report data showing that primary thyroid cells express functional GH-receptors in which GH has a direct and dose dependent effect on the GHR/GHBP gene transcription. Furthermore, TSH does not a have a major impact on GHR/GHBP gene regulation.

Regulation of human GH receptor gene transcription by 20 and 22 kDa GH in a human hepatoma cell line.

The human GH gene is 1.7 kilobase pairs (kb) in length and is composed of five exons and four introns. This gene is expressed in the pituitary gland and encodes a 22 kDa protein. In addition to this predominant (75%) form, 5-10% of pituitary GH is present as a 20 kDa protein that has an amino acid (aa) sequence identical to the 22 kDa form except for a 15 aa internal deletion of residues 32-46 as a result of an alternative splicing event. Because it has been reported that non-22-kDa GH isoforms might be partly responsible for short stature and growth retardation in children, the aim of this study was to compare the impact of both 22 kDa and 20 kDa GH on GH receptor gene (GH receptor/GH binding protein (GHR/GHBP)) expression. Various concentrations of 20 kDa and 22 kDa GH (0, 2, 5, 12.5, 25, 50 and 150 ng/ml) were added to human hepatoma (HuH7) cells cultured in serum-free hormonally defined medium for 0, 1 and 2 h. Thereafter GHR/GHBP mRNA expression was measured by quantitative PCR. Addition of either 20 kDa or 22 kDa GH, at low or normal physiological concentrations (0, 2, 5, 12.5, 25 or 50 ng/ml) induced a dose-dependent increase in GHR/GHBP expression. However, a supraphysiological concentration of 20 kDa GH (150 ng/ml) resulted in a significantly lower (P<0.05) downregulation of GHR/GHBP gene transcription compared with the downregulation achieved by this concentration of 22 kDa GH. This difference might be explained by a decreased ability to form a 1 : 1 complex with GHR and/or GHBP, which normally occurs at high concentrations of GH. Nuclear run-on experiments and GHBP determinations confirmed the changes in GHR/GHBP mRNA levels. In conclusion, we report that both 20 kDa and 22 kDa GH, in low and normal physiological concentrations, have the same effect on regulation of GHR/GHBP gene transcription in a human hepatoma cell line. At a supraphysiological concentration of 150 ng/ml, however, 20 kDa GH has a less self-inhibitory effect than the 22 kDa form.

"Hot spot" in the PROP1 gene responsible for combined pituitary hormone deficiency.

As pituitary function depends on the integrity of the hypothalamic-pituitary axis, any defect in the development and organogenesis of this gland may account for a form of combined pituitary hormone deficiency (CPHD). Although pit-1 was 1 of the first factors identified as a cause of CPHD in mice, many other homeodomain and transcription factors have been characterized as being involved in different developmental stages of pituitary gland development, such as prophet of pit-1 (prop-1), P-Lim, ETS-1, and Brn 4. The aims of the present study were first to screen families and patients suffering from different forms of CPHD for PROP1 gene alterations, and second to define possible hot spots and the frequency of the different gene alterations found. Of 73 subjects (36 families) analyzed, we found 35 patients, belonging to 18 unrelated families, with CPHD caused by a PROP1 gene defect. The PROP1 gene alterations included 3 missense mutations, 2 frameshift mutations, and 1 splice site mutation. The 2 reported frameshift mutations could be caused by any 2-bp GA or AG deletion at either the 148-GGA-GGG-153 or 295-CGA-GAG-AGT-303 position. As any combination of a GA or AG deletion yields the same sequencing data, the frameshift mutations were called 149delGA and 296delGA, respectively. All but 1 mutation were located in the PROP1 gene encoding the homeodomain. Importantly, 3 tandem repeats of the dinucleotides GA at location 296-302 in the PROP1 gene represent a hot spot for CPHD. In conclusion, the PROP1 gene seems to be a major candidate gene for CPHD; however, further studies are needed to evaluate other genetic defects involved in pituitary development.

Regulation of human growth hormone receptor gene transcription by triiodothyronine (T3).

In this study the hypothesis that triiodothyronine (T3) and growth hormone (GH) may have some direct or indirect effect on the regulation of GH-receptor/GH-binding protein (GHR/GHBP) gene transcription was tested. Different concentrations of T3 (0, 0.5, 2, 10 nmol/l) and GH (0, 10, 150 ng/ml) were added to human hepatoma (HuH7) cells cultured in serum-free hormonally-defined medium for 0, 1 and 2 h. Thereafter GHR/GHBP mRNA expression was quantitatively assessed by using PCR amplification. GH at a concentration of 10 ng/ml resulted in a significant increase of GHR/GHBP gene expression whereas a supraphysiological concentration of GH (150 ng/ml) caused a significant decrease of GHR/GHBP mRNA levels. The simultaneous addition of 0.5 nmol/l T3 to the variable concentrations of GH did not modify GHR/GHBP mRNA levels whereas the addition of 2 nmol/l up-regulated GHR/GHBP gene expression already after 1 h, an increase which was even more marked when 10 nmol/l of T3 was added. Interestingly, there was a positive correlation between the increase of GHR/GHBP mRNA levels and the T3 concentration used (r: 0.8). In addition, nuclear run-on experiments and GHBP determinations were performed which confirmed the changes in GHR/GHBP mRNA levels. Cycloheximide (10 microg/ml) did not alter transcription rate following GH addition but blocked GHR/GHBP gene transcription in T3 treated cells indicating that up-regulation of GHR/GHBP gene transcription caused by T3 requires new protein synthesis and is, therefore, dependent on indirect mechanisms. In conclusion, we present data showing that T3 on its own has a stimulatory effect on GHR/GHBP gene transcription which is indirect and additive to the GH-induced changes.

Phenotypic variability in familial combined pituitary hormone deficiency caused by a PROP1 gene mutation resulting in the substitution of Arg-->Cys at codon 120 (R120C).

As pituitary function depends on the integrity of the hypothalamic-pituitary axis, any defect in the development and organogenesis of this gland may account for a form of combined pituitary hormone deficiency (CPHD). A mutation in a novel, tissue-specific, paired-like homeodomain transcription factor, termed Prophet of Pit-1 (PROP1), has been identified as causing the Ames dwarf (df) mouse phenotype, and thereafter, different PROP1 gene alterations have been found in humans with CPHD. We report on the follow-up of two consanguineous families (n = 12), with five subjects affected with CPHD (three males and two females) caused by the same nucleotide C to T transition, resulting in the substitution of Arg-->Cys in PROP1 at codon 120. Importantly, there is a variability of phenotype, even among patients with the same mutation. The age at diagnosis was dependent on the severity of symptoms, ranging from 9 months to 8 yr. Although in one patient TSH deficiency was the first symptom of the disorder, all patients became symptomatic by exhibiting severe growth retardation and failure to thrive, which was mainly caused by GH deficiency (n = 4). The secretion of the pituitary-derived hormones (GH, PRL, TSH, LH, and FSH) declined gradually with age, following a different pattern in each individual; therefore, the deficiencies developed over a variable period of time. All of the subjects entered puberty spontaneously, and the two females also experienced menarche and periods before a replacement therapy was necessary.

Prevalence of human GH-1 gene alterations in patients with isolated growth hormone deficiency.

Human GH is encoded by the GH-1 gene which belongs to the GH gene cluster encompassing a distance of about 65 kb on the long arm of chromosome 17. Familial isolated growth hormone deficiency (IGHD) is associated with at least four Mendelian disorders. These include two forms that have autosomal recessive inheritance (IGHD types IA and IB) as well as autosomal dominant (IGHD type II) and X-linked (IGHD III) forms. The aim of our study was to evaluate the prevalence of all GH-1 gene alterations by sequencing the whole GH-1 gene after PCR amplification among 151 affected subjects from 83 families with severe IGHD (height: <-4.5 SD score). A high frequency of GH-1 gene alterations was found in families with IGHD type IA (8/12, 66.7%), whereas only a low frequency of GH-1 gene defects was present in all the other GH-deficient families (7/71, 9.9%). The absolute frequency of GH-1 gene deletions was 8.7% (6/69), 11.8% (4/34), and 18.7% (9/48) in Northern Europeans, Mediterraneans, and Asians, respectively, giving an overall frequency of 12.5% (19/151). The sizes of the deletions were heterogeneous with the most frequent (78%) being 6.7 kb. In addition, 6% (9/151) of the patients presented GH-1 gene mutations such as frameshift, stop codon and splicing error. Furthermore, total GH-1 gene abnormalities varied among different populations from 11.6% in Northern Europe, 14.7% in Mediterranean countries and 31.2% in Asia. Most striking, however, was the low frequency rate of 1.7% (2/119) of GH-1 gene mutations responsible for the most common phenotype of IGHD, namely type IB, among the subjects characterized by the production of deficient but detectable amounts of GH after provocative stimuli. This finding underlines the necessity to focus rather on the promoter region of the GH-1 gene (cis-acting elements and trans-acting factors), and on other candidate genes specific for the GH axis than the GH-1 gene itself to define genetically the IGHD type IB phenotype in more detail.

Allelic variations in the human growth hormone-1 gene promoter of growth hormone-deficient patients and normal controls.

OBJECTIVE: Isolated growth hormone deficiency (IGHD) type IB is suggested to be more probably due to alterations in the genes directly involved in the hypothalamo-pituitary axis and/or in the specific transcriptional regulation (cis-trans coupling) of the hGH-1 gene than to alterations in the gene itself. In this study we analyzed the hGH-1 gene promoter region for structural alterations and allelic variations. METHODS: The hGH-1 gene promoter region was analyzed by PCR, cycle sequencing and direct-blotting electrophoresis in a total of 212 individuals including 113 patients with IGHD type IB, 21 unaffected family members and 78 normal controls. RESULTS: Twenty-two sequence variation sites were identified. Of these, 14% were located around the region of -1075bp, 77% between -550bp and the translational start site (+1bp) and 9% within the first intron. Only one variation site affected a characterized cis-acting element, namely that of NF-1. Importantly, all the variations found in patients were also observed in non-affected family members as well as in normal unrelated controls. CONCLUSIONS: These findings imply that it is not a single variation within the GH-1 gene promoter, and therefore in the cis-acting elements, which causes IGHD. However, we can not exclude the possibility that combinations of variations might perturb expression. Furthermore, these data illustrate the normal heterogeneity of the GH-1 gene promoter region, a fact that has to be borne in mind whenever transcriptional studies are performed.

Regulation of human growth hormone receptor gene transcription by human growth hormone binding protein.

The hypothesis that growth hormone binding protein (GHBP) has an effect on its own on the regulation of the GH-receptor/GHBP transcription was tested. Three different forms of human GHBP (recombinant non-glycosylated GHBP, recombinant glycosylated GHBP and GHBP purified and extracted from serum) were added in different concentrations determined by LIFA [0 pmol/l; 50 pmol/l (low level), 200 pmol/l (average level) and 500 pmol/l (high level in circulation)] to a human hepatoma cell line (HuH7 cells) cultured in a serum free hormonally-defined medium. Following the incubation with GHBP for 0, 1 and 2 h, GH-receptor expression was quantitatively assessed by using polymerase chain reaction amplification. Treatment with a GHBP concentration of 50 pmol/l resulted in a significant increase of GH-receptor mRNA molecules given as number of molecules x 10(6)/microg total RNA. In contrast, the concentration of 500 pmol/l presented a significant decrease of GH-receptor mRNA molecules, whereas 200 pmol/l GHBP produced a GH-receptor gene expression which was in between the values of the experiments with 50 and 500 pmol/l of GHBP added. Furthermore, the three different forms of human GHBP used provided similar data and, therefore, did not effect in any variation of GH-receptor expression. In addition, nuclear run-on experiments confirmed the changes in GH-receptor expression; and cycloheximide (10 microg/ml) did not alter the transcription indicating that the up and down regulating effects of GHBP on the GH-receptor/GHBP gene transcription was dependent, at least partly, on pre-existing factors and does not require protein synthesis. In conclusion, we present data showing that GHBP on its own has an effect on GH-receptor gene expression.

Effect of different serum concentrations of growth hormone-binding protein (GHBP) on the regulation of GH receptor/GHBP gene transcription in a human hepatoma cell line.

Although high-affinity growth hormone (GH)-binding protein (GHBP) seems to mirror tissue GH receptor (GH-R) status and effects GH kinetics, the physiological importance and ultimate biological role of GHBP remain largely unknown and obscure. Therefore, the aims of this study were, first, to test the hypothesis that different serum concentrations of GHBP may regulate GH-R/GHBP gene transcription and, second, to define a new nonradioactive polymerase chain reaction (PCR) method to quantify GH-R/GHBP mRNA levels which was to compare with the RNase protection assay. Sera from patients with Laron-type dwarfism (n = 10) and adult obese patients (n = 7) containing distinct GH and GHBP concentrations were added to human hepatoma cells (HuH 7) cultured in a hormonally-adapted medium. GH-R/GHBP gene expression was studied 3 h after the addition of the sera. The results of the regulated GH-R/GHBP mRNA levels imply a direct impact of GHBP on GH-R/GHBP gene transcription under these circumstances. In conclusion, we set up a nonradioactive quantitative PCR method which enables the measurement and quantification of GH-R/GHBP mRNA. The results were identical with the data obtained using RNase protection assay. In addition, these results provide evidence that GHBP may have some effect on the regulation of the GH-R/GHBP transcription and that it is more than simply a shed or secreted product with extracellular destinations and functions. Our personal view, therefore, is that GHBP is rather an active player than an erratic extracellular domain of a receptor.

Isolated growth hormone deficiency: testing the little mouse hypothesis in man and exclusion of mutations within the extracellular domain of the growth hormone-releasing hormone receptor.

The phenotypic characteristics of isolated growth hormone deficiency (IGHD) type IB in humans, such as autosomal recessive inheritance, time of onset of growth retardation, diminished secretion of growth hormone (GH) and IGF-I, proportional reduction in weight and size, and delay in sexual maturation, has much in common with the phenotype of the homozygous little/little (lit/lit) mouse. Sequencing of the GH releasing hormone (GHRH) receptor in lit/lit mice has shown a single nucleotide substitution within the extracellular peptide binding domain at codon 60 that changed aspartic acid to glycine. Therefore, the GHRH receptor is a reasonable candidate gene for causing IGHD in humans. DNA from 65 unrelated healthy Caucasians of normal stature and 65 children with IGHD type IB of whom 12 did not respond to exogenous treatment with GHRH were studied. Restriction endonuclease analysis, linkage studies, and polymerase chain reaction amplification and sequencing of the whole extracellular domain including the first three membrane spanning domains of the GHRH receptor gene were performed. None of the analyses revealed any structural abnormalities in these patients with IGHD. This suggests that a lit/lit mouse equivalent is an unlikely explanation for the majority of children with IGHD. Although gross structural abnormalities in the whole gene have been ruled out in this study, mutations in the carboxyl terminus are still possible, and, therefore, the remaining part of the gene needs to be sequenced.

Regulation of human growth hormone-binding protein production by human growth hormone in a hepatoma cell line.

The mechanism by which growth hormone-binding protein (GH-BP) is generated in humans remains unclear. To address this question, we analysed human GH-receptor/GH-BP gene expression in a human hepatoma cell line (HuH7). Northern hybridisation showed that HuH7 cells contain a single mRNA species hybridising with a probe for the sequences encoding the extracellular domain of the hGH-receptor/GH-BP. These data were confirmed by solution hybridisation methods. Thereafter, the cells were treated with r-hGH at physiological (12.5, 25, 50 ng/ml) and supra-physiological (150, 500 ng/ml) concentrations over the period of 48 h. At intervals, RNase protection assays were performed to determine GH-receptor/GH-BP mRNA levels, nuclear run-on assays were carried out to determine whether changes in mRNA levels represented changes in transcription rate, and a radio-ligand binding assay was performed to measure levels of GH-BP in the medium. We found that the r-hGH-regulated changes in GH-receptor/GH-BP mRNA levels detected with the probe for sequences encoding the extracellular domain of human GH-receptor/GH-BP were identical to those previously detected using a probe for the sequences encoding the transmembrane/intracellular domain of the human GH-receptor. In addition, we found that r-hGH had a rapid effect on the levels of GH-BP in the culture medium, which differed from its effect on the GH-receptor/GH-BP mRNA levels. Furthermore, lowering of temperature resulted in a decrease of GH-BP released into the medium implying that enzymes may be involved in the releasing mechanism. These data support the idea that GH-receptor and GH-BP are encoded by a single mRNA species in humans. In addition, they suggest that GH-BP levels are not an accurate reflection of GH-receptor/GH-BP mRNA levels, but that GH-BP production is subject to r-hGH-dependent post-transcriptional regulation, perhaps at the level of post-translational cleavage of the full-length GH-receptor protein. The notion that GH-BP measurements might represent GH-receptor status at the functional level must therefore be taken with caution.

Isolated growth hormone (GH) deficiency type IA associated with a 45-kilobase gene deletion within the human GH gene cluster.

A Turkish family of seven individuals (two parents and five offspring) is described in which three children presented with isolated GH deficiency type IA, as defined by Illig et al. The gene deletion responsible for the isolated GH deficiency was characterized by Southern blotting and hybridization analysis of genomic DNA using a 32P-labeled hGH cDNA clone as a probe. In the affected patients, a total of approximately 45 kilobases of DNA, encompassing the human (h) GH-1, human chorionic somatomammotropin-L (hCS-L), hCS-A, and hGH-2 genes, were deleted. The end points of the deletion lay within two regions of highly homologous DNA sequence situated 5' to the hGH-1 gene and 5' to the hCS-B gene. The retention of only the hCS-B gene was associated with normal weight and length at birth and normal postpartum lactation in the mother heterozygous for the deletion. The parents, who are consanguineous, both presented with a DNA restriction pattern consistent with heterozygosity for this deletion.

Prevalence of human growth hormone-1 gene deletions among patients with isolated growth hormone deficiency from different populations.

Familial isolated growth hormone deficiency type IA results from homozygosity for either a 6.7-kb or a 7.6-kb hGH-1 gene deletion. Genomic DNA was extracted from circulating lymphocytes of 78 subjects with severe isolated growth hormone deficiency (height less than -4.5 SD score) and studied by polymerase chain amplification and by restriction endonuclease analysis looking for gene deletions within the hGH-gene cluster. The individuals analyzed were broadly grouped into three different populations (North-European, n = 32; Mediterranean, n = 22; and Turkish, n = 24). Ten out of 78 patients studied presented with an hGH-1 gene deletion; eight out of these 10 showed a 6.7-kb gene deletion, the remaining two a 7.6-kb hGH-1 gene deletion. Five of the 10 subjects developed anti-hGH antibodies to hGH replacement followed by a stunted growth response. Family studies of the affected patients were performed, revealing consanguinity in all the families, and the corresponding heterozygosity for the deletion was present in each of the parents. The results of our study revealed a prevalence for an hGH-1 gene deletion in three out of 32 North-European, three out of 22 Mediterranean, and four out of 24 Turkish patients with growth hormone deficiency (height less than 4.5 SD score). These data are important for prenatal diagnosis of at-risk pregnancies and for families at risk for recurrence and underline clearly the fact that the hGH-I gene deletion represents a common cause for growth hormone deficiency associated with severe growth retardation (height less than -4.5 SD score).

Nonenzymatic glucosylation and glucose-dependent cross-linking of protein.

A model system using RNase A has been established for studying the nonenzymatic glucosylation and glucose-dependent cross-linking of protein (Maillard reaction) under physiological conditions in vitro. The rate of glucosylation of RNase was first order in glucose. Glucosylation was accompanied by a comparable decrease in primary amino groups in the protein and lysine recoverable by amino acid analysis. Analysis of glucosylation reaction mixtures by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of mercaptoethanol revealed the time-dependent formation of RNase dimer and trimer. The polymerization reaction was mixed order with respect to glucose concentration, but was approximately first order with respect to protein concentration. When glucosylated protein was separated from glucose, the protein continued to polymerize even in the absence of glucose. Under these conditions, the primary cross-linking reaction occurred by condensation of a glucosylated amino acid on one RNase molecule with a free amino group on another. Lysine efficiently inhibited cross-linking between glucosylated and native RNase in the absence of glucose. An attempt to model the cross-linking reaction was made by studying the incorporation of [3H]lysine and N alpha-formyl-[3H]lysine into glucosylated RNase. Both were incorporated covalently into glucosylated but not native protein. However, free lysine was the major product recovered following NaBH4 reduction and amino acid analysis of the lysine derivative of glycosylated protein. The data are discussed in terms of the mechanism of protein cross-linking by glucose and the relevance of this reaction to the pathophysiology of diabetes.

Cytochemical aspects of Mercenaria mercenaria hemocytes.

The hemocytes of the hard clam M. mercenaria were of three types: an agranulocyte, a small, and a large granulocyte. The agranulocyte, with only a thin periphery of cytoplasm surrounding the nucleus, had no visible cytoplasmic granules in living preparations but did exhibit a few centers of nonspecific esterase activity. This cell type represented 2% of the hemocyte population. The small granulocyte possessed four distinct granule types and comprised 61% of the total cell population. Large granulocytes accounted fro 37% of all hemocytes. While they contained the same four granule types identified in the small granulocyte, only one-third the total number were present. The nucleus of all three hemocyte types appeared morphologically similar. The four types of granules observed were a blunt, dot-like, a refractile and a filamentous granule. Blunt granules were identified as mitochondria, based on their ability to reduce Janus Green B to diethyl safranin, the presence of NADH dehydrogenase activity and boundary staining with Sudan black B. Dot-like granules were identified as lysosomes on the basis of neutral red staining, localization of acid phosphatase and nonspecific esterase activity and staining with Sudan black B. Refractile granules were demonstrated to be membrane-bound, lipid-filled structures that reacted positively with Sudan black B and Oil red O, respectively; these granules act as lipid storage centers. Nuclear similarity of the three cell types suggest that these cells might represent different stages of maturity, rather than three distinct cell lines. This was also indicated by the similar yet graded cytochemical reactions and the varying degree of motility and phagocytic activity demonstrated by hemocyte types.