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The Growth Hormone (GH)-Axis of GH Receptor/Binding Protein Gene-Disrupted and Metallothionein-Human GH-Releasing Hormone Transgenic Mice: Hypothalamic Neuropeptide and Pituitary Receptor Expression in the Absence and Presence of GH Feedback¹

Department of Medicine (X.-d.P., S.P., M.R.G., L.A.F., R.D.K.), University of Illinois at Chicago, Chicago, Illinois; and Edison Biotechnology Institute (K.T.C., J.J.K.), and Department of Biomedical Sciences, College of Osteopathic Medicine (J.J.K.), Ohio University, Athens, Ohio

Address all correspondence and requests for reprints to: Rhonda D. Kineman, Ph.D., Department of Medicine (M/C 640), University of Illinois at Chicago, 1819 West Polk, Chicago, Illinois 60612. E-mail: kineman{at}uic.edu

	Abstract

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Elevation of circulating GH acts to feed back at the level of the hypothalamus to decrease GH-releasing hormone (GHRH) and increase somatostatin (SRIF) production. In the rat, GH-induced changes in GHRH and SRIF expression are associated with changes in pituitary GHRH receptor (GHRH-R), GH secretagogue receptor (GHS-R), and SRIF receptor subtype messenger RNA (mRNA) levels. These observations suggest that GH regulates its own synthesis and release not only by altering expression of key hypothalamic neuropeptides but also by modulating the sensitivity of the pituitary to hypothalamic input, by regulating pituitary receptor synthesis. To further explore this possibility, we examined the relationship between the expression of hypothalamic neuropeptides [GHRH, SRIF, and neuropeptide Y (NPY)] and pituitary receptors [GHRH-R, GHS-R, and SRIF receptor subtypes (sst2 and sst5)] in two mouse strains with alterations in the GH-axis; the GH receptor/binding protein gene-disrupted mouse (GHR/BP-/-) and the metallothionein promoter driven human GHRH (MT-hGHRH) transgenic mouse. In GHR/BP-/- mice, serum insulin-like growth factor I levels are low, and circulating GH is elevated because of the lack of GH negative feedback. Hypothalamic GHRH mRNA levels in GHR/BP-/- mice were 232 ± 20% of GHR/BP+/+ littermates (P < 0.01), whereas SRIF and NPY mRNA levels were reduced to 86 ± 2% and 52 ± 3% of controls, respectively (P < 0.05; ribonuclease protection assay). Pituitary GHRH-R and GHS-R mRNA levels of GHR/BP-/- mice were elevated to 275 ± 55% and 319 ± 68% of GHR/BP+/+ values (P < 0.05, respectively), whereas the sst2 and sst5 mRNA levels did not differ from GHR/BP intact controls as determined by multiplex RT-PCR. Therefore, in the absence of GH negative feedback, both hypothalamic and pituitary expression is altered to favor stimulation of GH synthesis and release. In MT-hGHRH mice, ectopic hGHRH transgene expression elevates circulating GH and insulin-like growth factor I. In this model of GH excess, endogenous (mouse) hypothalamic GHRH mRNA levels were reduced to 69 ± 6% of nontransgenic controls, whereas SRIF mRNA levels were increased to 128 ± 6% (P < 0.01). NPY mRNA levels were not significantly affected by hGHRH transgene expression. Also, MT-hGHRH pituitary GHRH-R and GHS-R mRNA levels did not differ from controls. However, sst2 and sst5 mRNA levels in MT-hGHRH mice were increased to 147 ± 18% and 143 ± 16% of normal values, respectively (P < 0.05). Therefore, in the presence of GH negative feedback, both hypothalamic and pituitary expression is altered to favor suppression of GH synthesis and release.

	Introduction

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IN THE RAT, acquired GH-deficiency, as occurs after hypophysectomy and thyroidectomy, results in the upregulation of hypothalamic GH-releasing hormone (GHRH) and the down-regulation of somatostatin (SRIF) expression (1, 2, 3, 4). Similar changes are observed in the hypothalamus of the spontaneous dwarf rat (SDR), where GH is absent as a consequence of a point mutation in the GH gene (5, 6). Replacement of GH in SDRs was associated with a reciprocal shift in hypothalamic GHRH and SRIF expression, whereas systemic insulin-like growth factor I (IGF-I) replacement had no effect. Taken together, these results demonstrate that circulating GH feeds back at the level of the hypothalamus, to negatively regulate its own synthesis and release.

Further examination of the GH-axis of the SDR has revealed that GH-mediated changes in hypothalamic GHRH and SRIF expression are also associated with changes in the expression patterns of the pituitary receptors known to regulate GH synthesis and release. In the absence of GH, pituitary messenger RNA (mRNA) levels for the GHRH receptor (GHRH- R), the GH secretagogue receptor (GHS-R), and the SRIF receptor subtype, sst2, are increased; whereas mRNA levels for the SRIF receptor subtype, sst5, are suppressed (5, 7, 8). GH replacement restored SDR pituitary receptor expression levels to normal, indicating that GH regulates its own synthesis and release not only by altering the expression of hypothalamic neuropeptides but also by regulating pituitary receptor synthesis.

To determine whether the GH-mediated changes in hypothalamic neuropeptide and pituitary receptor expression observed in the SDR are unique to this model system or represent generalized mechanisms of GH negative feedback regulation, we have examined the hypothalamic-pituitary axis of two genetically engineered mouse strains with altered GH signaling and production: 1) the GH receptor/binding protein gene-disrupted mouse (GHR/BP-/-); and 2) the metallothionein promoter-driven human GHRH (MT-hGHRH) transgenic mouse. The GHR/BP-/- mouse was developed by targeted disruption of exon 4 (the GH binding domain) of the GH receptor gene (9). The lack of GH signaling leads to an increase in circulating GH levels, while IGF-I is reduced and growth is severely retarded. The MT-hGHRH mouse, originally developed by Hammer et al. (10), expresses the hGHRH transgene in most tissues of the body, including the pituitary and hypothalamus (11). Chronic GHRH stimulation leads to increased serum GH and IGF-I levels and a giant phenotype. In the present study, ribonuclease (RNase) protection assays (RPAs) were used to examine the effect of altered GH signaling and production on hypothalamic neuropeptide [GHRH, SRIF, and neuropeptide Y (NPY)] mRNA levels, while multiplex RT-PCR was used to examine pituitary receptor (GHRH-R, GHS-R, sst2, and sst5) expression.

	Materials and Methods

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Animals and RNA
Mice were maintained on standard rodent chow diets and were weighed just before decapitation (12–16 weeks). The GHR/BP-/- mice (129/Ola x BALB/c background) were maintained by breeding GHR+/- mice and genotypes determined by PCR of tail-snip DNA obtained at weaning (12). The MT-hGHRH mouse strain (C57BL/6x SJL background) was propagated from the founder line, 765–2, reported by Hammer et al. (10). The colony was maintained by breeding nontransgenic females with heterozygote males and genotypes determined by PCR of tail-snip DNA, as previously described (13). Pituitaries and hypothalami from male GHR/BP-/-, MT-hGHRH, and their respective normal littermates (n = 5–10/group) were collected and stored at -70 C for subsequent mRNA analysis. Total pituitary and hypothalamic RNA was extracted as previously described (5). All experiments were conducted according to the principles and procedures outlined in the NIH Guide for the Care and Use of Laboratory Animals. All protocols were approved by the University of Illinois at Chicago animal care committee.

GH immunocytochemistry
To assess the proportion of somatotropes in anterior pituitaries from male GHR/BP-/-, MT-hGHRH, and their respective normal littermates, 2–3 anterior pituitaries were pooled and mechanically and enzymatically dissociated into single cells (n = 2 experiments). Monodispersed cells were placed on poly-L-lysine-coated microscope slides, fixed, and immunostained for GH using a monkey antirat GH serum (1:100,000) that exhibits complete cross-reactivity with mouse GH. Details of the pituitary dispersion and immunocytochemistry procedures have been previously reported (14).

RPA of hypothalamic GHRH, SRIF, and NPY mRNA
One microgram of mouse hypothalamic RNA was reverse transcribed using Superscript II RT (Life Technologies, Inc., St. Louis, MO) with an oligo d(T) primer. To generate riboprobes, complementary DNA (cDNA) was amplified by PCR using primers for mouse GHRH, SRIF, NPY, or -actin. The antisense primers were modified to contain a 17-base T7 RNA polymerase recognition sequence (5'-TAATACGACTCACTATA-3'), a 6-base transcription initiation sequence, and 15 or 20 bases of nonspecific (not hybridizable) sequence appended at the 5' end. The nonspecific sequence was added to the primer to allow for the differentiation of protected and unprotected probe after RNase digestion. The amplified PCR products were used as templates for in vitro transcription performed using the MAXIscript kit (Ambion, Inc., Austin, TX) in the presence of [-³²P]CTP. Radiolabeled riboprobes were gel-purified before use. The primer sequences and the expected sizes of full-length riboprobes and protected fragments are summarized in Table 1.

Multiplex RT-PCR of pituitary GHRH-R, GHS-R, sst2, and sst5 mRNA
The relative levels of pituitary GHRH-R, GHS-R, sst2, and sst5 mRNA were measured by multiplex RT-PCR using glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as an internal control. One microgram of total RNA was reverse transcribed using the Superscript Preamplification System for First Strand Synthesis (Life Technologies, Inc.) with random hexamer priming in a 20-µl vol. The resultant cDNA was used in three separate PCR reaction mixtures containing specific primers for either GHRH-R and GAPDHa (reaction no. 1); GHS-R and GAPDHb (reaction no. 2); or sst2, sst5, and GAPDHa (reaction no. 3). Primer sequences used in each PCR reaction (see Table 2) were selected on the basis of: 1) comparable annealing temperatures; 2) transcript specificity (as determined by a GenBank search); 3) exclusion of primers that showed secondary structure or primer/primer interactions; and 4) product size. Primer concentrations were empirically determined to achieve a final signal that was comparable for all PCR products within each reaction and that would provide noncompetitive and specific amplification for each PCR product. Therefore, this technique can only be used to compare the expression level of a single receptor type between experimental groups and not the relative expression levels between the various receptor types. Each PCR reaction was performed in a 50-µl vol containing 1.5 µl RT (reaction nos. 1 and 3) or 2.0 µl RT (reaction no. 2) and 1x PCR buffer, 1.5 mM MgCl₂, 0.2 mM deoxynucleotide triphosphates, 2U Taq Gold polymerase (Perkin-Elmer Corp., Branchburg, NJ), and 5 µCi [-³²P]dCTP (deoxycytidine triphosphate) (specific activity, 800 Ci/mmol). All PCR reactions consisted of a predenaturing step at 95 C for 10 min, 26–29 cycles of 1-min denaturation (95 C), 1-min annealing (62–69 C), and 1-min extension (72 C), followed by a final extension at 72 C for 10 min (see Table 2 for specific reaction details). PCR products from reactions no. 1 and no. 3 were separated on 5% polyacrylamide/8M urea gels while transcripts from reaction no. 2 were separated on 7% polyacrylamide/8M urea gels. Gels were dried on chromatography paper and exposed to a phosphorimage screen. Band intensity was evaluated by image analysis software (Molecular Dynamics, Inc.). There was no significant difference in GAPDH mRNA levels between experimental groups. Therefore, signal intensity for each of the pituitary receptor subtypes was adjusted by that of GAPDH to control for variability in the amount of total RNA used in the RT reaction and the efficiency of conversion of RNA to cDNA.

View larger version (34K): [in this window] [in a new window]   Figure 1. Amplification kinetics of pituitary receptor and GAPDH cDNA by multiplex RT-PCR. One microgram of total pituitary RNA was reverse transcribed using random hexamer priming. cDNA was amplified by PCR in a single sample, in the presence of radiolabeled [-32P]dCTP, using specific primers for mouse GHRH-R and GAPDHa (A); or GHS-R and GAPDHb (B); or sst2, sst5, and GAPDHa (C). Refer to Table 2 for specific primer sequences. The radiolabeled PCR products were separated on 5% (A and C) or 7% (B) polyacrylamide/8M urea gel. Gels were dried on chromatography paper and exposed to a phosphorimage screen. The signal intensities of the PCR products (upper panels of A, B, and C) were measured by phosphorimager and pixel density quantified by image analysis software. All PCR products were of the expected size.

	Results

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The GH-axis of the GHR/BP-/- mouse
GHR/BP-/- mice weighed 45% of their GH-R+/+ littermates, similar to previous reports (9, 15). Pituitaries of GHR/BP-/- mice were also smaller (39%) than controls, and this decrease in size was reflected by a decrease (39%) in the total RNA recovered (Table 3). Although the pituitaries were reduced in size, the proportion of GH immunopositive cells represented 64% of all pituitary cells, in contrast to the 51% observed in normal mouse pituitaries. Hypothalamic GHRH mRNA levels in GHR/BP-/- mice were 232 ± 20% (P < 0.01) of GHR/BP+/+ littermates, whereas SRIF and NPY mRNA levels were reduced to 86 ± 2% (P < 0.05) and 46 ± 3% (P < 0.01), respectively (Fig. 2A). Pituitary GHRH-R and GHS-R mRNA levels of GHR/BP-/- mice were elevated to 275 ± 55% and 319 ± 68% of GHR/BP+/+ values (P < 0.05), whereas the sst2 and sst5 mRNA levels did not differ from controls (Fig. 2B).

View larger version (21K): [in this window] [in a new window]   Figure 2. Relative mRNA levels of hypothalamic GHRH, SRIF and NPY, and pituitary GHRH-R, GHS-R, sst2, and sst5 in GHR/BP-/- and GHR/BP+/+ littermate control mice. Hypothalamic mRNA levels were determined by RPA, and their relative levels were adjusted by -actin and expressed as percent of GHR/BP+/+ controls (A). Pituitary receptor mRNA levels were determined by multiplex RT-PCR, and the relative levels were adjusted by GAPDH and expressed as percent of GHR/BP+/+ controls (B). Values represent the mean ± SEM. Numbers in parentheses are number of animals examined in each of the corresponding groups. *, P < 0.05; **, P < 0.01.

View larger version (23K): [in this window] [in a new window]   Figure 3. Relative mRNA levels of hypothalamic GHRH, SRIF and NPY, and pituitary GHRH-R, GHS-R, sst2, and sst5 in MT-hGHRH and wild-type (WT) littermate control mice. Hypothalamic mRNA levels were determined by RPA, and their relative levels were adjusted by -actin and expressed as percent of WT controls (n = 5 animals/group, A). Pituitary receptor mRNA levels were determined by multiplex RT-PCR, and the relative levels were adjusted by GAPDH and expressed as percent of WT controls (n = 10 animals/group, B). Values represent the mean ± SEM. *, P < 0.05; **, P < 0.01.

	Discussion

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Of interest is what drives these GH-mediated changes in hypothalamic GHRH and SRIF expression. A schematic, representing the putative interactions of the various components of the GH-axis, is shown in Fig. 4, to serve as a reference for the discussion that follows. Evidence from functional as well as anatomical studies demonstrate that NPY neurons within the arcuate nucleus express GHRs. These studies also suggest that NPY may be required for GH-mediated changes in GHRH and SRIF expression (reviewed in 20, 21). It is hypothesized that, in the presence of elevated circulating GH, NPY neurons are activated, thus decreasing GHRH production within the arcuate nucleus and increasing SRIF production within the periventricular nucleus. This hypothesis is supported by the fact that genetic disorders with decreased GH production [SDR; (5)] or GH signaling (GHR/BP-/-, current report) are characterized by reduced hypothalamic NPY expression. If GH-stimulated NPY expression leads to a decrease in GHRH and an increase in SRIF, we might have expected NPY mRNA levels to be elevated in the hypothalamus of the MT-hGHRH mouse; however, this was not the case. One possibility that would account for this discrepancy may be that maximal GH effects on NPY expression are achieved at physiologic concentrations; therefore, GH hypersecretion, as observed in the MT-hGHRH mouse, would not further stimulate NPY gene expression. This hypothesis is consistent with the fact that GH-mediated changes in hypothalamic NPY mRNA levels have been reported only after GH replacement in GH-deficient states (5, 20, 21).

View larger version (82K): [in this window] [in a new window]   Figure 4. Schematic representing the putative interactions of the various components of GH-axis, as determined by the results of the present study and the observations of others. Interactions representing direct effects are shown by the solid lines, whereas the dashed lines show interactions that may be indirect. +, -, Stimulatory or inhibitory actions on hormone synthesis and/or release, respectively. See Discussion for further details.

Because GHS-R expression parallels GHRH-R mRNA levels in both the GHR/BP-/- mouse and the SDR, it is tempting to speculate that the genes for the GHRH-R and GHS-R share common regulators. And indeed, increases in circulating GH levels were associated with a reduction in pituitary GHS-R mRNA levels in SDRs (7) and in rats implanted with GH-producing tumors (28). Direct evidence supporting a role for SRIF and IGF-I in these GH-induced changes awaits further experimentation. However, a positive role for GHRH in GHS-R regulation has been suggested. Hypophysectomized rats with pituitaries transplanted under the kidney capsule maintain responsiveness to GHRP-6 by prior GHRH priming (29). Also, acute GHRH exposure (4 h; iv) of normal rats or SDRs results in a 2-fold increase in GHS-R mRNA levels (26). However, the acute stimulatory effect of GHRH on GHS-R mRNA levels in vivo could not be reproduced in vitro (26), suggesting that GHRH modulates additional factors important in pituitary GHS-R gene regulation.

In contrast to the GHR/BP-/- mouse, mRNA levels for GHRH-R and GHS-R were unchanged in the MT-hGHRH mouse. These divergent observations may be explained by the fact that, in the MT-hGHRH mouse, unlike the GHR/BP-/- mouse, functional GHRs are present; and therefore, GH feedback regulation is intact. Hyperstimulation of the anterior pituitary by hGHRH leads to an increase in circulating GH that stimulates the production of peripheral IGF-I, in addition to increasing hypothalamic expression of SRIF. Elevated IGF-I and SRIF would, in turn, counteract the stimulatory actions of GHRH on its own receptor expression. It remains to be determined whether IGF-I and SRIF also suppress GHS-R synthesis.

Results obtained from this and previous studies demonstrate that GH feedback regulation includes regulation of the GH-stimulatory pituitary receptors. However, the association between GH and its inhibitory receptors (i.e. SRIF receptors) is not as clear. Seven SRIF receptor subtypes, encoded by five separate genes (sst1–5), have been cloned and characterized. Although all SRIF receptor subtypes have been detected in the anterior pituitary, in situ hybridization and immunocytochemistry studies indicate that sst2 and sst5 are the most dominant isoforms within the somatotrope population (reviewed in 30, 31). In addition, sst2 and sst5 selective agonists suppress GH release from primary pituitary cell cultures at concentrations 1000-fold less than sst1, 3, and 4 agonists (32), suggesting that sst2 and sst5 are primary mediators of pituitary GH release. Therefore, in the present report, we chose to examine the impact of genetic disruption of the GH-axis on pituitary sst2 and sst5 mRNA levels. In the GHR/BP-/- mouse, sst2 and sst5 expression levels did not differ from GHR/BP intact controls; whereas, in the MT-hGHRH mouse, both sst2 and sst5 mRNA levels were elevated to 140% of wild-type littermates. These observations were unexpected, because we had previously reported that in the SDR, the lack of GH was associated with an increase in sst2 and a decrease in sst5 mRNA levels, which could both be normalized with GH replacement (8). Taken together, these data suggest that GH-mediated regulation of pituitary SRIF receptor subtype expression may be species-specific.

It should be noted that comparisons between GH-regulatory pituitary receptor expression in wild-type and genetic mutant strains were made on a per-microgram-of-total-RNA basis. However, the proportion of somatotropes was significantly elevated in both GHR/BP-/- mice (64%) and MT-hGHRH mice (70%), compared with their respective controls (50%). These observations are consistent with previous histological evaluations demonstrating somatotrope hyperplasia in GHR/BP-/- (33) and MT-hGHRH (16) mice. Therefore, it can be argued that changes in pituitary receptor expression may be related to changes in the number of cells expressing the receptor and not to changes in the level of receptor expression per cell. Of all the pituitary receptor types studied, only the GHRH-R has been shown to be exclusively expressed in the somatotrope (34, 35). Therefore, a portion (but not all) of the more than 2-fold increase in GHRH-R mRNA levels observed in the GHR/BP-/- mice may be attributable to the relative increase in somatotrope number. Applying this same rationale to the other pituitary receptors (GHS-R, sst2, and sst5) is more difficult, in that the expression of these receptors is not limited to the somatotrope population. Lactotropes, thyrotropes, and corticotropes, as well as somatotropes, have been shown to express the GHS-R (36, 37, 38), whereas all pituitary cell types express sst2 and sst5 (30, 31). Therefore, it remains to be determined whether changes in the relative proportion of somatotropes contributed to the changes in GHS-R, sst2, and sst5 expression observed in this study.

In summary, examination of the GH axis of GHR/BP-/- and MT-hGHRH mice demonstrates that changes in GH signaling or production alters both hypothalamic neuropeptide and pituitary receptor expression. In the absence of GH negative feedback, as observed in the GHR/BP-/- mouse, both hypothalamic and pituitary expression is altered to favor stimulation of GH synthesis and release; whereas, in the presence of GH negative feedback, as in the MT-hGHRH mouse, both hypothalamic and pituitary expression is altered to favor suppression of GH synthesis and release.

	Footnotes

 
¹ This work was supported, in part, by USPHS Grant DK-30667 (to R.D.K.); by funding from the Bane Foundation (to L.A.F.) and from the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) of Ministry for Science and Technology of Brazil (to M.R.G.); and by the State of Ohio’s Eminent Scholars Program, which includes a gift from Milton and Lawrence Goll (to J.J.K.).

² Visiting Scientist from the Department of Pharmacology, Kyunghee University School of Medicine, Seoul 130–701, Korea.

Received August 22, 2000.

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