Molecular cloning, characterization of cDNA, and distribution of mRNA encoding the frog prohormone convertase PC1

RT-PCR analysis of the expression of POMC and its processing enzyme PC1 in amphibian melanotropes

The frog intermediate lobe comprises two functionally distinct cell subtypes, referred to as secretory and storage melanotropes, which differ in their ultrastructure, secretory, and synthetic rates, and display dissimilar responses to hypothalamic regulatory factors. All these differences make melanotrope subtypes an excellent model to analyze the expression and regulation of genes involved in the control and maintenance of the secretory state of endocrine cells. However, quantification of the expression levels of genes involved in the secretory process requires the characterization of a gene whose expression remains constant irrespective of the secretory state of the cells. In this study, we have cloned the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) gene from frog pituitary and have evaluated its suitability as internal standard in gene expression studies in melanotropes. A semiquantitative RT-PCR system developed to this end revealed that secretory melanotropes and storage melanotropes possess similar expression levels of GAPDH, whereas, as expected, secretory melanotropes showed higher levels of POMC transcripts than storage cells. Furthermore, we found that the expression of the convertase PC1, an intracellular protease involved in POMC processing, parallels that of POMC, thus suggesting that the higher secretory rate of the POMC-derived peptide alpha-MSH exhibited by secretory melanotropes is supported by their higher PC1 expression levels. In addition, we have shown that both POMC and PC1 mRNAs are up-regulated by the hypothalamic factor TRH in melanotrope cell cultures. In contrast, the inhibitory factor NPY reduced the expression level of the convertase but did not modify that of POMC. Taken together, these results demonstrate that PC1 expression is regulated in melanotropes by both stimulatory (TRH) and inhibitory (NPY) hypothalamic signals, in a manner which essentially parallels that observed for the precursor POMC.

Expression and localization of prohormone convertase PC1 in the calcitonin-producing cells of the bullfrog ultimobranchial gland

We examined the expression and localization of the prohormone convertases, PC1 and PC2, in the ultimobranchial gland of the adult bullfrog using immunohistochemical (IHC) and in situ hybridization (ISH) techniques. In the ultimobranchial gland, PC1-immunoreactive cells were columnar, and were present in the follicular epithelium. When serial sections were immunostained with anti-calcitonin, anti-CGRP, anti-PC1, and anti-PC2 sera, PC1 was found only in the calcitonin/CGRP-producing cells. No PC2-immunopositive cells were detected. In the ISH, PC1 mRNA-positive cells were detected in the follicle cells in the ultimobranchial gland. No PC2 mRNA-positive cells were detected. RT-PCR revealed expression of the mRNAs of PC1 and the PC2 in the ultimobranchial gland. However, very little of the PC2 mRNA is probably translated because no PC2 protein was detected either by IHC staining or by Western blotting analysis. We conclude that the main prohormone convertase that is involved in the proteolytic cleavage of procalcitonin in the bullfrog is PC1.

Novel neuropeptides related to frog growth hormone-releasing peptide: isolation, sequence, and functional analysis

We previously identified in the bullfrog a novel hypothalamic RFamide peptide (SLKPAANLPLRF-NH(2)) that stimulated GH release in vitro and in vivo and therefore was designated frog GH-releasing peptide (fGRP). Molecular cloning of cDNA encoding the deduced fGRP precursor polypeptide further revealed that it encodes fGRP and its related peptides (fGRP-RP-1, -RP-2, and -RP-3). In this study immunoaffinity purification using the antibody against fGRP was therefore conducted to determine whether these three putative fGRP-RPs exist as mature endogenous ligands in the frog brain. The mass peaks of the isolated immunoreactive substances were detected at 535.78, 1034.14, and 1079.71 m/z ([M+2H](2+)), and their sequences, SIPNLPQRF-NH(2), YLSGKTKVQSMANLPQRF-NH(2), and AQYTNHFVHSLDTLPLRF-NH(2), were revealed by the fragmentation, showing mature forms encoded in the cDNA sequences of fGRP-RP-1, -RP-2, and -RP-3, respectively. All of these fGRP-RPs contained a C-terminal -LPXRF-NH(2) (X = L or Q) sequence, such as fGRP. This study further analyzed hypophysiotropic activities of the identified endogenous fGRP-RPs. Only fGRP-RP-2 stimulated, in a dose-related way, the release of PRL from cultured frog pituitary cells; its threshold concentration ranged from less than 10(-7) M. A similar stimulatory action of fGRP-RP-2 on GH release was evident. It was ascertained that fGRP-RP-2 was also effective in elevating the circulating GH and PRL levels when administered systemically. In contrast, fGRP-RPs did not have any appreciable effect on the release of gonadotropins. Thus, fGRP-RP-2 may act as a novel hypothalamic factor on the frog pituitary to stimulate the release of GH and PRL.

Characterization of the cDNA encoding a somatostatin variant in the chicken brain: comparison of the distribution of the two somatostatin precursor mRNAs

Although the existence of two somatostatin variants (SS1 and SS2) has now been demonstrated in the brain of mammals, amphibians, and fish, only one isoform of somatostatin (SS1) has been characterized to date in the brain of birds. Here we report cloning of the cDNA encoding a 101-amino-acid protein (PSS2) that encompasses the somatostatin variant [Pro(2)]somatostatin-14 (SS2) at its C-terminus. Sequence analysis indicated that chicken PSS2 is more closely related to fish PSS2 than to mammalian cortistatin precursors. Northern blot analysis showed that the chicken PSS1 gene is expressed in the central nervous system (CNS) and in the pancreas, whereas the PSS2 gene is expressed only in the CNS and not in peripheral organs. In situ hybridization histochemistry revealed that, in the chicken brain, PSS1 mRNA is more widely distributed than PSS2 mRNA. In particular, PSS1 mRNA expression was found in the hippocampus, the hyperstriatum, the preoptic area, the ventricular hypothalamic nuclei, the optic tectum, and several nuclei of the mesencephalon and rhombencephalon. In contrast, the distribution of PSS2 mRNA was restricted to a few regions of the brain, including the paraolfactory lobe, the paleostriatum, and some nuclei of the mesencephalon and rhombencephalon. The fact that the PSS1 and PSS2 genes are differently expressed in the brain and in peripheral organs indicates that, in chicken, the two somatostatin variants likely exert distinct functions. In particular, the observation that PSS1 mRNA, but not PSS2 mRNA, occurs in the preoptic area and in the ventral hypothalamic nuclei suggests that, of the two somatostatin isoforms, only SS1 acts as a hypophysiotropic factor.

Occurrence of prohormone convertase-like substances in the neural complex cells of the ascidian Halocynthia roretzi

Our previous study on the distribution of adrenocorticotropin (ACTH)-like substances in the neural complex (cerebral ganglion, dorsal strand, and neural gland) of an ascidian Halocynthia roretzi revealed that some of the cells in the cerebral ganglion and the cells scattered along the dorsal strand were immunopositive with antiserum against ACTH. In order to ascertain whether these cells are equipped with prohormone convertases, we performed immunohistochemical studies on the neural complex by using antisera against PC1 and PC2. A considerable number of cells around the dorsal strand and a few cells in the neural ganglion were immunopositive with PC1 and/or PC2 antibodies. Immunoelectron microscopic study demonstrated that some granulated cells situated in the cerebral ganglion and along the dorsal strand contained PC1- or PC2-like substances within their secretory granules. Western blot analysis revealed the presence of 66-kDa PC1-like and 70-kDa PC2-like substances in the neural complex. Moreover, immunostaining of consecutive sections showed that the majority of the cells containing PC1- and/or PC2-like substances corresponded to the cells immunoreactive with antisera against ACTH and CLIP but not to those immunoreactive with an antiserum against PRL. Cells belonging to the neural gland neither contained electron-dense granules nor showed immunoreactivity with any antisera employed in this experiment. The possibility that some of the cells situated in the cerebral ganglion and along the dorsal strand are progenitors of vertebrate adenohypophyseal cells is discussed.

Molecular characterization of the cDNA and localization of the mRNA encoding the prohormone convertase PC5-A in the European green frog

The structure and distribution of PC5-A, a prohormone convertase that is thought to be involved in post-translational processing of peptide hormone and neuropeptide precursors, have not been investigated in submammalian vertebrates. In the present study, we characterized the cDNA encoding PC5-A in the European green frog Rana esculenta. The frog PC5-A cDNA encodes a 913-amino acid protein that encompasses a 28-amino acid signal peptide, the Asp/His/Ser catalytic triad found in all serine proteinases of the subtilisin family, and two potential N-linked glycosylation sites located in a C-terminal cysteine-rich domain. Reverse transcriptase polymerase chain reaction amplification showed that PC5-A mRNA is expressed in various organs including the brain, spinal cord, pituitary, lung, liver, intestine, and testis, but not in the stomach and pancreas. The distribution of PC5-A mRNA in the frog brain was studied by in situ hybridization histochemistry. Intense expression was observed in the mitral cellular layer of the olfactory bulb, the nucleus of the diagonal band of Broca, the anterior preoptic area, and the suprachiasmatic and ventral hypothalamic nuclei. The expression pattern of PC5-A mRNA in the central nervous system of anuran amphibians was consistent with the implication of this prohormone convertase in the processing of various neuropeptide precursors.

Polygenic expression of somatostatin in the sturgeon Acipenser transmontanus: molecular cloning and distribution of the mRNAs encoding two somatostatin precursors

The sequence of somatostatin-14 (SS1) has been strongly preserved throughout the evolution of vertebrates from agnathans to mammals. In Acipenseridae (sturgeons), two isoforms of somatostatin have been characterized to date: somatostatin-14 has been identified from the gastrointestinal tract of the pallid sturgeon Scaphirhynchus albus and [Pro(2)]somatostatin-14 has been identified from the pituitary of the Russian sturgeon Acipenser gueldenstaedti. In the present study, we report the cloning of two distinct somatostatin cDNAs from the brain of the sturgeon Acipenser transmontanus. One of the cDNAs encodes a 116-amino acid protein (PSS1) that contains the SS1 sequence at its C-terminal extremity and, thus, is clearly orthologous to other vertebrate PSS1. The other cDNA encodes a 111-amino acid protein that contains the somatostatin variant [Pro(2)]somatostatin-14 at its C-terminal extremity. This second precursor exhibits more than 67% identity with the recently characterized lungfish PSS2 and goldfish PSS2. Reverse transcriptase-polymerase chain reaction analysis revealed that PSS1 is expressed in the central nervous system, the pancreas and the gut, whereas PSS2 is found in the central nervous system but not in the digestive system. In situ hybridization histochemistry showed that the PSS1 and PSS2 genes are differently expressed in numerous regions of the sturgeon brain. Interestingly, PSS1 and PSS2 mRNAs are present in the hypothalamus suggesting that, in sturgeon, both SS1 and SS2 may play hypophysiotropic functions. The PSS2 mRNA but not the PSS1 mRNA was found in the intermediate lobe of the pituitary. The present data demonstrate that two somatostatin genes are expressed in the sturgeon brain: one precursor generates somatostatin-14 and the other one gives rise to a [Pro(2)]somatostatin-14 variant, which is orthologous to goldfish, lungfish, and frog SS2.

Pituitary adenylate cyclase-activating polypeptide and its receptors in amphibians

Pituitary adenylate cyclase-activating polypeptide (PACAP), a novel peptide of the secretin/glucagon/vasoactive intestinal polypeptide superfamily, has been initially characterized in mammals in 1989 and, only 2 years later, its counterpart has been isolated in amphibians. A number of studies conducted in the frog Rana ridibunda have demonstrated that PACAP is widely distributed in the central nervous system (particularly in the hypothalamus and the median eminence) and in peripheral organs including the adrenal gland. The cDNAs encoding the PACAP precursor and 3 types of PACAP receptors have been cloned in amphibians and their distribution has been determined by in situ hybridization histochemistry. Ontogenetic studies have revealed that PACAP is expressed early in the brain of tadpoles, soon after hatching. In the frog Rana ridibunda, PACAP exerts a large array of biological effects in the brain, pituitary, adrenal gland, and ovary, suggesting that, in amphibians as in mammals, PACAP may act as neurotrophic factor, a neurotransmitter and a neurohormone.

Ontogeny of pituitary adenylate cyclase-activating polypeptide (PACAP) in the frog (Rana ridibunda) tadpole brain: immunohistochemical localization and biochemical characterization

The anatomic distribution and biochemical characteristics of the neuropeptide pituitary adenylate cyclase-activating polypeptide (PACAP) were investigated in the central nervous system of the frog, Rana ridibunda, during development. Three to four days after hatching, at stages IV-VII, PACAP-immunoreactive perikarya were detected in the dorsal thalamus within the anterior ventral area, and a few fibers were found in the medial pallium. Positive cell bodies were first observed in the hypothalamus at stages VIII-IX, at the level of the dorsal and ventral infundibular nuclei. In these regions, the number of positive perikarya increased during ontogeny. In tadpoles, during the mid- and late premetamorphosis, a more complex organization of the PACAP-immunoreactive system was found in the thalamus with the appearance, at stages IX-XII, of two additional groups of positive neurons in the ventrolateral area and posterocentral nucleus. At stages XIII-XVIII of larval development and subsequent larval stages, PACAP-immunoreactive fibers were found in the median eminence. In newly metamorphosed animals, several additional groups of positive perikarya appeared in the medial pallium, the preoptic nucleus, the torus semicircularis, the tegmentum of the mesencephalon, and the cerebellum. The immunoreactive peptide contained in the tadpole brain was characterized by high performance liquid chromatography analysis combined with radioimmunoassay quantification. At all stages investigated, the predominant form of PACAP-immunoreactive material coeluted with synthetic frog PACAP38. The occurrence of PACAP soon after hatching indicates that the peptide may exert neurotrophic activities. The existence of immunoreactive elements in several thalamic regions at mid- and late premetamorphic stages suggests that PACAP may act as a neurotransmitter, neuromodulator, or both, during ontogenesis. Finally, the presence of PACAP-immunoreactive perikarya in hypothalamic nuclei and nerve fibers in the median eminence supports the view that PACAP may play a role in the control of pituitary hormone secretion during larval development.

Expression and localization of prohormone convertase 1/3 (SPC3) in porcine ovary

Tissue distribution and cellular localization of PC1/3 mRNA in porcine tissues were examined by ribonuclease protection assay and in situ hybridization. PC1/3 mRNA was detected mainly in the corpus luteum of pregnant sow and brain. Within the ovary, PC1/3 and relaxin transcripts colocalized within large luteal cells. Levels of PC1/3 transcripts in corpora lutea increased as gestation advanced, parallel with an observed increase in relaxin transcripts. A role for PC1/3 in proprotein processing in the ovary is discussed.