Prolactin-releasing peptide, a possible modulator of prolactin in the euryhaline silver sea bream (Sparus sarba): A molecular study

PRL and PrRP cDNAs have been isolated from euryhaline silver sea bream (Sparus sarba). The PRL cDNA consists of 1360 bp encoding 212 amino acids whereas the PrRP cDNA contains 631 bp encoding preproPrRP with 122 amino acids. The mature PrRP sequence within the preprohormone is identical to the PrRPs isolated from other fish species. PRL mRNA was uniquely expressed in sea bream pituitary but PrRP mRNA was expressed in a variety of organs and tissues including the intestines, olfactory rosette and various brain regions such as hypothalamus and pituitary. Expression levels of PRL and PrRP mRNA have been examined in sea bream adapted to different salinities (0, 6, 12, 33 and 50 ppt). In the pituitary, both PRL and PrRP mRNA were significantly higher in fish adapted to low salinities (0 and 6 ppt) and the expression profiles of both hormones closely paralleled each other. However, expression of hypothalamic PrRP was significantly higher in fish adapted to iso-osmotic salinity (12 ppt) when pituitary PRL expression was low. The present study demonstrates, for the first time, a synchronized mRNA expression pattern between PRL and PrRP in fish pituitary but a disparity of mRNA expression levels between hypothalamic PrRP and pituitary PRL during salinity adaptation. These data suggest that PrRP may possibly act as a local modulator in pituitary rather than a hypothalamic factor for regulation of pituitary PRL expression in silver sea bream.     

Molecular cloning and sequence analysis of putative chicken prolactin cDNA

A cDNA library was prepared from mRNA isolated from anterior pituitary glands of incubating bantam hens, in which prolactin mRNA levels were predicted to be very high. Nine clones, representing abundant mRNA species, were identified and shown to contain homologous sequences. Two clones, of 871 bp and 580 bp, were analysed by DNA sequencing. The shorter clone was found to be a truncated cDNA product but otherwise identical to the longer clone. The 871 bp cDNA, PRL101, contains an open reading frame capable of encoding a polypeptide of 229 amino acids. This putative polypeptide has a high degree of homology to mammalian prolactins (approximately 70%), strongly suggesting that PRL101 encodes chicken preprolactin. The protein was predicted to have a 30 amino acid signal sequence which would be cleaved off to give a mature protein of 199 amino acids. The peptide sequence also had a 26% homology to chicken growth hormone, which is related to prolactin. This similarity confirms the conclusion that PRL101 is a chicken prolactin cDNA clone. An abundant mRNA of approximately 880 b was detected in poly(A)+ RNA from pituitary glands probed with PRL101. Analysis of chicken genomic DNA showed that there is one copy of the prolactin gene in the genome. PRL101 hybridized strongly to genomic DNA from closely related galliforms (quail and turkey) and less strongly to DNA from more distantly related species (duck and ring dove).     

Isolation and characterization of a homologue of mammalian prolactin-releasing peptide from the tilapia brain and its effect on prolactin release from the tilapia pituitary

In the tilapia (Oreochromis mossambicus), as in many teleosts, prolactin (PRL) plays a major role in osmoregulation in freshwater. Recently, PRL-releasing peptides (PrRPs) have been characterized in mammals. Independently, a novel C-terminal RF (arginine-phenylalanine) amide peptide (Carrasius RF amide; C-RFa), which is structurally related to mammalian PrRPs, has been isolated from the brain of the Japanese crucian carp. The putative PrRP was purified from an acid extract of tilapia brain by affinity chromatography with antibody against synthetic C-RFa and HPLC on a reverse-phase ODS-120 column. The tilapia PrRP cDNA was subsequently cloned by polymerase chain reaction. The cDNA consists of 619 bp encoding a preprohormone of 117 amino acids. Sequence comparison of the isolated peptide and the preprohormone revealed that tilapia PrRP contains 20 amino acids and is identical to C-RFa. Incubation of the tilapia pituitary with synthetic C-RFa (100 nM) significantly stimulated the release of two forms of tilapia PRL (PRL188 and PRL177). However, the effect of C-RFa was less pronounced than the marked increase in PRL release in response to hyposmotic medium. The ability of C-RFa to stimulate PRL release appears to be specific, since C-RFa failed to stimulate growth hormone release from the pituitary in organ culture. In contrast, rat and human PrRPs had no effect on PRL release. C-RFa was equipotent with chicken GnRH in stimulating PRL release in the pituitary preincubated with estradiol 17beta. Circulating levels of PRL were significantly increased 1 h after intraperitoneal injection of 0.1 microg/g of C-RFa in female tilapia in freshwater but not in males. These results suggest that C-RFa is physiologically involved in the control of PRL secretion in tilapia.     

Cloning and Expression of Somatolactin, a Pituitary Hormone Related to Growth Hormone and Prolactin from Gilthead Seabream,Sparus aurata

A pituitary hormone, somatolactin (SL), belonging to the GH/PRL family, is produced in the intermediate lobe of the teleost pituitary. The function of this protein is uncertain. Clones coding for SL were isolated and sequenced from a gilthead seabream pituitary cDNA expression library. The nucleotide sequence of the larger cDNA isolated was 1.5 kb containing a 0.8-kb 3′-untranslated region and two potential polyadenylation signals (AATAAA). The mature polypeptide is composed of 207 amino acids, and a signal peptide of 24 residues was also found in the SL precursor. A potential N-glycosylation site Asn-Lys-Thr was identified in gilthead seabream SL. A comparison of the SL amino acid sequences of several fishes indicated that seven cysteine residues are characteristically present in all the SLs so far isolated. Six of those residues are present in homologous positions in SL and GHSparus aurataproteins. SL and GH fromS. auratashowed a 43% homology at the nucleotide level and 22% identity at the amino acid level. Expression of recombinant SL (rSL) inEscherichia coliand isolation from inclusion bodies led to a monomeric form of SL identical in electrophoretic mobility to one of the two forms of the native SL secreted from gilthead seabream pituitaries culturedin vitro.Further, a native glycosylated modified SL secretedin vitroas shown by N-glycosidase treatment was identified. Specific anti-SL antibodies that discriminate well against gilthead seabream GH and PRL in immunoblotting were also raised against rSL.     

PRL and GH synthesis and release from the sea bream (Sparus auratus L.) pituitary gland in vitro in response to osmotic challenge

The endocrine factors prolactin (PRL) and growth hormone (GH) are believed to have counteracting effects in the adaption of fish to changes in environmental salinity. In order to further investigate this interaction sea bream were challenged with full seawater (SW) or freshwater (FW) for 7 days and the response of pituitary glands cultured in vitro to an osmotic challenge (230, 275 and 320 mOsm/kg) was assessed. In vitro PRL secretion from pituitaries of SW-adapted fish was unaltered in response to an osmotic challenge, while GH secretion increased in the lowest osmolality (230 mOsm/kg). In contrast, both GH and PRL secretion by pituitaries from FW challenged fish was significantly increased (p < 0.01) over that of pituitaries from SW fish at the highest osmolality (320 mOsm/kg). After FW challenge pituitary PRL content and de novo synthesised and released PRL were significantly increased (p < 0.01), while total PRL secretion was not different from SW animals. GH pituitary content decreased in FW animals while total secretion and secretion of de novo synthesised protein were significantly increased (p < 0.01). In addition, after transfer of fish to FW expression of PRL and GH increased 3- and 2-fold, respectively. Despite the increase in PRL expression, no increase in total PRL secretion occurred and although in gills a 2-fold increase in the osmoregulatory marker, Na⁺/K⁺-ATPase activity was detected, profound haemodilution and a cumulative mortality of 40% occurred in sea bream placed in FW. Taken together the results suggest that the sea bream pituitary gland fails to respond appropriately to the osmotic challenge caused by low salinity and the physiological response evoked in vivo is not enough to allow this species to withstand and adapt to FW.     

The primary structure of coho salmon growth hormone and its cDNA

Total RNA was extracted from coho salmon growth hormone (sGH) cell regions and used to synthesize double-stranded cDNA, which was inserted into a plasmid vector and used to transform Escherichia coli HB101. The total RNA was also separated according to size by electrophoresis on agarose gels and the fraction that directed the cell-free synthesis of protein in the size range of GHs of other species was isolated and used to screen the transformed colonies of E. coli. A clone containing the putative sGH cDNA was identified and its nucleotide sequence was determined. To verify that the cDNA was that of sGH, the GH cell region of coho pituitary glands was incubated in organ culture. The secreted GH was purified by HPLC and the sequence of its 42 amino-terminal amino acids was determined. Comparison of this sequence with the amino acid sequence derived from the cDNA showed that it encoded sGH. Medium containing the presumptive sGH as the only prominent protein was active in a GH radioreceptor assay that involved labeled bovine GH and pregnant mouse liver membranes: the sGH was approximately 10% as active as the bGH standard. RNA blotting analysis showed that sGH was the major species of RNA produced by the GH cell region of the salmon pituitary. The mRNA of sGH differed from those of human, rat, and bovine GH in that its 3'-untranslated region was unusually large (about 500 nucleotides) but the coding region showed significant homology with mammalian GHs and resembled them in having a strong (78%) preference for G and C in the third positions of the codons. The amino acid sequence of sGH showed 32-34% and 19-22% identical homology with mammalian GHs and prolactins, respectively. Several conserved regions between sGH and mammalian GH and PRL molecules were also revealed that could indicate conservation of structurally and/or functionally important domains. Hydropathy analysis disclosed that although sGH and the GH of a representative mammal (pig) had similar profiles in some regions, the sGH was overall more hydrophobic than the pig (p) GH. Similarities and differences, were also noted in the predicted secondary structure of sGH and pGH.     

Molecular cloning of growth hormone-encoding cDNA of an Indian major carp, Labeo rohita, and its expression in Escherichia coli and zebrafish

The cDNA clones encoding for growth hormone (GH) of an Indian major carp rohu Labeo rohita were isolated from a cDNA library constructed from the poly(A)(+) RNA extracted from the pituitary glands of rohu. Partial GH cDNA of the rohu (3'-end) was amplified by RT-PCR and used as probe to screen the cDNA library. Full-length GH-specific cDNA clones (1180 bp) were isolated and sequenced. The sequence contains 48-bp 5'-noncoding region followed by an ORF of 621 bp and a 3'-noncoding region of 521 bp. The peptide shares about 90% identity with the GH of Cyprinus carpio (Linn.) and >84% identity with GH sequences of other cyprinids. The GH-encoding cDNA of rohu has been cloned into expression vectors and GH protein has been over expressed in Escherichia coli and purified as a soluble protein. The GH cDNA was cloned into a bicistronic vector with EGFP; injection of in vitro transcribed GH-EGFP mRNA into zebrafish embryo has resulted in EGFP expression confirming the cloned GH cDNA is functional in fish and the IRES element could be effectively used in fish for bicistronic expression of foreign genes.     

Immunocytochemical identification of the prolactin- and growth hormone-secreting cells in the teleost pituitary with antisera to tilapia prolactin and growth hormone

Antisera raised to highly purified tilapia (Sarotherodon mossambicus) prolactin (PRL) and growth hormone (GH) were used to locate PRL and GH cells in the adenohypophysis of seven species of teleosts by immunoenzymological methods using horseradish peroxidase. The only pituitary cells in the tilapia that immunologically reacted with anti-tilapia PRL were the PRL cells located in the rostral pars distalis (RPD). In the pituitary glands of two species of salmonids and two species of marine fishes, the tilapia PRL antibodies bound to both PRL and GH cells; no prolactin-immunoreactive cells were identified in the goldfish and eel pituitaries. Antiserum to tilapia GH reacted specifically with the GH cells located in the proximal pars distalis of all teleosts examined in this study, but not with any presumed PRL cells in the RPD. These results indicate that tilapia PRL antisera are specific for tilapia PRL cells but not necessarily for these cells in other teleost species. Tilapia GH antisera showed no species specificity among the teleosts tested.     

Genomic structure of the sea lamprey growth hormone-encoding gene

Growth hormone (GH) belongs to a family of pituitary hormones together with prolactin and somatolactin. In our previous study, GH and its cDNA were identified in the pituitary gland of the sea lamprey, Petromyzon marinus, an extant representative of the most ancient class of vertebrates, and isolated GH stimulated expression of insulin-like growth factor in the liver. The evidence suggests that GH is the ancestral hormone in the molecular evolution of the GH/PRL/SL family and that the endocrine mechanism for growth stimulation was established at an early stage in the evolution of vertebrates. To further understand the molecular evolution of the GH/PRL/SL gene family, we report the genomic structure of sea lamprey GH including its 5'-flanking region, being cloned by PCR using specific primers prepared from its cDNA. The sea lamprey GH gene consists of 13,604 bp, making it the largest of all the GH genes. The 5'-flanking region within 697 bp contains consensus sequences for a TATA box, two Pit-1/GHF-1, three TRE, and a CRE. The sea lamprey GH gene consists of five exons and four introns, the same as in mammals, birds, and teleosts such as cypriniforms and siluriforms with the exception of some teleosts such as salmoniforms, percififorms, and tetradontiforms, in which there is an additional intron in the 5th exon. The 5-exon-type gene organization might reflect the structure of the ancestral gene for the GH/PRL/SL gene family.     

Isolation, cDNA cloning, and growth promoting activity of rabbitfish (Siganus guttatus) growth hormone

We report the isolation, cDNA cloning, and growth promoting activity of rabbitfish (Siganus guttatus; Teleostei; Perciformes; Siganidae) growth hormone (GH). Rabbitfish GH was extracted from pituitary glands under alkaline conditions, fractionated by gel filtration chromatography on Sephadex G-100, and purified by high-performance liquid chromatography. The fractions containing GH were identified by immunoblotting with bonito GH antiserum. Under nonreducing conditions, the molecular weight of rabbitfish GH is about 19 kDa as estimated by SDS-PAGE. The purified hormone was potent in promoting growth in rabbitfish fry. Weekly intraperitoneal injections of the hormone significantly accelerated growth. This was evident 3 weeks after the start of the treatment, and its effect was still significant 2 weeks after the treatment was terminated. Rabbitfish GH cDNA was cloned to determine its nucleotide sequence. Excluding the poly (A) tail, rabbitfish GH cDNA is 860 base pairs (bp) long. It contained untranslated regions of 94 and 175 bp in the 5' and 3' ends, respectively. It has an open reading frame of 588 bp coding for a signal peptide of 18 amino acids and a mature protein of 178 amino acid residues. Rabbitfish GH has 4 cysteine residues. On the amino acid level, rabbitfish GH shows high identity (71-74%) with GHs of other perciforms, such as tuna, sea bass, yellow tail, bonito, and tilapia, and less (47-49%) identity with salmonid and carp GHs.     

Greater conservation of somatolactin, a presumed pituitary hormone of the growth hormone/prolactin family, than of growth hormone in teleost fish

From pituitary cDNA libraries of Atlantic cod and chum salmon, cDNA clones coding for somatolactin (SL), a presumed pituitary hormone belonging to the growth hormone (GH)/prolactin (PRL) family, were isolated and characterized. The 1.3-kb cod SL mRNA was composed of a greater than 0.25-kb 5' untranslated region, a coding region for the precursor of 235 amino acids (aa), a 0.14-kb 3' untranslated region, and a poly(A) tail. The 2.5-kb salmon SL mRNA had a less than 0.1-kb 5' untranslated region, a precursor (233 aa) coding region, a 1.6-kb 3' untranslated region, and a poly(A) tail. A signal peptide of 26 and 24 aa was found in the SL precursor of cod and salmon, respectively. Thus, the mature SLs of these fish are composed of 209 aa. Two potential N-glycosylation sites were identified in cod SL, whereas no site could be found in the salmon. A comparison of amino acid sequences of the three SLs so far isolated indicated six Cys residues to be in homologous positions to those in GH and PRL, and one Cys residue to be characteristically present in SL. Among cod, salmon, and flounder, greater colinearity of amino acid sequences was noted in SLs than in GHs. The identities of the SL amino acid sequences were between 73 and 81% as compared to 58-62% for the corresponding GHs, indicating greater conservation of SL than GH.