The amino-acid sequences of sculpin islet somatostatin-28 and peptide YY

Anatomic and molecular characterization of the endocrine pancreas of a teleostean fish: Atlantic wolffish (Anarhichas lupus)

BACKGROUND

The biologic attributes of the endocrine pancreas and the comparative endocrinology of islet amyloid polypeptide (IAPP) of fish are not well described in the literature. This study describes the endocrine pancreasof one teleostean fish. Ten captive Atlantic wolffish (Anarhichas lupus)from the Montreal Biodome were submitted for necropsy and their pancreata were collected.

RESULTS

Grossly, all the fish pancreata examined contained 1-3 nodules of variable diameter (1-8 mm). Microscopically, the nodules were uniform, highly cellular, and composed of polygonal to elongated cells. Immunofluorescence for pancreatic hormones was performed. The nodules were immunoreactive for insulin most prominent centrally, but with IAPP and glucagon only in the periphery of the nodules. Exocrine pancreas was positive for chromogranin A. Not previously recognized in fish, IAPP immunoreactivity occurred in α, glucagon-containing, cells and did not co-localize with insulin in β cells. The islet tissues were devoid of amyloid deposits. IAPP DNA sequencing was performed to compare the sequence among teleost fish and the potency to form amyloid fibrils. In silico analysis of the amino acid sequences 19-34 revealed that it was not amyloidogenic.

CONCLUSIONS

Amyloidosis of pancreatic islets would not be expected as a spontaneous disease in the Atlantic wolffish. Our study underlines that this teleost fish is a potential candidate for pancreatic xenograft research.

Molecular evolution of the neuropeptide Y (NPY) family of peptides: cloning of three NPY-related peptides from the sea bass (Dicentrarchus labrax)

Neuropeptide Y (NPY) is a 36-amino-acid peptide that is widely and abundantly expressed in the central nervous system of all vertebrates investigated. Related peptides have been found in various vertebrate groups: peptide YY (PYY) is present in gut endocrine cells of many species and pancreatic polypeptide (PP) is made in the pancreas of all tetrapods. In addition, a fish pancreatic peptide called PY has been reported in three species of fishes. The evolutionary relationships of fish PY have been unclear and it has been proposed to be the orthologue (species homologue) of each of the three tetrapod peptides. We demonstrate here with molecular cloning techniques that the sea bass (Dicentrarchus labrax), an acanthomorph fish, has orthologues of both NPY and PYY as well as a separate PY peptide. Sequence comparisons suggest that PY arose as a copy of the PYY gene, presumably in a duplication event separate from the one that generated PP from PYY in tetrapods. PY sequences from four species of fish indicate that, similar to PP, PY evolves much more rapidly than NPY and PYY. The physiological role of PY is unknown, but we demonstrate here that sea bass PY, like NPY and PYY but in contrast to the tetrapod PP, is expressed in brain.

Neuropeptide families and their receptors: evolutionary perspectives

Examination of families of neuropeptides and their receptors can provide information about phyletic relationships and evolutionary processes. Within an individual a given signal molecule may serve many diverse functions, mediated via subtypes of the receptor which may be coupled to their transduction mechanisms in different ways. The rate of evolution of a peptide may reflect or be reflected in the rate of evolution of its receptor. For example, in the neuropeptide Y (NPY) family, pancreatic polypeptide (PP) shows significant structural diversity, while NPY is highly conserved. Molecular forms of a given subtype of NPY receptor that is selectively activated by NPY (Y1 or Y2 or Y5) are also highly conserved, but the subtype that is primarily activated by PP (Y4), shows remarkable diversity. Also, between receptor subtypes there can be remarkable diversity. This is evident in several neuropeptide families, where a neuropeptide sequence is highly conserved across a wide range of species but where the receptor homology of subtypes with species tends to be much lower than homology between species. For example, human and rat vasopressin are identical, but the human V(1)- or V(2)-vasopressin receptors are approximately 80% homologous with rat V(1)- or V(2)-receptors, but within humans or rats the V(1)-receptor is less than 50% homologous with the V(2)-receptor. Furthermore, duplication of an ancestral gene is thought to have led to the co-presence in eutherian mammals of oxytocin and vasopressin, which have maintained a close structural similarity, yet in many species the oxytocin receptor is only 30 to 50% homologous with vasopressin receptors. Thus it appears that there has been greater evolutionary pressure to conserve the signal molecule, than to conserve the structure of the receptor. Evaluation of the evolution of neuropeptides and their receptors may be useful in determining phyletic relationships. Traditional classification places the guinea pig as a hystricomorph rodent within the same order (Rodentia) as the muriform or myomorph rat and mouse. However, molecular analyses of polypeptides have led to the suggestion that guinea pigs belong to a distinct order. Analysis of several neuropeptide sequences and the Y4 receptor supports this view. In general terms for both neuropeptides and receptors, sequence homology reflects phylogeny and taxonomy as based on morphological features. Within the oxytocin/vasopressin family in which peptides and receptors have been characterised in invertebrate representatives as well as fish and amphibia in addition to mammals, the molecular diversity correlates well with evolutionary diversity.

Molecular cloning and pharmacological characterization of a somatostatin receptor subtype in the gymnotiform fish Apteronotus albifrons

The actions of the various forms of somatostatin (SRIF), including those of the tetradecapeptide SRIF(14), are mediated by specific receptors. In mammals, five subtypes of SRIF receptors, termed sst(1-5), have been cloned. Using a combination of reverse transcriptase-polymerase chain reaction and genomic library screening in the gymnotiform fish Apteronotus albifrons, a gene encoding the first-known nonmammalian SRIF receptor has been isolated. The deduced amino acid sequence displays 59% identity with the human sst(3) receptor protein; hence, the gene is termed "Apteronotus sst(3)." The predicted protein consists of 494 amino acid residues exhibiting a putative seven-transmembrane domain topology typical of G protein-coupled receptors. A signal corresponding to the Apteronotus sst(3) receptor was detected in brain after amplification of poly(A)(+)-RNA by reverse transcriptase-polymerase chain reaction, but not by Northern blot analysis or in situ hybridization, suggesting a low level of expression. Membranes prepared from CCL39 cells stably expressing the Apteronotus sst(3) receptor gene bound [(125)I][Leu(8),d-Trp(22), (125) I-Tyr(25)]SRIF(28) with high affinity and in a saturable manner (B(max) = 4470 fmol/mg protein; pK(D) = 10.5). SRIF(14) and various synthetic SRIF receptor agonists produced a dose-dependent inhibition of radioligand binding, with the following rank order of potency: SRIF(14) approximately SRIF(28) > BIM 23052 > octreotide > BIM 23056. Under low stringency conditions, an Apteronotus sst(3) probe hybridized to multiple DNA fragments in HindIII or EcoRI digests of A. albifrons DNA, indicating that the Apteronotus sst(3) receptor is a member of a larger family of Apteronotus SRIF receptors.

Cloning of a neuropeptide Y/peptide YY receptor from the Atlantic cod: the Yb receptor

Neuropeptide Y (NPY) belongs to a family of structurally related neuroendocrine peptides that bind to G protein-coupled receptors. Five different receptor subtypes have recently been cloned in mammals and we have found another three receptor genes in the zebrafish, called zYa, zYb, and zYc, that appear to be distinct subtypes as deduced from their widely different sequences. To elucidate the evolutionary relationships between the mammalian and zebrafish receptors, we have used the zebrafish probes to isolate genomic clones from another teleost fish, the Atlantic cod, Gadus morhua. We present here the sequence of the cod Yb gene, whose deduced protein sequence is equally identical to the zebrafish Yb (69%) and Yc proteins (66%). The two zebrafish receptors are 76% identical to each other, suggesting that they arose by gene duplication in the zebrafish lineage after divergence from the cod lineage. The five cloned mammalian NPY-family receptors and the three cloned zebrafish NPY receptors indicate that this is the largest receptor family among all peptide receptors that belong to the superfamily of G protein-coupled receptors.

Effects of somatostatin on lipid metabolism of larvae and metamorphosing landlocked sea lamprey, Petromyzon marinus

This study was designed to examine the role of somatostatin in regulating changes in lipid metabolism of larvae and metamorphosing landlocked sea lamprey, Petromyzon marinus. Larvae and animals in late metamorphosis (stage 6 on a 7-stage scale) were injected intraperitoneally once per day for 2 days with either saline (0.6%) or somatostatin-14 (SS-14; 500 ng/g body wt). Injection of SS-14 into larval and stage 6 metamorphosing animals resulted in elevated plasma fatty acids levels. In larvae, SS-14-induced hyperlipidemia was supported by enhanced lipolysis, as indicated by increased triacylglycerol lipase (TGL) activity in the liver and kidney. Mobilization of larval renal lipid was accompanied by reduced TG synthesis, as indicated by decreased diacylglycerol acyltransferase (DGAT) activity. In stage 6 metamorphosing lamprey, SS-14 did not significantly affect TGL activity; however, SS-14 significantly reduced fatty acid synthesis, as measured by acetyl-CoA carboxylase activity, in kidney, liver, and muscle, as well as muscular TG synthesis. SS-14-stimulated lipid depletion is reminiscent of the pattern of lipid metabolism displayed by P. marinus during their spontaneous metamorphosis-an observation which suggests that somatostatin may play a role in metamorphosis-associated changes in lipid metabolism in this species.

Simultaneous and coupled energy optimization of homologous proteins: a new tool for structure prediction

BACKGROUND

Homology-based modeling and global optimization of energy are two complementary approaches to prediction of protein structures. A combination of the two approaches is proposed in which a novel component is added to the energy and forces similarity between homologous proteins.

RESULTS

The combination was tested for two families: pancreatic hormones and homeodomains. The simulated lowest-energy structure of the pancreatic hormones is a reasonable approximation to the native fold. The lowest-energy structure of the homeodomains has 80% of the native contacts, but the helices are not packed correctly. The fourth lowest energy structure of the homeodomains has the correct helix packing (RMS 5.4 A and 82% of the correct contacts). Optimizations of a single protein of the family yield considerably worse structures.

CONCLUSIONS

Use of coupled homologous proteins in the search for the native fold is more successful than the folding of a single protein in the family.

Evolution of neuropeptide Y, peptide YY and pancreatic polypeptide

The neuropeptide Y family of peptides consists of neuropeptide Y (NPY), which is expressed in the central and peripheral nervous systems, and peptide YY (PYY) and pancreatic polypeptide (PP) which are gut endocrine peptides. All three peptides are 36 amino acids long and act on G-protein-coupled receptors. NPY and PYY are present in all vertebrates, whereas PP probably arose as a copy of PYY in an early tetrapod ancestor. NPY is one of the most conserved peptides during evolution and no gnathostome (jawed) species differs from the ancestral gnathostome sequence at more than five positions. PYY is more variable, particularly in mammals which have nine differences to the gnathostome ancestor. PP may be the most rapidly evolving neuroendocrine peptide among tetrapods with only 50% identity between mammals, birds, and amphibians. Ancestral gnathostome NPY and PYY seem to have differed at only four positions, suggesting that the gene duplication occurred shortly before the appearance of the gnathostomes. The two peptides differ from one another at 9-12 positions in tetrapod species and share at least two receptor subtypes in mammals. In bony and cartilaginous fishes, NPY and PYY have only 5-6 differences which, together with more extensive neuronal localization of PYY, indicate an even greater functional overlap between the two peptides in these animal groups. The emergence of sequence information for several receptor subtypes from various species will shed additional light on the evolution of the functions of the NPY-family peptides.

Neuropeptide role of both peptide YY and neuropeptide Y in vertebrates suggested by abundant expression of their mRNAs in a cyclostome brain

The evolution of the neuropeptide Y (NPY) family of peptides has been unclear despite sequence information from many vertebrates. We describe here two NPY-related peptides deduced from cDNA clones of the river lamprey (Lampetra fluviatilis), a cyclostome providing one of the best models of a primitive vertebrate brain. One peptide corresponds to NPY as it has 83% identity to human NPY and its mRNA is expressed in the lateral brainstem, dorsal spinal cord and retina. The second lamprey peptide corresponds anatomically to peptide YY (PYY) as its mRNA is found in gut cells and in medial brainstem neurons. Its sequence is 60-70% identical to both PYY and NPY of mammals. These data suggest that the gene duplication leading to NPY and PYY had already occurred in the ancestral vertebrate 450 million years ago. The expression of the presumed PYY homolog in both gut and central nervous system indicates that PYY has served the dual role as a hormone and a neuropeptide from an early stage in vertebrate evolution. The similarities in the location of NPY- and PYY-expressing cells between lamprey and mammals suggest that the functions of these peptides may have been conserved.

Evolution of neuropeptide Y and its related peptides

1. The neuropeptide Y (NPY) family of peptides includes also the gut endocrine peptide YY (PYY), tetrapod pancreatic polypeptide (PP), and fish pancreatic peptide-tyrosine (PY). All peptides are 36 amino acids long. 2. Sequences from many types of vertebrates show that NPY has remained extremely well conserved throughout vertebrate evolution with 92% identity between mammals and cartilaginous fishes. 3. PYY has 97-100% identity between cartilaginous fishes and bony fishes, but is less conserved in amphibians and mammals (83% identity between amphibians and sharks and 75% identity between mammals and sharks). 4. NPY and PYY share 70-80% identity in most species. 5. Both NPY and PYY were present in the early vertebrate ancestor because both peptides have been found in lampreys. 6. The tissue distribution appears to have been largely conserved between phyla, except that PYY has more widespread neuronal expression in lower vertebrates. 7. Pancreatic polypeptide has diverged considerably among tetrapods leaving only 50% identity between mammals, birds/reptiles and frogs. 8. Several lines of evidence suggest that the PP gene arose by duplication of the PYY gene, probably in the early evolution of the tetrapods. 9. The pancreatic peptide PY found in anglerfish and daddy sculpin may have resulted from an independent duplication of the PYY gene. 10. The relationships of the recently described mollusc and worm peptides NPF and PYF with the NPY family still appear unclear.

Peptide YY in the mammalian pancreas: immunocytochemical localization and immunochemical characterization

Peptide YY (PYY) was demonstrated by immunochemical and/or immunocytochemical methods in endocrine cells in the pancreas of adult mice, rats, guinea-pigs, cats, dogs, pigs and cows. In the pancreas of mouse and rat, immunoreactive PYY was observed in a major subpopulation of the glucagon cells (splenic lobe of the pancreas); immunoreactive PYY also occurred in a subpopulation of the pancreatic polypeptide (PP) cells (duodenal lobe), and in a few extra-insular endocrine cells dispersed throughout the pancreatic parenchyma. In the pancreas of cat, dog and pig immunoreactive PYY was found to coexist with PP, but not with glucagon. Radioimmunoassay (RIA) revealed PYY-like material in extracts of pancreas (and colon) of all the species examined. The highest concentrations were found in the pancreas of cat and mouse; moderate amounts were found in the rat and only small amounts were detected in guinea-pig and pig. The concentrations in the pancreas were uniformly much lower than those in the colon. Analysis by high performance liquid chromatography (HPLC) showed that the PYY-immunoreactive material from pancreas (and rat colon) had an elution profile very similar to that of synthetic PYY, and distinct from that of PP and neuropeptide Y.

Pancreatic endocrine cells in sea bass (Dicentrarchus labrax L.) II. Immunocytochemical study of insulin and somatostatin peptides

Insulin (INS)- and somatostatin (SST)-immunoreactive cells were demonstrated by light immunocytochemistry in the endocrine pancreas of sea bass (Dicentrarchus labrax). INS-immunoreactive cells were identified using bovine/porcine, bonito, and salmon (s) INS antisera; the immunostaining was abolished when each antiserum was preabsorbed with its respective peptide but not with unrelated peptides. These cells also reacted with mammal (m) SST-28 (4-14) antiserum. The immunoreaction did not change when this antiserum was preabsorbed by bovine INS. INS-immunoreactive cells were located in the central part of the endocrine areas of the principal, intermediate, and small islets. Two SST-immunoreactive cell types (D1 and D2) were revealed. D1 cells, immunoreactive to SST 14 (562) and sSST-25 antisera, were located next to the glucagon-immunoreactive cells in the peripheral part of the endocrine areas. D2 cells, immunoreactive to SST-14 (562), SST-14 (566), and mSST-28 (4-14) antisera, were found in apposition to the INS-immunoreactive cells. The specificity controls showed that D1 cells expressed sSST-25-like peptides, while D2 cells might contain SST-14 and/or mSST-28-like peptides. The close topographic association between the different SST-immunoreactive cells and both glucagon- and insulin-immunoreactive cells might indicate the existence of a specific paracrine regulation of each endocrine cell type in the sea bass endocrine pancreas.

Pancreatic endocrine cells in sea bass (Dicentrarchus labrax L.) I. Immunocytochemical characterization of glucagon- and PP-related peptides

PP-, PYY-, and glucagon-immunoreactive cells were immunocytochemically identified in the pancreatic islets of Dicentrarchus labrax (sea bass). PYY cells also reacted with anti-PP serum. The specificity control showed that preabsorption of PP antiserum by PYY peptide abolished the immunostaining, while the reaction did not change when the PYY antiserum was preabsorbed by PP. These results suggested the existence of a PP/PYY molecule in the sea bass islets. The islet distribution of PP/PYY-immunoreactive cells differed markedly. Thus, in the principal islet and some intermediate islets few PP/PYY-immunoreactive cells are present (type I islets), whereas in the smaller and some intermediate ones they are numerous (type II islets). Adjacent sections stained by peroxidase-antiperoxidase (PAP) technique and individual sections stained by immunofluorescence double staining showed the coexistence of glucagon and PP/PYY-like immunoreactivities. Both islet types contained cells with PP/PYY coexisting with glucagon peptide, while cells showing solely glucagon immunoreactivity were found in type I islets only.

Salmon pancreatic polypeptide exhibits neuropeptide Y-like activities in rats

Salmon pancreatic polypeptide (sPP) is a 36 residue peptide amide isolated from salmon pancreas. It has 83% sequence identity with porcine neuropeptide Y (NPY). To confirm the sequence and obtain sufficient quantity of peptide for biological investigations, sPP was synthesized by automated t-Boc solid phase synthesis. The purified product had the expected amino acid composition, primary structure and mass, and was chemically and biologically indistinguishable from natural sPP. Investigation of its biological properties revealed that, like NPY, sPP increased blood pressure and decreased heart rate in anesthetized rats in a dose-dependent manner. There was no significant difference in the responses of NPY and sPP. Furthermore, administration of sPP directly into the hypothalamus of rats induced a feeding response comparable to that induced by NPY. Based on these investigations it may be suggested that synthetic and natural sPP are identical, and that sPP can express NPY-like activities in mammals presumably by interacting with the receptors of NPY.

Identification of two somatostatin-immunoreactive cell types in the principal islet of Sparus auratus L. (Teleostei) by immunogold staining

Two types of somatostatin (SST 14)-immunoreactive cells are identified by immunogold staining in the Lowicryl-embedded principal islet of Sparus auratus: D1 cells, having large moderate to low electron dense granules, located between A cells in the islet periphery and D2 cells, containing smaller electron-dense granules, present between B cells in the central region of the islet. Although SST 28-like immunoreactivity was not observed in D cells of S. auratus, the presence of SST 14 and a SST 22-,25-, or 28-like sequence in D2 and D1 cells, respectively, is discussed. A third SST 14-immunoreactive cell, found in the islet periphery, showed immunoreactive D1- and unreactive A-like granules. This cell type, which has a pyknotic-like nucleus and a dark appearance in osmicated Epon-embedded tissue, is supposed to be the product of fusion of D1 and A cells.

Centrally truncated and stabilized porcine neuropeptide Y analogs: design, synthesis, and mouse brain receptor binding

Porcine neuropeptide Y (pNPY) has been proposed to form an intramolecularly stabilized structure characterized by N- and C-terminal helical regions arranged antiparallel due to a central turn region. Analogs based on this structural model that have the central turn region and various amounts of the helical regions removed, yet retain the N and C termini in a similar spatial orientation were designed. The gap formed by removal of the central residues (residues 8-17 or 7-20) was spanned with a single 8-aminooctanoic acid residue (Aoc) and the structure was further stabilized by the introduction of a disulfide bridge. [D-Cys7,Aoc8-17,Cys20]pNPY and [Cys5,Aoc7-20,D-Cys24]pNPY were synthesized and found to have receptor binding affinities of 2.3 nM and 150 nM, respectively, in mouse brain membranes (pNPY affinity is 3.6 nM in this assay). It is proposed that the central region (residues 7-17) of pNPY serves a structural role in the peptide and is not involved in direct receptor interaction.

Somatostatin-related and glucagon-related peptides with unusual structural features from the European eel (Anguilla anguilla)

Peptides derived from prosomatostatins I and II and from two distinct proglucagons have been isolated from the pancreas of a teleost fish, the European eel (Anguilla anguilla). The product of prosomatostatin I processing, somatostatin-14, is identical to mammalian somatostatin-14. A 25-amino-acid-residue peptide (Ser-Val-Asp-Asn-Gln5-Gln-Gly-Arg-Glu-Arg10-Lys-Ala-Gly-Cys- Lys15-Asn-Phe-Tyr- Trp-Lys20-Gly-Pro-Thr-Ser-Cys25) is derived from prosomatostatin II. Compared with the corresponding peptides from other teleost fish, the eel somatostatin-25 contains the unusual substitution Pro for Phe at position 22. This peptide was also isolated in a form containing a hydroxylsyl residue at position 20. A 29-amino-acid-residue eel glucagon contains four substitutions relative to human glucagon Asn for Ser8, Glu for Asp15, Thr for Ser16, and Ser for Thr29). In common with mammalian and avian glucagons but unlike most other fish glucagons, the eel peptide possesses a glutamine residue at position 3. A peptide derived from a second proglucagon comprises 36 amino acid residues. A 7-residue C-terminal extension to the glucagon sequence shows structural similarity to the corresponding extension in ratfish (Hydrolagus colliei) glucagon and mammalian oxyntomodulin.

Isolation and sequence of rat peptide YY and neuropeptide Y

Rat peptide YY and rat neuropeptide Y have been isolated in parallel from colon and brain extracts respectively, using salt fractionation, gel filtration chromatography, cation-exchange HPLC, and reverse phase phenyl-silica HPLC. Immunoreactivity was identified using a combination of 3 NPY immunoassays which exhibit differing cross-reactivities for PYY (90%, less than 0.01% and 30% respectively). The yield at the final purification step was 1.2 nmol rPYY and 0.5 nmol rNPY. Half of each purified peptide was subjected to complete microsequence analysis. This showed that while rat NPY was structurally identical to human NPY, the sequence of PYY from rat colon was the same as porcine PYY isolated from extracts of duodenum.

Different cellular distributions of two somatostatins in brain and pancreas of salmonids, and their associations with insulin- and glucagon-secreting cells

Invariant somatostatin-14 (SST-14) and somatostatin-25 (SST-25), isolated from coho salmon pancreas (Plisetskaya et al., 1986a) are likely coded by two distinct somatostatin genes. The present study was undertaken to investigate whether these genes are expressed in the same or in different cell types in the pancreatic islets and in the brain of two salmonids: rainbow trout and coho salmon. Antibodies generated against SST-14, mammalian (m) SST-28(1-14), salmon (s) SST-25, salmon insulin, and salmon glucagon were used as immunocytochemical probes. Two distinct cell types containing SSTs were revealed in the pancreas of both salmonid species: one cell type immunoreactive to both SST-14 and mSST-28(1-14) and the other cell type immunoreactive only to sSST-25. The SST-14/mSST-28(1-14)-positive cells were limited to the more central parts of the islets, in apposition to the insulin-positive cells: sSST-25-positive cells were located more peripherally and were associated topographically with the glucagon-positive cells. In contrast to the pancreas, neurons in the neurohypophysis and hypothalamus of the rainbow trout and coho salmon contained only SST-14-like and mSST-28(1-14)-like immunoreactivities, while immunoreactivity to sSST-25 was completely absent. These results suggest that differentiation in the pancreas and brain of salmonid fishes results in cell types in which SST genes are separately expressed. The close topographical association of sSST-25 with glucagon cells, and of SST-14 with insulin cells, in the pancreatic islets implies yet unknown functional regulatory relationships that require detailed study.