Robert M. Dores

Evolution of POMC: origin, phylogeny, posttranslational processing, and the melanocortins

The proopiomelanocortin (POMC) gene was most likely derived from an ancestral opioid‐coding gene following the 1R chordate genome duplication event. During the radiation of the jawless fish, the POMC organization plan emerged multiple melanocortin sequences (α‐MSH/ACTH and β‐MSH) and a C‐terminally extended opioid sequence (β‐endorphin). Following the 2R genome duplication event, the γ‐MSH sequence was gained. Among the jawed vertebrates, three distinct trends in the evolution of the POMC gene are apparent: the gain of the δ‐MSH sequence (cartilaginous fish), the loss of the γ‐MSH sequence (ray‐finned fish), and the retention of the post 2R POMC organization plan (lobe‐finned fish/tetrapods). POMC is synthesized in the pituitary gland and in neurons of the hypothalamus, where an array of posttranslational processing mechanisms, such as endoproteolytic cleavage and N‐acetylation, generate distinct sets of end‐products in these tissues. A striking feature of the melanocortin end‐products is the rigorous conservation of the primary sequence of α‐MSH and the first 25 amino acids of ACTH.

Effects of environmental osmolality on release of prolactin, growth hormone and ACTH from the tilapia pituitary

Prolactin (PRL) plays a central role in freshwater (FW) adaptation in teleost fish. Evidence now suggests that growth hormone (GH) acts in the seawater (SW) adaptation in at least some euryhaline fish. Reflecting its important role in FW adaptation, plasma levels of PRL(188) and PRL(177) are higher in tilapia (Oreochromis mossambicus) adapted to FW than in those adapted to SW. A transient but significant increase in plasma GH was observed 6h after transfer from FW to SW. Elevated plasma PRL levels were seen in association with reductions in plasma osmolality after blood withdrawal in FW fish whereas no significant change was seen in plasma GH levels. When pituitaries from FW tilapia were incubated for 7 days, secretion of both PRLs was significantly greater in hyposmotic medium than in hyperosmotic medium for the first 24h. Secretion of GH from the same pituitary was relatively low during this period compared with PRL secretion. No consistent effect of medium osmolality on GH release was seen for the first day, but its cumulative release was increased significantly in hyperosmotic medium after 2 days and thereafter. On the other hand, ACTH release was extremely low compared with the secretion of PRLs and GH and there was no consistent effect of medium osmolality. These results indicate that PRL release from the tilapia pituitary is stimulated both in vivo and in vitro as extracellular osmolality is reduced, whereas the secretion of GH increases temporarily when osmolality is increased. ACTH seems to be relatively insensitive to the changes in environmental osmolality.

The molecular evolution of neuropeptides : prospects for the '90s

Three distinct opioid precursors have been identified in the central nervous system of mammals: proopiomelanocortin (POMC), proenkephalin, and prodynorphin. These precursors are derived from separate genes, synthesized in distinct neurons, and yield unique sets of opioid end products. This review will discuss the general mechanisms involved in the biosynthesis of neuropeptide precursors and consider the roles of posttranscriptional and posttranslational processing mechanisms in the generation of multiple sets of end products from a single gene. In addition, techniques that can be used for isolating and characterizing neuropeptide genes, mRNAs, and end products will be reviewed. These introductory comments will serve as the framework for a discussion of the phylogeny of the opioid precursors in the major groups of non-mammalian vertebrates.

Cloning of a second proopiomelanocortin cDNA from the pituitary of the sturgeon, Acipenser transmontanus.

A recent study on the pituitary of the sturgeon, Acipenser transmontanus, resulted in the cloning of a cDNA that codes for the prohormone, proopiomelanocortin (POMC). This cDNA is designated sturgeon POMC A. Subsequent analysis of the sturgeon pituitary uncovered a second distinct POMC cDNA (sturgeon POMC B). In both sturgeon POMC cDNAs the open reading frame is 795 nucleotides in length. However, the two sturgeon POMC cDNAs differ at 26 amino acid positions in the opening frame. In addition, the 2 forms of POMC differ at 45 nucleotide positions within the open reading frame. The number and types of point mutations are compared in the 2 sturgeons POMC cDNAs, and the origin of the two POMC genes is discussed.

Cloning of Proopiomelanocortin from the Brain of the African Lungfish, Protopterus annectens, and the Brain of the Western Spadefoot Toad, Spea multiplicatus

A degenerate primer, specific for the opioid core sequence YGGFM, was used to clone and sequence proopiomelanocortin (POMC) cDNAs from the brain of the African lungfish, Protopterus annectens, and from the brain of the western spadefoot toad, Spea multiplicatus. In addition, the opioid-specific primer was used to clone and sequence a 3′RACE product corresponding to a portion of the open reading frame of S. multiplicatus proenkephalin. For both species, cDNA was made from a single brain and a degenerate opioid-specific primer provided a reliable probe for detecting opioid-related cDNAs. The African lungfish POMC cDNA was 1,168 nucleotides in length, and contained regions that are similar to tetrapod POMCs and fish POMCs. The African lungfish POMC encodes a tetrapod-like γ-MSH sequence that is flanked by sets of paired basic amino acid proteolytic cleavage sites. The γ-MSH region in ray-finned fish POMCs either has degenerate cleavage sites or is totally absent in some species. However, the African lungfish γ-MSH sequence does contain a deletion which has not been observed in tetrapod γ-MSH sequences. The β-endorphin region of lungfish POMC has the di-amino acid sequence tryptophan-aspartic acid in the N-terminal region and an additional glutamic acid residue in the C-terminal region of β-endorphin – features found in fish β-endorphin, but not tetrapod β-endorphins. The western spadefoot toad POMC was 1,186 nucleotides in length, and exhibited an organizational scheme typical for tetrapod POMCs. However, the toad POMC did lack a paired basic amino acid proteolytic cleavage site N-terminal to the β-MSH sequence. Thus, like rat POMC, it is doubtful that β-MSH is an end product in either the toad brain or intermediate pituitary. At the amino acid level, the toad POMC had 76% sequence identity with Xenopus laevis POMC and 68% sequence identity with Rana ribidunda POMC. The use of these POMC sequences to assess phylogenetic relationships within anuran amphibians will be discussed. With respect to the fragment of S. multiplicatus proenkephalin cDNA, two metenkephalin sequences and the metenkephalin-RF sequence were found encoded in this fragment. As seen for X. laevis and R. ridibunda proenkephalin, a leuenkephalin sequence was not detected in the C-terminal region of the S. multiplicatus proenkephalin. The absence of a leuenkephalin sequence may be a common feature of anuran amphibian proenkephalins.

Differential Mechanisms for the N-Acetylation of Alpha-Melanocyte-Stimulating Hormone and Beta-Endorphin in the Intermediate Pituitary of the Frog, Xenopus laevis

Immunohistochemical analysis of the pituitary of Xenopus laevis revealed the colocalization of alpha-melanocyte-stimulating-hormone (MSH)-related immunoreactivity and N-acetyl-beta-endorphin-related immunoreactivity in the cells of the intermediate pituitary. In order to determine whether the immunoreactive N-acetylated beta-endorphin is released in parallel with the immunoreactive alpha-MSH, intermediate pituitaries were incubated in L-15 medium for 24 h. The medium and an acid extract of the intermediate pituitaries from each incubation were separately fractioned by a combination of gel filtration chromatography, reverse-phase high-performance liquid chromatography, and cation exchange chromatography. In the intermediate pituitary extract, the major form of alpha-MSH had chromatographic properties which corresponded to nonacetylated alpha-MSH (ACTH)(1-13)amide; whereas the major form of beta-endorphin had an apparent molecular weight of 1.2 kDa and was N-acetylated. The 1.2-kDa form of beta-endorphin and ACTH(1-13)amide were present in equimolar amounts. Analysis of the medium indicated that both end products were released in parallel. However, as reported in the literature, there was a significant increase in the N-acetylation of ACTH(1-13)amide during secretion. There was no further processing of beta-endorphin during secretion. Collectively, these observations indicate that in the intermediate pituitary of X. laevis there are separate mechanisms for the N-acetylation of alpha-MSH and beta-endorphin.

Cloning of a neoteleost (Oreochromis mossambicus) pro-opiomelanocortin (POMC) cDNA reveals a deletion of the γ-melanotropin region and most of the joining peptide region: implications for POMC processing☆☆

A signature feature of tetrapod pro-opiomelanocortin (POMC) is the presence of three melantropin (MSH) coding regions (alpha-MSH, beta-MSH, gamma-MSH). The MSH duplication events occurred early during the radiation of the jawed vertebrates well over 400 million years ago. However, in at least one order of modern bony fish (subdivision Teleostei; order Salmoniformes; i.e. salmon and trout) the gamma-MSH sequence has been deleted from POMC. To determine whether the gamma-MSH deletion has occurred in other teleost orders, a POMC cDNA was cloned from the pituitary of the neoteleost Oreochromis mossambicus (order Perciformes). In O. mossambicus POMC, the deletion is more extensive and includes the gamma-MSH sequence and most of the joining peptide region. Because the salmoniform and perciform teleosts do not share a direct common ancestor, the gamma-MSH deletion event must have occurred early in the evolution of the neoteleost fishes. The post-translational processing of O. mossambicus POMC occurs despite the fact that the proteolytic recognition sequence, (R/K)-Xn-(R/K) where n can be 0, 2, 4, or 6, a common feature in mammalian neuropeptide and polypeptide hormone precursors, is not present at several cleavage sites in O. mossambicus POMC. These observations would indicate that either the prohormone convertases in teleost fish use distinct recognition sequences or vertebrate prohormone convertases are capable of recognizing a greater number of primary sequence motifs around proteolytic cleavage sites.

A View of the N‐Acetylation of α‐Melanocyte‐Stimulating Hormone and β‐Endorphin from a Phylogenetic Perspectivea

Low molecular weight polypeptide hormones and neuropeptides are synthesized on larger precursor proteins that are biologically inert.’ These precursors must undergo a series of posttranslational proteolytic cleavage events in order to liberate the biologically interesting sequences that may be interspersed within the sequence of the precursor.2 The end products generated as a result of these proteolytic cleavage events may undergo a number of additional posttranslational modifications including a-amidation, sulfation, and phosphorylation.2 For example, several neuropeptides are C-terminally amidated.3 N-terminal acetylation, however, is a less common posttranslational processing event. Among secreted polypeptides, only a-melanocyte-stimulating hormone (a-MSH) and p-endo~hin, end products of the proopiomelanocortin (POMC) biosynthetic pathway, undergo this posttranslational m~dification.~ This review will focus on the phylogeny of the POMC-specific N-acetyltransferase mechanisms that occur in the vertebrate intermediate pituitary. A case will be made that there is an “ancestral” POMC N-acetylating mechanism that has generally persisted throughout vertebrate evolution. In addition, a novel modification of this “general” scheme that is observed in anuran amphibians will be discussed at length.

Catecholaminergic cells and fibers in the brain of the lizard Anolis carolinensis identified by traditional as well as whole-mount immunohistochemistry.

SummaryUsing traditional as well as whole-mount immunohistochemistry, we described the location of tyrosine hydroxylase-and dopamine beta hydroxylase-positive cells and fibers in the brain of the lizard Anolis carolinensis. Major catecholaminergic cell groups were in the ependyma in certain ventricular regions, alous coeruleus, anterior hypothalamic and lateral hypothalamic areas, and in the mesencephalic tegmental region, locus coeruleus, nucleus of the solitary tract, vagal motor nucleus, and rhombencephalic reticular formation. Major catecholaminergic fibers, tracts and varicosities included tuberohypophysial, mesolimbic, nigrostriatal, isthmocortical, medullohypothalamic, and coeruleospinal systems. Although the catecholaminergic systems in A. carolinensis are similar to those in the brains of other lizards studied, there are a few species differences. Our information about A. carolinensis will be used to help localize the hypothalamic asymmetry in catecholamine metabolism previously described in this lizard.

Molecular evolution of GPCRs: Melanocortin/melanocortin receptors.

The melanocortin receptors (MCRs) are a family of G protein-coupled receptors that are activated by melanocortin ligands derived from the proprotein, proopiomelanocortin (POMC). During the radiation of the gnathostomes, the five receptors have become functionally segregated (i.e. melanocortin 1 receptor (MC1R), pigmentation regulation; MC2R, glucocorticoid synthesis; MC3R and MC4R, energy homeostasis; and MC5R, exocrine gland physiology). A focus of this review is the role that ligand selectivity plays in the hypothalamus/pituitary/adrenal-interrenal (HPA-I) axis of teleosts and tetrapods as a result of the exclusive ligand selectivity of MC2R for the ligand ACTH. A second focal point of this review is the roles that the accessory proteins melanocortin 2 receptor accessory protein 1 (MRAP1) and MRAP2 are playing in, respectively, the HPA-I axis (MC2R) and the regulation of energy homeostasis by neurons in the hypothalamus (MC4R) of teleosts and tetrapods. In addition, observations are presented on trends in the ligand selectivity parameters of cartilaginous fish, teleost, and tetrapod MC1R, MC3R, MC4R, and MC5R paralogs, and the modeling of the HFRW motif of ACTH(1-24) when compared with α-MSH. The radiation of the MCRs during the evolution of the gnathostomes provides examples of how the physiology of endocrine and neuronal circuits can be shaped by ligand selectivity, the intersession of reverse agonists (agouti-related peptides (AGRPs)), and interactions with accessory proteins (MRAPs).