Ghrelin: a multifunctional hormone in non-mammalian vertebrates

In mammals, ghrelin is a non-amidated peptide hormone, existing in both acylated and non-acylated forms, produced mainly from the X/A or ghrelin cells present in the mucosal layer of the stomach. Ghrelin is a natural ligand of the growth hormone (GH) secretagogue-receptor (GHS-R), and functions primarily as a GH-releasing hormone and an orexigen, as well as having several other biological actions. Among non-mammalian vertebrates, amino acid sequence of ghrelin has been reported in two species of cartilaginous fish, seven species of teleosts, two species of amphibians, one species of reptile and six species of birds. The structure and functions of ghrelin are highly conserved among vertebrates. This review presents a concise overview of ghrelin biology in non-mammalian vertebrates.     

Recent advances in the phylogenetic study of ghrelin

To understand fully the biology of ghrelin, it is important to know the evolutionary history of ghrelin and its receptor. Phylogenetic and comparative genomic studies of mammalian and non-mammalian vertebrates are a useful approach to that end. Ghrelin is a hormone that has apparently evaded natural selection during a long evolutionary history. Surely ghrelin plays crucial physiological roles in living animals. Phylogenetic studies reveal the nature and evolutionary history of this important signaling system.     

Structure, distribution and physiological functions of ghrelin in fish

Ghrelin was originally purified and characterized in rats and humans as the first identified endogenous ligand of the growth hormone secretagogue receptor. In mammals, ghrelin is mainly produced in the stomach, with minor levels of ghrelin present in the brain and various other tissues. Ghrelin is involved in the regulation of many physiological functions including the regulation of growth hormone secretion and food intake in mammals. The gene and peptide structures of ghrelin have been recently identified in several fish species. As in mammals, ghrelin mRNA is mainly expressed in the gut of fish. Ghrelin is involved in the regulation of a number of physiological functions, including the regulation of pituitary hormone release and the stimulation of food intake in fish. In this review, we wish to provide an up-to-date discussion on the structure, distribution and functions of ghrelin in fish, in comparison to ghrelin in other vertebrates.     

Ghrelin- and growth hormone secretagogue receptor-immunoreactive cells in Xenopus pancreas

Ghrelin and its receptor, growth hormone secretagogue receptor (GHS-R), are produced by various cell types and affect feeding behavior, metabolic regulation, and energy balance. In the mammalian pancreas, the types of endocrine cells immunoreactive for ghrelin vary. Further, no study has clarified the type of endocrine cells producing ghrelin and GHS-R in the non-mammalian pancreas. We immunohistochemically investigated ghrelin-like and GHS-R-like immunoreactivities in the Xenopus pancreas. Ghrelin-immunoreactive cells were observed both in islets and extrainsular regions, and they corresponded to insulin-containing cells. GHS-R-immunoreactive cells were observed in the islets, and these immunoreactive cells corresponded to insulin- and somatostatin-containing cells. These observations suggest that ghrelin is co-secreted with insulin and that ghrelin may act in an autocrine fashion for insulin-containing cells and in a paracrine fashion for somatostatin-containing cells in this species.     

Evolutionary conservation of the structural, pharmacological, and genomic characteristics of the melanocortin receptor subtypes

We have cloned melanocortin receptors (MCRs) from several species of fish. The MC4R and MC5R subtypes arose early in vertebrate evolution and their primary structure is remarkably conserved. Expression and pharmacological characterization of the MCRs in fish has revealed that they bind and respond to melanocortin peptides with high potency. Detailed characterization of the binding properties of the different subtypes suggests that MCRs in early vertebrates had preference for adrenocorticotropic hormone (ACTH) peptides, while the high sensitivity for the shorter proopiomelanocortin (POMC) products, such as the alpha-, beta-, and gamma-melanocyte-stimulating hormone (MSH), has appeared later, perhaps as the MCR subtypes gained more specialized functions. The MCR repertoire shows in general high similarities in their primary structures, while they are however not similar in terms of functional roles. The MCRs serve therefore as an interesting model family to understand the molecular mechanisms of how functions of the genes can diverge during evolution. In this review, we provide an overview of our recent studies on the cloning, expression, pharmacology, 3D modeling, and genomic studies of the MCRs in non-mammalian species.     

Isolation, characterization and binding properties of two rat liver fatty acid-binding protein isoforms

Mammalian liver has only one fatty acid-binding protein (L-FABP) while the liver of non-mammalian vertebrates expresses a liver basic FABP (Lb-FABP) in addition to other members of the FABP family. We explore the possibility that L-FABP isoforms accomplish, in the liver of mammals, the metabolic functions corresponding to the different FABPs present in the liver of non-mammalian vertebrates. We have isolated isoforms I and II which have a different residue 105, Asn in the former and Asp in the latter. We made a conformational comparison of the apo-isoforms by intrinsic fluorescence emission and fourth-derivative spectroscopy, native-state proteolysis and unfolding curves. Ligand affinity was studied by measuring cis-parinaric acid displacement by different ligands. They have differences in their molecular conformation, including the environment of the binding site. Isoform II has probably a more open conformation than isoform I, thus allowing the binding of a greater variety of ligands. The affinity of isoform II for lysophospholipids, prostaglandins, retinoids, bilirubin and bile salts is greater than that of isoform I. These characteristics of rat L-FABP isoforms I and II suggest that they may accomplish different functions as happens with those of the different FABP types in non-mammalian species.     

大口黑鲈GHRH-LP和GHRH基因序列同源性、基因结构和时序表达研究

促生长激素释放激素(Growth hormone releasing hormone,GHRH)是生长激素释放调控的重要因子。过去人们一直将鱼类的促生长激素释放激素样多肽(Growth hormone releasing hormone like peptide,GHRH-LP)误认为是GHRH,直到最近才分离出GHRH基因。为了了解GHRH和GHRH-LP基因的结构特征及表达差异,研究克隆了大口黑鲈(Micropterus salmoides)GHRH和GHRH-LP基因,同时应用实时定量PCR技术研究了这两个基因的组织表达及发育时序表达情况。结果显示,大口黑鲈GHRH的成熟肽由27个氨基酸残基组成,GHRH-LP的成熟肽由44个氨基酸残基组成。两个基因均由5个外显子和4个内含子组成,但两者成熟肽编码区在外显子上的分布有明显不同。与其他脊椎动物比较,GHRH同源性为74%100%,而GHRH-LP同源性为41%96%,两者间具有一定的相似性(37%63%)。GHRH基因仅在前脑和延脑中表达,而GHRH-LP基因在中枢神经系统及外周组织中均有表达;在胚胎发育过程中GHRH在神经胚后期检测到表达,其表达水平在仔鱼出膜1d后显著提高,而GHRH-LP在囊胚期及后续发育过程中均检测到表达。基因结构、序列同源性及表达谱研究均表明,GHRH和GHRH-LP存在显著差异,应为具有不同功能的两个基因。       

Novel approaches for the study of vertebrate steroid hormone receptors

Steroid hormones are essential for the normal function of most organ systems in vertebrates. Reproductive activities in females and males, such as the differentiation, growth and maintenance of the reproductive system, require signaling by sex steroid hormones. Although extensively studied in mammals and a few fish and bird species, the evolution and molecular mechanisms associated with the nuclear steroid hormone receptors are still poorly understood in amphibians and reptiles. Given our interest in environmental signaling of sex determination as well as a major interest in environmental contaminants that can mimic steroid hormone signaling, we have established an approach to study the molecular function (ligand binding and trans-activation) of steroid hormone receptors cloned from reptiles. This approach involves molecular cloning and sequencing of steroid hormone receptors, phylogenic analysis and in vitro trans-activation assays using endogenous or exogenous ligands. Comparing the in vitro trans-activation induced by different ligands with receptors cloned from different species would develop additional functional relationships (classification) among steroid hormone receptors. This approach can provide insight into understanding why each species could have different responses to exogenous ligands. Further, we have developed a novel and less invasive approach to obtaining mRNA for molecular cloning and sequencing of steroid hormone receptors in reptiles and other non-mammalian species, using blood cells as a source of genetic material. For example, white blood cells (WBCs) and red blood cells (RBCs) of the American alligator both express steroid hormone receptors and have adequate amounts of mRNA for molecular cloning. This approach would allow us to analyze components of endocrine function of steroid hormones without sacrificing animals. Especially in endangered species, this approach could provide an understanding of endocrine functions, elucidate the phylogenic relationships of various receptors in vitro, such as the steroid hormone receptors, and determine possible effects of environmental contaminants in a minimally invasive manner.     

The structure of the nasal chemosensory system in squamate reptiles. 1. The olfactory organ,with special reference to olfaction in geckos

The luminal surface of the chemosensory epithelia of the main olfactory organ of terrestrial vertebrates is covered by a layer of fluid. The source of this fluid layer varies among vertebrates. Little is known regarding the relative development of the sources of fluid (sustentacular cells and Bowman's glands) in reptiles, especially in gekkotan lizards (despite recent assertions of olfactory speciality). This study examined the extent and morphology of the main olfactory organ in several Australian squamate reptiles, including three species of gekkotans, two species of skinks and one snake species. The olfactory mucosa of two gekkotan species (Christinus marmoratus and Strophurus intermedius) is spread over a large area of the nasal cavity. Additionally, the sustentacular cells of all three gekkotan species contained a comparatively reduced number of secretory granules, in relation to the skinks or snake examined. These observations imply that the gekkotan olfactory system may function differently from that of either skinks or snakes. Similar variation in secretory granule abundance was previously noted between mammalian and non-mammalian olfactory sustentacular cells. The observations in gekkotans suggests that the secretory capacity of the non-mammalian olfactory sustentacular cells show far more variation than initially thought.     

The discovery of ghrelin--a personal memory

The endogenous ligand for growth-hormone secretagogue receptor (GHS-R) was purified from the stomach and named it "ghrelin," after the word root "ghre" in Proto-Indo-European languages meaning "grow", since ghrelin has potent growth hormone (GH) releasing activity. Ghrelin plays important roles for maintaining growth hormone release and energy homeostasis in vertebrates. In this essay, I described my personal memory on the discovery of ghrelin in the year 1999.     

Ghrelin can bind to a species of high density lipoprotein associated with paraoxonase

Ghrelin is a 28-residue peptide hormone that is principally released from the stomach during fasting and prior to eating. Two forms are present in human plasma: the unmodified peptide and a less abundant acylated version, in which octanoic acid is attached to the third residue, a serine, via an ester linkage. The acylated form of ghrelin acts as a ligand for the growth hormone secretagogue receptor and can stimulate the release of growth hormone from the pituitary gland. It also initiates behavioral and metabolic adaptations to fasting. Here we show that an immobilized form of ghrelin specifically binds a species of high density lipoprotein associated with the plasma esterase, paraoxonase, and clusterin. Both free ghrelin and paraoxon, a substrate for paraoxonase, can inhibit this interaction. An endogenous species of ghrelin is found to co-purify with high density lipoprotein during density gradient centrifugation and subsequent gel filtration. This interaction links the orexigenic peptide hormone ghrelin to lipid transport and metabolism. Furthermore, the interaction of the esterified hormone ghrelin with a species of HDL containing an esterase suggests a possible mechanism for the conversion of ghrelin to des-acyl ghrelin.     

Diversification and coevolution of the ghrelin/growth hormone secretagogue receptor system in vertebrates

The gut hormone ghrelin is involved in numerous metabolic functions, such as the stimulation of growth hormone secretion, gastric motility, and food intake. Ghrelin is modified by ghrelin O‐acyltransferase (GOAT) or membrane‐bound O‐acyltransferase domain‐containing 4 (MBOAT4) enabling action through the growth hormone secretagogue receptors (GHS‐R). During the course of evolution, initially strong ligand/receptor specificities can be disrupted by genomic changes, potentially modifying physiological roles of the ligand/receptor system. Here, we investigated the coevolution of ghrelin, GOAT, and GHS‐R in vertebrates. We combined similarity search, conserved synteny analyses, phylogenetic reconstructions, and protein structure comparisons to reconstruct the evolutionary history of the ghrelin system. Ghrelin remained a single‐gene locus in all vertebrate species, and accordingly, a single GHS‐R isoform was identified in all tetrapods. Similar patterns of the nonsynonymous (dN) and synonymous (dS) ratio (dN/dS) in the vertebrate lineage strongly suggest coevolution of the ghrelin and GHS‐R genes, supporting specific functional interactions and common physiological pathways. The selection profiles do not allow confirmation as to whether ghrelin binds specifically to GOAT, but the ghrelin dN/dS patterns are more similar to those of GOAT compared to MBOAT1 and MBOAT2 isoforms. Four GHS‐R isoforms were identified in teleost genomes. This diversification of GHS‐R resulted from successive rounds of duplications, some of which remained specific to the teleost lineage. Coevolution signals are lost in teleosts, presumably due to the diversification of GHS‐R but not the ghrelin gene. The identification of the GHS‐R diversity in teleosts provides a molecular basis for comparative studies on ghrelin's physiological roles and regulation, while the comparative sequence and structure analyses will assist translational medicine to determine structure–function relationships of the ghrelin/GHS‐R system.     

Unique roles of glucagon and glucagon-like peptides: Parallels in understanding the functions of adipokinetic hormones in stress responses in insects

Glucagon is conventionally regarded as a hormone, counter regulatory in function to insulin and plays a critical anti-hypoglycemic role by maintaining glucose homeostasis in both animals and humans. Glucagon performs this function by increasing hepatic glucose output to the blood by stimulating glycogenolysis and gluconeogenesis in response to starvation. Additionally it plays a homeostatic role by decreasing glycogenesis and glycolysis in tandem to try and maintain optimal glucose levels. To perform this action, it also increases energy expenditure which is contrary to what one would expect and has actions which are unique and not entirely in agreement with its role in protection from hypoglycemia. Interestingly, glucagon-like peptides (GLP-1 and GLP-2) from the major fragment of proglucagon (in non-mammalian vertebrates, as well as in mammals) may also modulate response to stress in addition to their other physiological actions. These unique modes of action occur in response to psychological, metabolic and other stress situations and mirror the role of adipokinetic hormones (AKHs) in insects which perform a similar function. The findings on the anti-stress roles of glucagon and glucagon-like peptides in mammalian and non-mammalian vertebrates may throw light on the multiple stress responsive mechanisms which operate in a concerted manner under regulation by AKH in insects thus functioning as a stress responsive hormone while also maintaining organismal homeostasis.     

Cooperativity and allosteric regulation in non-mammalian vertebrate haemoglobins.

1. This review illustrates the vast range of molecular functions expressed in non-mammalian vertebrate haemoglobins; with particular reference to the degree of aggregation of haemoglobin subunits and their interactions with allosteric effectors. 2. In at least the broadest sense, these properties suggest that haemoglobin function in non-mammalian vertebrates can be viewed against the evolutionary hierarchy of organisms rather than from a purely adaptive perspective.     

Distribution patterns of neurotensin-like immunoreactive cells in the gastro-intestinal tract of higher vertebrates

Summary The endocrine system of the gastro-intestinal tract of selected species representing the five higher vertebrate classes was investigated with reference to occurrence and distribution of neurotensin-like immunoreactive cells. Using antibodies against C-terminal and N-terminal fragments of neurotensin and against the C-terminal sequence of xenopsin it was demonstrated that the intestine of all species studied contains endocrine, neurotensin-like immunoreactive cells. However, large differences in localization and frequency of these neurotensin-like immunoreactive cells were found. Except for a teleostean fish, neurotensin-like immunoreactive cells in the gastro-intestinal tract were more frequent in non-mammalian vertebrates than in mammals. In contrast to mammals, where the highest density of neurotensin-like immunoreactive cells was present in the ileal mucosa, in the non-mammalian vertebrates studied the corresponding cells were most abundant in the pyloric-duodenal junction. The exact mapping of neurotensin-like immunoreactive cells is presented throughout the entire gastro-intestinal tract of six species (Rattus, Coturnix, Lacerta, Rana, Xenopus, Carassius) including a quantitative evaluation of sequential serial sections.     

Distribution of plasma magnesium in various vertebrates

Plasma magnesium in at least five mammalian species (humans, rat, dog, sheep, cattle) is in the form of a complex, separable from ionic magnesium and plasma protein by size exclusion chromatography on Sephadex G-10. Plasma magnesium in three non-mammalian vertebrates (toads, trout, chicken) behaves similarly to ionic magnesium or as a very small magnesium complex on Sephadex G-10.     

Adult neurogenesis in non-mammalian vertebrates

Adult neurogenesis is an exciting and rapidly advancing field of research. It addresses basic biological questions, such as the how and why of de novo neuronal production during adulthood, as well as medically relevant issues, including the potential link between adult neural stem cells and psychiatric disorders, or how stem cell manipulation might be used as a strategy for neuronal replacement. Current research mainly focuses on rodents, but we review here recent examination of non-mammalian vertebrates, which demonstrates that bona fide adult neural stem cells exist in these species. Importantly, especially in teleost fish, these cells can be abundant and located in various brain areas. Hence, non-mammalian vertebrate species provide invaluable comparative material for extracting core mechanisms of adult neural stem cell maintenance and fate.     

Medaka dmY/dmrt1Y is not the universal primary sex-determining gene in fish

An outstanding candidate for a primary male-determining gene equivalent to Sry of mammals has been recently described from a non-mammalian vertebrate, the medaka fish (Oryzias latipes). However, the universality of dmY/dmrt1Y as the master sex-determining gene in fish is questionable. Phylogenetic analysis shows that dmY/dmrt1Y is an evolutionarily young Y chromosome-specific duplicate of a gene involved in testis development in vertebrates, and that this duplicate cannot be the primary sex-determining gene in most other fish species. Study of alternative fish models will probably uncover new genetic strategies controlling sexual dimorphism in vertebrates.