Evolutionary implication of the absence of atrial natriuretic peptide (ANP) in euryhaline Oryzias fishes

The genus Oryzias contains nearly 20 species, including the Japanese medaka (Oryzias latipes). Because each species exhibits different adaptability to environmental salinity, Oryzias fishes offer unique opportunities for comparative studies. To understand the mechanisms of osmotic adaptation, we are studying the functional evolution of the natriuretic peptide (NP) family??a group of small peptide hormones involved in body fluid regulation??by using Oryzias fishes. Analysis of the Japanese medaka genome revealed that 7 NP subtypes, namely, Atrial NP (ANP), B-type NP (BNP), Ventricular NP (VNP), and 4?C-type NPs (CNP-1 through CNP-4) were generated from a CNP-4-like ancestral gene discovered in the cyclostomes before the ray-finned fish/lobe-finned fish divergence. This evolutionary history has been confirmed by the discovery of hidden NP genes in tetrapods. Through analyses of phylogenetic distribution of NP subtypes, we also found that specific losses of subtypes have occurred in each vertebrate lineage. For example, ANP is absent in the Japanese and Indian medaka and the flying fish, suggesting that loss of the ANP gene occurred after the divergence of Beloniformes from Cyprinodontiformes. This fact also supports the inclusion of Oryzias into Beloniformes as suggested by phylogenetic analysis using whole mitochondrial genome sequences. How Oryzias fishes have retained their euryhalinity with a reduced number of NPs is an interesting question. CNP-3, which is functionally flexible, may be a substitute for the lost cardiac NPs.     

Does the natriuretic peptide system exist throughout the animal and plant kingdom?

Natriuretic peptides (NPs) and their receptors have been identified in vertebrate species ranging from elasmobranchs to mammals. Atrial, brain and ventricular NP (ANP, BNP and VNP) are endocrine hormones secreted from the heart, while C-type NP (CNP) is principally a paracrine factor in the brain and periphery. In elasmobranchs, only CNP is present in the heart and brain and it functions as a circulating hormone as well as a paracrine factor. Four types of NP receptors are cloned in vertebrates. NPR-A and NPR-B are guanylyl cyclase-coupled receptors, whereas NPR-C and NPR-D have only a short cytoplasmic domain. NPs are hormones important for volume regulation in mammals, while they act more specifically for Na(+) regulation in fishes. The presence of NP and its receptor has also been suggested in the most primitive vertebrate group, cyclostomes, and its molecular identification is in progress. The presence of ANP or its mRNA has been reported in the hearts and ganglia of various invertebrate species such as mollusks and arthropods using either antisera raised against mammalian ANP or rat ANP cDNA as probes. Immunoreactive ANP has also been detected in the unicellular Paramecium and in various species of plants including Metasequoia. Furthermore, the N-terminal prosegments of ANP, whose sequences are scarcely conserved even in vertebrates, have also been detected by the radioimmunoassay for human ANP prosegments in all invertebrate and plant species examined including Paramecium. Although these data are highly attractive, the current evidence is too circumstantial to be convincing that the immunoreactivity truly originates from ANP and its prosegments in such diverse organisms. The caution that has to be exercised in identification of vertebrate hormones from phylogenetically distant organisms is discussed.     

Diverse forms of guanylyl cyclases in medaka fish -- their genomic structure and phylogenetic relationships to those in vertebrates and invertebrates

Fish species such as medaka fish, fugu, and zebrafish contain more guanylyl cyclases (GCs) than do mammals. These GCs can be divided into two types: soluble GCs and membrane GCs. The latter are further divided into four subfamilies: (i) natriuretic peptide receptors, (ii) STa/guanylin receptors, (iii) sensory-organ-specific membrane GCs, and (iv) orphan receptors. Phylogenetic analyses of medaka fish GCs, along with those of fugu and zebrafish, suggest that medaka fish is a much closer relative to fugu than to zebrafish. Analyses of nucleotide data available on a web site (http://www.ncbi. nlm.nih.gov/) of GCs from a range of organisms from bacteria to vertebrates suggest that gene duplication, and possibly chromosomal duplication, play important roles in the divergence of GCs. In particular, the membrane GC genes were generated by chromosomal duplication before the divergence of tetrapods and teleosts.     

Relative antidipsogenic potencies of six homologous natriuretic peptides in eels

Atrial natriuretic peptide (ANP) exhibits a potent antidipsogenic effect in seawater (SW) eels to limit excess Na(+) uptake, thereby effectively promoting SW adaptation. Recently, cardiac ANP, BNP and VNP and brain CNP1, 3 and 4, have been identified in eels. We examined the antidipsogenic effect of all homologous NPs using conscious, cannulated eels in both FW and SW together with parameters that affect drinking. A dose-response study (0.01-1 nmol/kg) in SW eels showed the relative potency of the antidipsogenic effect was in the order ANP ≥ VNP > BNP = CNP3 > CNP1 ≥ CNP4, while the order was ANP = VNP = BNP > CNP3 = CNP1 = CNP4 for the vasodepressor effect. The minimum effective dose of ANP for the antidipsogenic effect is much lower than that in mammals. ANP, BNP and VNP at 0.3 nmol/kg decreased drinking, plasma Na(+) concentration and aortic pressure and increased hematocrit in SW eels. The cardiac NPs induced similar changes in drinking, aortic pressure and hematocrit in FW eels, but aside from BNP no change in plasma Na(+) concentration. CNPs had no effect on drinking, plasma Na(+) concentration and hematocrit but induced mild hypotension in both FW and SW eels, except for CNP3 that inhibited drinking in SW eels. These results show that ANP, BNP and VNP are potent antidipsogenic hormones in eels in spite of other regulatory factors working to induce drinking, and that CNPs are without effects on drinking except for the ancestor of the cardiac NPs, CNP3.     

Gene duplications and losses within the cyclooxygenase family of teleosts and other chordates

Cyclooxygenase (COX) produces prostaglandins in animals via the oxidation and reduction of arachidonic acid. Different types and numbers of COX genes have been found in corals, sea squirts, fishes, and tetrapods, but no study has used a comparative phylogenetic approach to investigate the evolutionary history of this complex gene family. Therefore, to examine COX evolution in the teleosts and chordates, 9 novel COX sequences (possessing residues and domains critical to COX function) were acquired from the euryhaline killifish, longhorn sculpin, sea lamprey, Atlantic hagfish, and amphioxus using standard polymerase chain reaction (PCR) and cloning methods. Phylogenetic analyses of these and other COX sequences show a complicated history of COX duplications and losses. There are three main lineages of COX in the chordates corresponding to the three subphyla in the phylum Chordata, with each lineage representing an independent COX duplication. Hagfish and lamprey most likely have traditional COX-1/2 genes, suggesting that these genes originated with the first round of genome duplication in the vertebrates according to the 2R hypothesis and are not exclusively present in the gnathostomes. All teleosts examined have three COX genes due to a teleost-specific genome duplication followed by variable loss of a COX-1 (in the zebrafish and rainbow trout) or COX-2 gene (in the derived teleosts). Future studies should examine the functional ramifications of these differential gene losses.     

Teleost fish with specific genome duplication as unique models of vertebrate evolution

Whole-genome duplication (WGD) is believed to be one of the major evolutionary events that shaped the genome organization of vertebrates. Here, we review recent research on vertebrate genome evolution, specifically on WGD and its consequences for gene and genome evolution in teleost fishes. Recent genome analyses confirmed that all vertebrates experienced two rounds of WGD early in their evolution, and that teleosts experienced a subsequent additional third-round (3R)-WGD. The 3R-WGD was estimated to have occurred 320–400 million years ago in a teleost ancestor, but after its divergence from a common ancestor with living non-teleost actinopterygians (Bichir, Sturgeon, Bowfin, and Gar) based on the analyses of teleost-specific duplicate genes. This 3R-WGD was confirmed by synteny analysis and ancestral karyotype inference using the genome sequences of Tetraodon and medaka. Most of the tetrapods, on the other hand, have not experienced an additional WGD; however, they have experienced repeated chromosomal rearrangements throughout the whole genome. Therefore, different types of chromosomal events have characterized the genomes of teleosts and tetrapods, respectively. The 3R-WGD is useful to investigate the consequences of WGD because it is an evolutionarily recent WGD and thus teleost genomes retain many more WGD-derived duplicates and “traces” of their evolution. In addition, the remarkable morphological, physiological, and ecological diversity of teleosts may facilitate understanding of macrophenotypic evolution on the basis of genetic/genomic information. We highlight the teleosts with 3R-WGD as unique models for future studies on ecology and evolution taking advantage of emerging genomics technologies and systems biology environments.     

Structural characterization of GnRH loci in the medaka genome

To help clarify the origin of a third gonadotropin-releasing hormone (GnRH) paralog found only in the teleost lineage, we have characterized GnRH loci in a teleost species, the medaka Oryzias latipes, and compared corresponding regions of the medaka and human genomes. Three GnRHs for medaka-type GnRH (mdGnRH), chicken-II-type GnRH (cGnRH-II), and salmon-type GnRH (sGnRH) exist as single-copy genes and reside on separate chromosomes in the medaka genome. Both medaka mdGnRH and human mGnRH are closely linked to FLJ20038 encoding a hypothetical protein, and both cGnRH-IIs in the medaka and humans are adjacent to PTP(alpha) for protein tyrosine phosphatase alpha. These conserved syntenies demonstrate that mdGnRH and cGnRH-II in teleosts are orthologous to mGnRH and cGnRH-II in tetrapods, respectively. On the other hand, the third paralogous GnRH in the medaka, sGnRH, is adjacent to PTP(epsilon), a paralog of PTP(alpha). Although humans possess PTP(epsilon) on 10q26, no sGnRH-like sequence was found in the human genome databases. Therefore a gene duplication that gave rise to the third paralogous GnRH likely occurred before the divergence of teleosts and tetrapods, and it has been lost only in the tetrapod lineage. Additionally, together with the prior observations that like GnRH, PTP(alpha)/PTP(epsilon) are strongly expressed in neural and tumor cells and that GnRH can increase PTP activity, the current data suggests that the physically linked cGnRH-II/sGnRH and PTP(alpha)/PTP(epsilon) are also functionally linked.     

Phylogenetic Timing of the Fish-Specific Genome Duplication Correlates with the Diversification of Teleost Fish

For many genes, ray-finned fish (Actinopterygii) have two paralogous copies, where only one ortholog is present in tetrapods. The discovery of an additional, almost-complete set of Hox clusters in teleosts (zebrafish, pufferfish, medaka, and cichlid) but not in basal actinopterygian lineages (Polypterus) led to the formulation of the fish-specific genome duplication hypothesis. The phylogenetic timing of this genome duplication during the evolution of ray-finned fish is unknown, since only a few species of basal fish lineages have been investigated so far. In this study, three nuclear genes (fzd8, sox11, tyrosinase) were sequenced from sturgeons (Acipenseriformes), gars (Semionotiformes), bony tongues (Osteoglossomorpha), and a tenpounder (Elopomorpha). For these three genes, two copies have been described previously teleosts (e.g., zebrafish, pufferfish), but only one orthologous copy is found in tetrapods. Individual gene trees for these three genes and a concatenated dataset support the hypothesis that the fish-specific genome duplication event took place after the split of the Acipenseriformes and the Semionotiformes from the lineage leading to teleost fish but before the divergence of Osteoglossiformes. If these three genes were duplicated during the proposed fish-specific genome duplication event, then this event separates the species-poor early-branching lineages from the species-rich teleost lineage. The additional number of genes resulting from this event might have facilitated the evolutionary radiation and the phenotypic diversification of the teleost fish.[Reviewing Editor: Martin Kreitman]     

Consequences of hoxb1 duplication in teleost fish

Vertebrate evolution is characterized by gene and genome duplication events. There is strong evidence that a whole-genome duplication occurred in the lineage leading to the teleost fishes. We have focused on the teleost hoxb1 duplicate genes as a paradigm to investigate the consequences of gene duplication. Previous analysis of the duplicated zebrafish hoxb1 genes suggested they have subfunctionalized. The combined expression pattern of the two zebrafish hoxb1 genes recapitulates the expression pattern of the single Hoxb1 gene of tetrapods, possibly due to degenerative changes in complementary cis-regulatory elements of the duplicates. Here we have tested the hypothesis that all teleost duplicates had a similar fate post duplication, by examining hoxb1 genes in medaka and striped bass. Consistent with this theory, we found that the ancestral Hoxb1 expression pattern is subdivided between duplicate genes in a largely similar fashion in zebrafish, medaka, and striped bass. Further, our analysis of hoxb1 genes reveals that sequence changes in cis-regulatory regions may underlie subfunctionalization in all teleosts, although the specific changes vary between species. It was previously shown that zebrafish hoxb1 duplicates have also evolved different functional capacities. We used misexpression to compare the functions of hoxb1 duplicates from zebrafish, medaka and striped bass. Unexpectedly, we found that some biochemical properties, which were paralog specific in zebrafish, are conserved in both duplicates of other species. This work suggests that the fate of duplicate genes varies across the teleost group.     

Comparative genome mapping reveals evidence of gene conversion between Sox9 paralogs of rainbow trout (Oncorhynchus mykiss)

Considerable evidence suggests that one genome duplication event preceded the divergence of teleost fishes and a second genome duplication event occurred before the radiation of teleosts of the family Salmonidae. Two Sox9 genes have been isolated from a number of teleosts and are called Sox9a and Sox9b. Two Sox9 gene copies have also been isolated from rainbow trout, a salmonid fish and are called Sox9 and Sox9α2. Previous evaluations of the evolutionary history of rainbow trout Sox9 gene copies using phylogenetic reconstructions of their coding regions indicated that they both belong to the Sox9b clade. In this study, we determine the true evolutionary history of Sox9 gene copies in rainbow trout. We show that the locus referred to as Sox9 in rainbow trout is itself duplicated. Mapping of the duplicated Sox9 gene copies indicates that they are co-orthologs of Sox9b while mapping of Sox9α2 indicates that it is an ortholog of Sox9a. This relationship is supported by phylogenetic reconstruction of Sox9 gene copies in teleosts using their 3′ untranslated regions. The conflicting phylogenetic topology of Sox9 genes in rainbow trout indicates the occurrence of gene conversion events between Sox9 and Sox9α2 which is supported by a number of recombination analyses.     

Evolution of trace amine associated receptor (TAAR) gene family in vertebrates: lineage-specific expansions and degradations of a second class of vertebrate chemosensory receptors expressed in the olfactory epithelium

The trace amine-associated receptors (TAARs) form a specific family of G protein-coupled receptors in vertebrates. TAARs were initially considered neurotransmitter receptors, but recent study showed that mouse TAARs function as chemosensory receptors in the olfactory epithelium. To clarify the evolutionary dynamics of the TAAR gene family in vertebrates, near-complete repertoires of TAAR genes and pseudogenes were identified from the genomic assemblies of 4 teleost fishes (zebrafish, fugu, stickleback, and medaka), western clawed frogs, chickens, 3 mammals (humans, mice, and opossum), and sea lampreys. Database searches revealed that fishes had many putatively functional TAAR genes (13-109 genes), whereas relatively small numbers of TAAR genes (3-22 genes) were identified in tetrapods. Phylogenetic analysis of these genes indicated that the TAAR gene family was subdivided into 5 subfamilies that diverged before the divergence of ray-finned fishes and tetrapods. In tetrapods, virtually all TAAR genes were located in 1 specific region of their genomes as a gene cluster; however, in fishes, TAAR genes were scattered throughout more than 2 genomic locations. This possibly reflects a whole-genome duplication that occurred in the common ancestor of ray-finned fishes. Expression analysis of zebrafish and stickleback TAAR genes revealed that many TAARs in these fishes were expressed in the olfactory organ, suggesting the relatively high importance of TAARs as chemosensory receptors in fishes. A possible evolutionary history of the vertebrate TAAR gene family was inferred from the phylogenetic and comparative genomic analyses.     

The evolution of teleost pigmentation and the fish‐specific genome duplication

Teleost fishes have evolved a unique complexity and diversity of pigmentation and colour patterning that is unmatched among vertebrates. Teleost colouration is mediated by five different major types of neural‐crest derived pigment cells, while tetrapods have a smaller repertoire of such chromatophores. The genetic basis of teleost colouration has been mainly uncovered by the cloning of pigmentation genes in mutants of zebrafish Danio rerio and medaka Oryzias latipes. Many of these teleost pigmentation genes were already known as key players in mammalian pigmentation, suggesting partial conservation of the corresponding developmental programme among vertebrates. Strikingly, teleost fishes have additional copies of many pigmentation genes compared with tetrapods, mainly as a result of a whole‐genome duplication that occurred 320–350 million years ago at the base of the teleost lineage, the so‐called fish‐specific genome duplication. Furthermore, teleosts have retained several duplicated pigmentation genes from earlier rounds of genome duplication in the vertebrate lineage, which were lost in other vertebrate groups. It was hypothesized that divergent evolution of such duplicated genes may have played an important role in pigmentation diversity and complexity in teleost fishes, which therefore not only provide important insights into the evolution of the vertebrate pigmentary system but also allow us to study the significance of genome duplications for vertebrate biodiversity.     

Duplication of phospholipase C-delta gene family in fish genomes

Fishes possess more genes than other vertebrates, possibly because of a genome duplication event during the evolution of the teleost (ray-finned) fish lineage. To further explore this idea, we cloned five genes encoding phosphoinositide-specific phospholipase C-delta (PLC-delta), designated respectively PoPLC-deltas, from olive flounder (Paralichthys olivaceus), and we performed phylogenetic analysis and sequence comparison to compare our putative gene products (PoPLC-deltas) with the sequences of known human PLC isoforms. The deduced amino acid sequences shared high sequence identity with human PLC-delta1, -delta3, and -delta4 isozymes and exhibited similar primary structures. In phylogenetic analysis of PoPLC-deltas with PLC-deltas of five teleost fishes (zebrafish, stickleback, medaka, Tetraodon, and Takifugu), three tetrapods (human, chicken, and frog), and two tunicates (sea squirt and pacific sea squirt), whose putative sequences of PLC-delta are available in Ensembl genome browser, the result also indicated that the two paralogous genes corresponding to each PLC-delta isoform originated from fish-specific genome duplication prior to the divergence of teleost fish. Our analyses suggest that an ancestral PLC-delta gene underwent three rounds of genome duplication during the evolution of vertebrates, leading to the six genes of three PLC-delta isoforms in teleost fish.     

Asymmetric evolution in two fish-specifically duplicated receptor tyrosine kinase paralogons involved in teleost coloration

The occurrence of a fish-specific genome duplication (FSGD) in the lineage leading to teleost fishes is widely accepted, but the consequences of this event remain elusive. Teleosts, and the cichlid fishes from the species flocks in the East African Great Lakes in particular, evolved a unique complexity and diversity of body coloration and color patterning. Several genes involved in pigment cell development have been retained in duplicate copies in the teleost genome after the FSGD. Here we investigate the evolutionary fate of one of these genes, the type III receptor tyrosine kinase (RTK) colony-stimulating factor 1 receptor (csf1r). We isolated and shotgun sequenced two paralogous csf1r genes from a bacterial artificial chromosome library of the cichlid fish Astatotilapia burtoni that are both linked to paralogs of the pdgfr beta gene, another type III RTK. Two pdgfr beta-csf1r paralogons were also identified in the genomes of pufferfishes and medaka, and our phylogenetic analyses suggest that the pdgfr beta-csf1r locus was duplicated during the course of the FSGD. Comparisons of teleosts and tetrapods suggest asymmetrical divergence at different levels of genomic organization between the teleost-specific pdgfr beta-csf1r paralogons, which seem to have evolved as coevolutionary units. The high-evolutionary rate in the teleost B-paralogon, consisting of csf1rb and pdgfr betab, further suggests neofunctionalization by functional divergence of the extracellular, ligand-binding region of these cell-surface receptors. Finally, we hypothesize that genome duplications and the associated expansion of the RTK family might be causally linked to the evolution of coloration in vertebrates and teleost fishes in particular.     

Evolution of sarcomeric myosin heavy chain genes: evidence from fish

Myosin heavy chain (MYH) is a major structural protein, integral to the function of sarcomeric muscles. We investigated both exon-intron organization and amino acid sequence of sarcomeric MYH genes to infer their evolutionary history in vertebrates. Our results were consistent with the hypothesis that a multigene family encoded MYH proteins in the ancestral chordate, one gene ancestral to human MYH16 and its homologues and another ancestral to all other vertebrate sarcomeric MYH genes. We identified teleost homologues of mammalian skeletal and cardiac MYH genes, indicating that the ancestors of those genes were present before the divergence of actinopterygians and sarcopterygians. Indeed, the ancestral skeletal genes probably duplicated at least once before the divergence of teleosts and tetrapods. Fish homologues of mammalian skeletal MYH are expressed in skeletal tissue and homologues of mammalian cardiac genes are expressed in the heart but, unlike mammals, there is overlap between these expression domains. Our analyses inferred two other ancestral vertebrate MYH genes, giving rise to human MYH14 and MYH15 and their homologues. Relative to the skeletal and cardiac genes, MYH14 and MYH15 homologues are characterized by evolution of intron position, differences in evolutionary rate between the functionally differentiated head and rod of the myosin protein, and possible evolution of function among vertebrate classes. Tandem duplication and gene conversion appear to have played major roles in the evolution of at least cardiac and skeletal MYH genes in fish. One outcome of this high level of concerted evolution is that different fish taxa have different suites of MYH genes, i.e., true orthologs do not exist.     

Evolution of Hox Clusters in Salmonidae: A Comparative Analysis Between Atlantic Salmon (Salmo salar) and Rainbow Trout (Oncorhynchus mykiss)

We studied the genomic organization of Hox genes in Atlantic salmon (Salmo salar) and made comparisons to that in rainbow trout (Oncorhynchus mykiss), another member of the family Salmonidae. We used these two species to test the hypothesis that the Hox genes would provide evidence for a fourth round of duplication (4R) of this gene family given the recent polyploid ancestry of the salmonid fish. Thirteen putative Hox clusters were identified and 10 of these complexes were localized to the current Atlantic salmon genetic map. Syntenic regions with the rainbow trout linkage map were detected and further homologies and homeologies are suggested. We propose that the common ancestor of Atlantic salmon and rainbow trout possessed at least 14 clusters of Hox genes, and additional clusters cannot be ruled out. Salmonid Hox cluster complements seem to be more similar to those of zebrafish (Danio rerio) than medaka (Oryzias latipes) or pufferfish (Sphoeroides nephelus and Takifugu rubripes), as both Atlantic salmon and rainbow trout have retained HoxCb ortholog, which has been lost in medaka and pufferfish but not in zebrafish. However, our data suggest that phylogenetically, the homologous genes within each cluster express mosaic relationships among the teleosts tested and, thus, leave unresolved the interfamilial relationships among these taxa. Sequence data from this article have been deposited within the EMBL/GenBank Data Libraries under the following accession numbers: AY677341, AY677342, AY677343, AY677344, AY677345, AY677346, AY677347, AY677348, AY677349, AY677350, AY677351, AY677352, AY677353, AY677354, AY677355, AY677356, AY677357, AY677358, AY677359, AY677360, AY677361, AY677362, AY677363, AY677364 and AY677365. [Reviewing Editor: Dr. Axel Meyer]     

Mapping rainbow trout immune genes involved in inflammation reveals conserved blocks of immune genes in teleosts

We report the genetic map location of 14 genes involved in the inflammatory response to salmonid bacterial and viral pathogens, which brings the total number of immune genes mapped in rainbow trout (RT, Oncorhynchus mykiss) to 61. These genes were mapped as candidate genes that may be involved in resistance to bacterial kidney disease, as well as candidates for known QTL for resistance to infectious hematopoietic necrosis virus, infectious pancreatic necrosis virus and Ceratomyxa shasta. These QTL map to one or more of the linkage groups containing immune genes. The combined analysis of these linkage results and those of previously mapped immune genes in RT shows that many immune genes are found in syntenic blocks of genes that have been retained in teleosts despite species divergence and genome duplication events.