Diversity of the pufferfish Takifugu rubripes fast skeletal myosin heavy chain genes

Myosin is a highly conserved, ubiquitous actin-based molecular motor that is distributed as diverse as from prokaryotes to mammalian tissues. Among various types in the myosin family proteins, class II, also called sarcomeric, myosin is a classical, conventional molecule that has been extensively studies on its functional and structural properties. It consists of two heavy chains (MYH) of about 200 kDa and four light chains of about 20 kDa. The exon–intron organization was determined for the major subunit of MYH, which contains ATP-hydrolysis and actin-binding sites, from torafugu (tiger pufferfish) Takifugu rubripes fast skeletal muscles. Comprehensive investigation for fast skeletal MYHs based on the fugu (torafugu) genome database and subsequent construction of their physical map revealed that torafugu contains at least 8 putative skeletal MYHs. Furthermore, genomic structural analysis revealed that skeletal MYHs are not clustered in a single locus, but rather spread to at least four loci, with two of them locating at the mammalian syntenic regions. Such arrangement of torafugu MYHs are in a marked contrast to mammalian fast skeletal MYHs that are clustered in a single locus. These data suggest that an ancient segmental duplication or whole-genome duplication occurred in fish lineage as in many other reported torafugu genes.     

Biglycan-Like Extracellular Matrix Genes of Agnathans and Teleosts

Biglycan and decorin are two members of a family of small extracellular matrix proteoglycans characterized by the presence of 10 leucine-rich repeats and one or two attachment sites for glucosaminoglycans. Both have thus far been described only from tetrapod species, mainly mammals. Because the extracellular matrix has played an important part in the evolution of Metazoa, the phylogeny of its components is of considerable interest. In this study, biglycan-like (BGL) cDNA sequences have been obtained from two teleost (Oreochromis cichlid and zebrafish) and two lamprey species. The analysis of the sequences suggests that, like tetrapods, the lampreys possess two types of proteoglycans, both of which are biglycan-like; decorin-like proteoglycans could not be identified in these species. The genes specifying these two types apparently arose by duplication in the lamprey lineage after its divergence from gnathostomes. The two teleost species possess a BGL proteoglycan and a bona fide decorin. The BGL proteoglycan is highly divergent from the tetrapod biglycan and related to the BGL proteoglycans of the lamprey. Hence, although the duplication generating the ancestors of biglycan and decorin genes occurred after the divergence of agnathans but before the emergence of teleosts, only decorin acquired its characteristic properties in the bony fishes. The BGL gene presumably turned into a typical biglycan only in the tetrapod lineages. The presumed acquisitions of new functions appear to have been accompanied by changes in the evolutionary rate. Received: 13 April 2000 / Accepted: 4 July 2000     

A 5'-flanking region of embryonic-type myosin heavy chain gene,MYHM743-2, from torafugu Takifugu rubripes regulates developmental muscle-specific expression

The myosin heavy chain gene, MYH_M743-2, is highly expressed in fast muscle fibers of torafugu embryos. However, the regulatory mechanisms involved in its expression have been unclear. In this study, we examined spatio-temporal expression patterns of this gene during development by injecting expression vectors containing the GFP reporter gene fused to the 5'-flanking region of MYH_M743-2 into fertilized eggs of zebrafish and medaka. Although the -2.1 kb 5'-flanking region of torafugu MYH_M743-2 showed no homology with the corresponding regions of zebrafish and medaka orthologous genes on the rVISTA analysis, the torafugu 5'-flanking region activated the GFP expression which was detected in the myotomal compartment for both zebrafish and medaka embryos. The GFP expression was localized to fast and slow muscle fibers in larvae as revealed by immunohistochemical analysis. In addition to the above tissues, GFP was also expressed in jaw, eye and pectoral fin muscles in embryos and larvae. These results clearly demonstrated that the 2.1 kb 5'-flanking region of MYH_M743-2 contains essential cis-regulatory sequences for myogenesis that are conserved among torafugu, zebrafish and medaka.     

The complete mitochondrial DNA sequence of the shark Mustelus manazo: evaluating rooting contradictions to living bony vertebrates

A remarkable example of a misleading mitochondrial protein tree is presented, involving ray-finned fishes, coelacanths, lungfishes, and tetrapods, with sea lampreys as an outgroup. In previous molecular phylogenetic studies on the origin of tetrapods, ray-finned fishes have been assumed as an outgroup to the tetrapod/lungfish/coelacanth clade, an assumption supported by morphological evidence. Standard methods of molecular phylogenetics applied to the protein-encoding genes of mitochondria, however, give a bizarre tree in which lamprey groups with lungfish and, therefore, ray-finned fishes are not the outgroup to a tetrapod/lungfish/coelacanth clade. All of the dozens of published phylogenetic methods, including every possible modification to maximum likelihood known to us (such as inclusion of site heterogeneity and exclusion of potentially misleading hydrophobic amino acids), fail to place the ray-finned fishes in a biologically acceptable position. A likely cause of this failure may be the use of an inappropriate outgroup. Accordingly, we have determined the complete mitochondrial DNA sequence from the shark, Mustelus manazo, which we have used as an alternative and more proximal outgroup than the lamprey. Using sharks as the outgroup, lungfish appear to be the closest living relative of tetrapods, although the possibility of a lungfish/coelacanth clade being the sister group of tetrapods cannot be excluded.      

Evolution of follistatin in teleosts revealed through phylogenetic, genomic and expression analyses

Follistatin (Fst) inhibits transforming growth factor-β (TGF-B) proteins and is a known regulator of amniote myogenesis. Here, we used phylogenetic, genomic and experimental approaches to study its evolution in teleosts. Phylogenetic analyses suggested that one fst gene (fst1) is common to euteleosts, but a second gene (fst2) is conserved specifically within the Ostariophysi. Zebrafish fst1/2 respectively appear on chromosomes 5 and 10 in two genomic regions, each with conserved synteny to a single region in tetrapods. Interestingly, other teleosts have two corresponding chromosomal regions with a similar repertoire of paralogues. Phylogenetic reconstruction clustered these gene duplicates into two sister clades branching from tetrapod sequences. We suggest that an ancestral fst-containing chromosome was duplicated during the teleost whole genome duplication, but that fst2 was lost in lineages external to the Ostariophysi. We show that Fst1 of teleosts/mammals has evolved under strong purifying selection, but the N-terminal of Fst2 may have evolved under positive selection. Furthermore, the tissue-specific expression of zebrafish fst2 was restricted to fewer tissues compared to its paralogue and the single fst1 orthologue of Atlantic salmon (Salmo salar). Zebrafish fst1/2 may have subfunctionalized relative to non-duplicated vertebrate lineages, as several regions in the fst promoter of tetrapods were conserved with one paralogue, but not both. Finally, we examined the embryonic expression of fst1 in a teleost outside the Ostariophysi (Atlantic salmon). During segmentation, fst1 was expressed in the anterior somite compartment but was excluded from muscle progenitors that strongly expressed myogenic regulatory factors (MRFs). Later, fst1 was expressed in myogenic progenitors of the pectoral fin buds and also within the pax7 ⁺ cell layer external to the myotome. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Divergent evolution of the myosin heavy chain gene family in fish and tetrapods: evidence from comparative genomic analysis.

Myosin heavy chain genes (MYHs) are the most important functional domains of myosins, which are highly conserved throughout evolution. The human genome contains 15 MYHs, whereas the corresponding number in teleost appears to be much higher. Although teleosts comprise more than one-half of all vertebrate species, our knowledge of MYHs in teleosts is rather limited. A comprehensive analysis of the torafugu (Takifugu rubripes) genome database enabled us to detect at least 28 MYHs, almost twice as many as in humans. RT-PCR revealed that at least 16 torafugu MYH representatives (5 fast skeletal, 3 cardiac, 2 slow skeletal, 1 superfast, 2 smooth, and 3 nonmuscle types) are actually transcribed. Among these, MYH(M743-2) and MYH(M5) of fast and slow skeletal types, respectively, are expressed during development of torafugu embryos. Syntenic analysis reveals that torafugu fast skeletal MYHs are distributed across five genomic regions, three of which form clusters. Interestingly, while human fast skeletal MYHs form one cluster, its syntenic region in torafugu is duplicated, although each locus contains just a single MYH in torafugu. The results of the syntenic analysis were further confirmed by corresponding analysis of MYHs based on databases from Tetraodon, zebrafish, and medaka genomes. Phylogenetic analysis suggests that fast skeletal MYHs evolved independently in teleosts and tetrapods after fast skeletal MYHs had diverged from four ancestral MYHs.     

Lamprey contractile protein genes mark different populations of skeletal muscles during development

Agnathan lampreys retain ancestral characteristics of vertebrates in the morphology of skeletal muscles derived from two mesodermal regions: trunk myotomes and unsegmented head mesoderm. During lamprey development, some populations of myoblasts migrate via pathways that differ from those of gnathostomes. To investigate the evolution of skeletal muscle differentiation in vertebrates, we characterize multiple contractile protein genes expressed in the muscle cells of the Japanese lamprey, Lethenteron japonicum. Lamprey actin gene LjMA2, and myosin heavy chain (MyHC) genes LjMyHC1 and LjMyHC2 are all expressed in the developing skeletal muscle cells of early embryos. However, LjMyHC1 and LjMyHC2 are expressed only in cells originating from myotomes, while LjMA2 is expressed in both myotomal and head musculature. Thus, in lampreys, myotomes and head mesoderm differ in the use of genes encoding contractile protein isoforms. Phylogenetic tree analyses including lamprey MyHCs suggest that the variety of muscle MyHC isoforms in different skeletal muscles may correspond to the morphological complexity of skeletal muscles of different vertebrate species. Another lamprey actin gene LjMA1 is likely to be the first smooth muscle actin gene isolated from non-tetrapods. We conclude that, in vertebrate evolution, the different regulatory systems for striated and smooth muscle-specific genes may have been established before the agnathan/gnathostome divergence.     

Identification of a Novel Gig2 Gene Family Specific to Non-Amniote Vertebrates

Gig2 (grass carp reovirus (GCRV)-induced gene 2) is first identified as a novel fish interferon (IFN)-stimulated gene (ISG). Overexpression of a zebrafish Gig2 gene can protect cultured fish cells from virus infection. In the present study, we identify a novel gene family that is comprised of genes homologous to the previously characterized Gig2. EST/GSS search and in silico cloning identify 190 Gig2 homologous genes in 51 vertebrate species ranged from lampreys to amphibians. Further large-scale search of vertebrate and invertebrate genome databases indicate that Gig2 gene family is specific to non-amniotes including lampreys, sharks/rays, ray-finned fishes and amphibians. Phylogenetic analysis and synteny analysis reveal lineage-specific expansion of Gig2 gene family and also provide valuable evidence for the fish-specific genome duplication (FSGD) hypothesis. Although Gig2 family proteins exhibit no significant sequence similarity to any known proteins, a typical Gig2 protein appears to consist of two conserved parts: an N-terminus that bears very low homology to the catalytic domains of poly(ADP-ribose) polymerases (PARPs), and a novel C-terminal domain that is unique to this gene family. Expression profiling of zebrafish Gig2 family genes shows that some duplicate pairs have diverged in function via acquisition of novel spatial and/or temporal expression under stresses. The specificity of this gene family to non-amniotes might contribute to a large extent to distinct physiology in non-amniote vertebrates.     

A fibrous membrane suspends the multifocal lens in the eyes of lampreys and African lungfishes

The sharpness and thus information content of the retinal image in the eye depends on the optical quality of the lens and its accurate positioning in the eye. Multifocal lenses create well‐focused color images and are present in the eyes of all vertebrate groups studied to date (mammals, reptiles including birds, amphibians, and ray‐finned fishes) and occur even in lampreys, i.e., the most basal vertebrates with well‐developed eyes. Results from photoretinoscopy obtained in this study indicate that the Dipnoi (lungfishes), i.e., the closest piscine relatives to tetrapods, also possess multifocal lenses. Suspension of the lens is complex and sophisticated in teleosts (bony fishes) and tetrapods. We studied lens suspension using light and electron microscopy in one species of lamprey (Lampetra fluviatilis) and two species of African lungfish (Protopterus aethiopicus aethiopicus and Protopterus annectens annectens). A fibrous and highly transparent membrane suspends the lens in both of these phylogenetically widely separated vertebrate groups. The membrane attaches to the lens approximately along the lens equator, from where it extends to the ora retinalis. The material forming the membrane is similar in ultrastructure to microfibrils in the zonule fibers of tetrapods. The membrane, possibly in conjunction with the cornea, iris, and vitreous body, seems suitable for keeping the lens in the correct position for well‐focused imaging. Suspension of the lens by a multitude of zonule fibers in tetrapods may have evolved from a suspensory membrane similar to that in extant African lungfishes, a structure that seems to have appeared first in the lamprey‐like ancestors of allextant vertebrates. J. Morphol. 271:980–989, 2010. © 2010 Wiley‐Liss, Inc.     

New insights into the organization and evolution of vertebrate IRBP genes and utility of IRBP gene sequences for the phylogenetic study of the Acanthomorpha (Actinopterygii: Teleostei)

The interphotoreceptor retinoid-binding protein (IRBP) coding gene has been used with success for the large-scale phylogeny of mammals. However, its phylogenetic worth had not been explored in Actinopterygians. We explored the evolution of the structure of the gene and compared the structure predicted from known sequences with that of a basal vertebrate lineage, the sea lamprey Petromyzon marinus. This sequence is described here for the first time. The structure made up of four tandem repeats (or modules) arranged in a single gene, as present in Chondrichthyes (sharks and rays) and tetrapods, is also present in sea lamprey. In teleosts, one to two paralogous copies of IRBP gene have been identified depending on the genomes. When the sequences from all modules for a wide sampling of vertebrates are compared and analyzed, all sequences previously assigned to a particular module appear to be clustered together, suggesting that the divergence among modules is older than the split between lampreys and other vertebrates. Finally, 92 acanthomorph teleosts were sequenced for the partial module 1 of the gene 2 (713 bp) to assess for the first time the use of this marker for the systematic studies of the Teleostei. The partial sequence is slightly more variable than other markers currently used for this group, and the resulting trees from our sequences recover most of the clades described in the recent molecular multi-marker studies of the Acanthomorpha. We recommend the use of partial sequences from the IRBP gene 2 as a marker for phylogenetic inference in teleosts.     

Six Homeoproteins and a linc-RNA at the Fast MYH Locus Lock Fast Myofiber Terminal Phenotype

Thousands of long intergenic non-coding RNAs (lincRNAs) are encoded by the mammalian genome. However, the function of most of these lincRNAs has not been identified in vivo. Here, we demonstrate a role for a novel lincRNA, linc-MYH, in adult fast-type myofiber specialization. Fast myosin heavy chain (MYH) genes and linc-MYH share a common enhancer, located in the fast MYH gene locus and regulated by Six1 homeoproteins. linc-MYH in nuclei of fast-type myofibers prevents slow-type and enhances fast-type gene expression. Functional fast-sarcomeric unit formation is achieved by the coordinate expression of fast MYHs and linc-MYH, under the control of a common Six-bound enhancer.     

Lack of Plasma Kallikrein-Kinin System Cascade in Teleosts

The kallikrein-kinin system (KKS) consists of two major cascades in mammals: “plasma KKS” consisting of high molecular-weight (HMW) kininogen (KNG), plasma kallikrein (KLKB1), and bradykinin (BK); and “tissue KKS” consisting of low molecular-weight (LMW) KNG, tissue kallikreins (KLKs), and [Lys⁰]-BK. Some components of the KKS have been identified in the fishes, but systematic analyses have not been performed, thus this study aims to define the KKS components in teleosts and pave a way for future physiological and evolutionary studies. Through a combination of genomics, molecular, and biochemical methods, we showed that the entire plasma KKS cascade is absent in teleosts. Instead of two KNGs as found in mammals, a single molecular weight KNG was found in various teleosts, which is homologous to the mammalian LMW KNG. Results of molecular phylogenetic and synteny analyses indicated that the all current teleost genomes lack KLKB1, and its unique protein structure, four apple domains and one trypsin domain, could not be identified in any genome or nucleotide databases. We identified some KLK-like proteins in teleost genomes by synteny and conserved domain analyses, which could be the orthologs of tetrapod KLKs. A radioimmunoassay system was established to measure the teleost BK and we found that [Arg⁰]-BK is the major circulating form instead of BK, which supports that the teleost KKS is similar to the mammalian tissue KKS. Coincidently, coelacanths are the earliest vertebrate that possess both HMW KNG and KLKB1, which implies that the plasma KKS could have evolved in the early lobe-finned fish and descended to the tetrapod lineage. The co-evolution of HMW KNG and KLKB1 in lobe-finned fish and early tetrapods may mark the emergence of the plasma KKS and a contact activation system in blood coagulation, while teleosts may have retained a single KKS cascade.     

The evolution of tenascins and fibronectin

Tenascins are extracellular matrix glycoproteins that act both as integrin ligands and as modifiers of fibronectin-integrin interactions to regulate cell adhesion, migration, proliferation and differentiation. In tetrapods, both tenascins and fibronectin bind to integrins via RGD and LDV-type tripeptide motifs found in exposed loops in their fibronectin-type III domains. We previously showed that tenascins appeared early in the chordate lineage and are represented by single genes in extant cephalochordates and tunicates. Here we have examined the genomes of the coelacanth Latimeria chalumnae, the elephant shark Callorhinchus milii as well as the lampreys Petromyzon marinus and Lethenteron japonicum to learn more about the evolution of the tenascin gene family as well as the timing of the appearance of fibronectin during chordate evolution. The coelacanth has 4 tenascins that are more similar to tetrapod tenascins than are tenascins from ray-finned fishes. In contrast, only 2 tenascins were identified in the elephant shark and the Japanese lamprey L. japonicum. An RGD motif exposed to integrin binding is observed in tenascins from many, but not all, classes of chordates. Tetrapods that lack this RGD motif in tenascin-C have a similar motif in the paralog tenascin-W, suggesting the potential for some overlapping function. A predicted fibronectin with the same domain organization as the fibronectin from tetrapods is found in the sea lamprey P. marinus but not in tunicates, leading us to infer that fibronectin first appeared in vertebrates. The motifs that recognize LDV-type integrin receptors are conserved in fibronectins from a broad spectrum of vertebrates, but the RGD integrin-binding motif may have evolved in gnathostomes.     

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.