Structure and expression of three Emx genes in the dogfish Scyliorhinus canicula: functional and evolutionary implications

We report the characterization of three Emx genes in a chondrichthyan, the dogfish Scyliorhinus canicula. Comparisons of these genes with their osteichthyan counterparts indicate that the gnathostome Emx genes belong to three distinct orthology classes, each containing one of the dogfish genes and either the tetrapod Emx1 genes (Emx1 class), the osteichthyan Emx2 genes (Emx2 class) or the zebrafish Emx1 gene (Emx3 class). While the three classes could be retrieved from the pufferfish genome data, no indication of an Emx3-related gene in tetrapods could be found in the databases, suggesting that this class may have been lost in this taxon. Expression pattern comparisons of the three dogfish Emx genes and their osteichthyan counterparts indicate that not only telencephalic, but also diencephalic Emx expression territories are highly conserved among gnathostomes. In particular, all gnathostomes share an early, dynamic phase of Emx expression, spanning presumptive dorsal diencephalic territories, which involves Emx3 in the dogfish, but another orthology class, Emx2, in tetrapods. In addition, the dogfish Emx2 gene shows a highly specific expression domain in the cephalic paraxial mesoderm from the end of gastrulation and throughout neurulation, which suggests a role in the segmentation of the cephalic mesoderm.     

Patterns and consequences of vertebrate Emx gene duplications

SUMMARY We have cloned and analyzed two Emx genes from the lamprey Petromyzon marinus and our findings provide insight into the patterns and developmental consequences of gene duplications during early vertebrate evolution. The Emx gene family presents an excellent case for addressing these issues as gnathostome vertebrates possess two or three Emx paralogs that are highly pleiotropic, functioning in or being expressed during the development of several vertebrate synapomorphies. Lampreys are the most primitive extant vertebrates and characterization of their development and genomic organization is critical for understanding vertebrate origins. We identified two Emx genes from P. marinus and analyzed their phylogeny and their embryological expression relative to other chordate Emx genes. Our phylogenetic analysis shows that the two lamprey Emx genes group independently from the gnathostome Emx1, Emx2 , and Emx3 paralogy groups. Our expression analysis shows that the two lamprey Emx genes are expressed in distinct spatial and temporal patterns that together broadly encompass the combined sites of expression of all gnathostome Emx genes. Our data support a model wherein large-scale regulatory evolution of a single Emx gene occurred after the protochordate/vertebrate divergence, but before the vertebrate radiation. Both the lamprey and gnathostome lineages then underwent independent gene duplications followed by extensive paralog subfunctionalization. Emx subfunctionalization in the telencephalon is remarkably convergent and refines our understanding of lamprey forebrain patterning. We also identify lamprey-specific sites of expression that indicate either neofunctionalization in lampreys or sites-specific nonfunctionalization of all gnathostome Emx genes. Overall, we see only very limited correlation between Emx gene duplications and the acquisition of novel expression domains.     

Three structurally and functionally conserved Hlx genes in zebrafish

For the Hlx class, which includes homeodomains (HD) that are similar to Drosophila H2.0, few members have been identified in vertebrates. In this report, we describe three zebrafish genes, hlx1, hlx2 and hlx3, related to the murine Dbx genes. The proteins encoded by hlx1 and hlx2 have about the same sequence identity to Dbx1 (approximately 60%), suggesting that they derive from a duplication in the fish lineage. This is supported by similarities in the embryonic expression patterns and promoter sequence conservation. The zebrafish Hlx3 protein is related to murine Dbx2, but it is apparently too diverged to be orthologous. Our phylogenetic analysis of all the known HD sequences of the Hlx class also shows that it can be divided into at least two distinct families. All the Dbx-like genes have similar expression in the embryonic nervous system. However, the initial expression patterns of the zebrafish hlx genes are quite unique, suggesting that some functional divergence has occurred between fish and mammals.     

Neuropeptide Y/peptide YY receptor Y2 duplicate in zebrafish with unique introns displays distinct peptide binding properties

The neuropeptide Y-family peptides and receptors are involved in a broad range of functions including appetite regulation. Both the peptide genes and the receptor genes are known to have duplicated in early vertebrate evolution. The ancestral jawed vertebrate had 7 NPY receptors but the number varies between 4 and 7 in extant vertebrates. Herein we describe the identification of an additional NPY receptor in two fish species, zebrafish and medaka. They cluster together with the Y2 receptors in phylogenetic analyses and seem to be orthologous to each other that is why we have named them Y2-2. Their genes differ from Y2 in having introns in the coding region. Binding studies with zebrafish Y2-2 receptors show that the three endogenous peptides NPY, PYYa and PYYb have similar affinities, 0.15–0.66 nM. This is in contrast to the Y2 receptor where they differed considerably from one another. N-terminally truncated NPY binds poorly and the Y2 antagonist BIIE0246 binds well to Y2-2, results that are reversed in comparison to Y2. Zebrafish Y2-2 mRNA was detected by PCR in the intestine and the eye, but not in the brain. In conclusion, we have found a novel Y2-like NPY/PYY receptor that probably arose in early teleost fish evolution.     

Developmental expression of zebrafish emx1 during early embryogenesis

Emx family homeobox genes, Emx1 and Emx2, play an essential role in rostral brain development in mammalian embryos. Here we report a zebrafish emx family gene, emx1, which is more similar to the mouse Emx1 gene than the previously reported zebrafish emx1 gene; we propose to rename that gene emx3. The expression of emx1 is first detected around the 10-somite stage in the pineal gland (epiphysis) primodium in the developing anterior brain and in the pronephric primodium within the intermediate mesoderm. emx1 expression in the epiphysis has not been reported in other species. Expression in the epiphysis is suppressed at 23 h post-fertilization (hpf) in the floating head (flh) mutant, in which development of the epiphysis is impaired. Subsequently, emx1 is expressed in the telencephalon, as reported in mammals, and can be detected in the olfactory placode and in a small group of cells in the forebrain at 25 hpf. In the mesoderm, emx1 expression is gradually concentrated in the posterior pronephric duct during somitogenesis, and becomes expressed predominantly in the urogenital opening at 25 hpf. Thus, emx1 displays a unique expression pattern that is distinct from the patterns of emx2 and emx3.     

Phylogenetic relationships and chromosomal location of five distinct glycine receptor subunit genes in the teleost Danio rerio

Glycine receptors mediating synaptic inhibition are heteromeric proteins constituted of alpha and beta subunits. The mammalian GlyR subunits constitute a subgroup in the superfamily of ligand-gated ionic channels. To compare the evolutionary events in the mammalian and teleostean lineages for the receptor family, we first undertook systematic cloning of the constitutive subunits of the zebrafish glycine receptor. The isolation of two alpha subunits (alphaZ1 and alphaZ2) and one beta subunit (betaZ) has been reported previously and we report here the characterization of two novel alpha subunits, alphaZ3 and alphaZ4, increasing the known zebrafish subunits number to four alpha and one beta. Establishment of phylogenetic relationships reveals that alphaZ1, alphaZ3 and betaZeta are orthologous to mammalian alpha1, alpha3 and beta subunits. However, two zebrafish GlyRalpha subunit genes are orthologous to the unique avian and mammalian alpha4 subunit revealing a duplication of the alpha4 gene in zebrafish. Whole-mount in situ hybridization in 24-hours post fertilization (hpf) and 52-hpf embryos of the daughter gene products display very different expression patterns indicating distinct functions of the duplicated genes. Gene mapping reveals that the two duplicated genes are localized on two different linkage groups (LG5 and LG22) as would be daughter genes resulting from a large-scale duplication of the ancestral genome. Finally, we report that a linked pair of genes on human chromosome 4 (alpha3 and beta) is also linked on linkage group 1 in zebrafish (alphaZ3 and betaZ) as a consequence of a mosaic conserved syntheny.     

Evolutionary analysis of vertebrate Notch genes

We have conducted an evolutionary analysis of Notch genes of the vertebrates Danio rerio and Mus musculus to examine the expansion and diversification of the Notch family during vertebrate evolution. The existence of multiple Notch genes in vertebrate genomes suggests that the increase in Notch signaling pathways may be necessary for the additional complexity observed in the vertebrate body plan. However, orthology relationships within the vertebrate Notch family indicate that biological functions are not fixed within orthologous groups. Phylogenetic reconstruction of the vertebrate Notch family suggests that the zebrafish notch1a and 1b genes resulted from a duplication occurring around the time of the teleost/mammalian divergence. There is also evidence that the mouse Notch4 gene is the result of a rapid divergence from a Notch3-like gene. Investigation of the ankyrin repeat region sequences showed there to be little evidence for gene conversion events between repeat units. However, relationships between repeats 2-5 suggest that these repeats are the result of a tandem duplication of a dual repeat unit. Selective pressure on maintenance of ankyrin repeat sequences indicated by relationships between the repeats suggests that specific repeats are responsible for particular biological activities, a finding consistent with mutational studies of the Caenorhabditis elegans gene glp-1. Sequence similarities between the ankyrin repeats and the region immediately C-terminal of the repeats further suggests that this region may be involved in the modulation of ankyrin repeat function.     

Differential expression of orthologous Dlx genes in zebrafish and mice: implications for the evolution of the Dlx homeobox gene family

Dlx homeobox genes of vertebrates are often organised as physically linked pairs in which the two genes are transcribed convergently (tail-to-tail arrangement). Three such Dlx pairs have been found in mouse, human, and zebrafish and are thought to have originated from the duplication of an ancestral gene pair. These pairs include Dlx1/Dlx2, Dlx7/Dlx3, and Dlx6/Dlx5 (the zebrafish orthologue of Dlx5 is named dlx4). Expression patterns of physically linked Dlx genes overlap extensively. Furthermore, orthologous Dlx genes often show highly similar expression patterns. We analysed Dlx expression during the gastrula and early somitogenesis of the mouse and zebrafish. It was found that expression of the mouse Dlx6 gene takes place in the rostral ectoderm and presumptive olfactory and otic placodes with patterns similar to the previously reported expression of the physically linked Dlx5 gene. However, we observed only very weak expression of the mouse Dlx3 gene at the same stage. This contrasts with the expression of dlx genes in zebrafish where dlx3 and dlx7, but not dlx4 and dlx6 are expressed during gastrulation in the rostral ectoderm and presumptive placodes. Thus, Dlx expression patterns at early stages are better conserved between paralogous pairs of physically linked genes than between orthologous pairs. This suggests that early expression of Dlx genes existed prior to the duplications that led to the multiple pairs of physically linked genes but was differentially conserved in different paralogs in zebrafish and mice.     

Expression of three <Emphasis Type="Italic">spalt </Emphasis>(<Emphasis Type="Italic">sal</Emphasis>) gene homologues in zebrafish embryos

Three homologues of the Drosophilaregion-specific homeotic gene spalt (sal) have been isolated in zebrafish, sall1a, sall1b and sall3. Phylogenetic analysis of these genes against known salDNA sequences showed zebrafish sall1aand sall1b to be orthologous to other vertebrate sal-1 genes and zebrafish sall3to be orthologous to other vertebrate sal-3 genes, except Xenopus sall3. Phylogenetic reconstruction suggests that zebrafish sall1a and sall1bresulted from a gene duplication event occurring prior to the divergence of the ray-finned and lobe-finned fish lineages. Analysis of the expression pattern of the zebrafish sal genes shows that sall1a and sall3 share expression domains with both orthologous and non-orthologous vertebrate sal genes. Both are expressed in various regions of the CNS, including in primary motor neurons. Outside of the CNS, sall1a expression is observed in the otic vesicle (ear), heart and in a discrete region of the pronephric ducts. These analyses indicate that orthologies between zebrafish sal genes and other vertebrate sal genes do not imply equivalence of expression pattern and, therefore, that biological functions are not entirely conserved. However we suggest that, like other vertebrate sal genes, zebrafish sal genes have a role in neural development. Also, expression of zebrafish sall1a in the otic vesicle, heart sac and the pronephric ducts of zebrafish embryos is possibly consistent with some of the abnormalities seen in Sall1-deficient mice and in Townes-Brocks Syndrome, a human disorder which is caused by mutations in the human spalt gene SALL1.     

Two vertebrate homeobox genes related to the Drosophila empty spiracles gene are expressed in the embryonic cerebral cortex.

We cloned two homeobox genes, Emx1 and Emx2, related to empty spiracles, a gene expressed in very anterior body regions during early Drosophila embryogenesis, and studied their expression in mouse embryos. Emx1 expression is detectable from day 9.5 of gestation whereas Emx2 appears to be already expressed in 8.5 day embryos. Both genes are expressed in the presumptive cerebral cortex and olfactory bulbs. Emx1 is expressed exclusively there, whereas Emx2 is also expressed in some neuroectodermal areas in embryonic head including olfactory placodes in earlier stages and olfactory epithelia later in development.     

Relationships among msx gene structure and function in zebrafish and other vertebrates

The zebrafish genome contains at least five msx homeobox genes, msxA, msxB, msxC, msxD, and the newly isolated msxE. Although these genes share structural features common to all Msx genes, phylogenetic analyses of protein sequences indicate that the msx genes from zebrafish are not orthologous to the Msx1 and Msx2 genes of mammals, birds, and amphibians. The zebrafish msxB and msxC are more closely related to each other and to the mouse Msx3. Similarly, although the combinatorial expression of the zebrafish msx genes in the embryonic dorsal neuroectoderm, visceral arches, fins, and sensory organs suggests functional similarities with the Msx genes of other vertebrates, differences in the expression patterns preclude precise assignment of orthological relationships. Distinct duplication events may have given rise to the msx genes of modern fish and other vertebrate lineages whereas many aspects of msx gene functions during embryonic development have been preserved.      

Zebrafish hox paralogue group 2 genes function redundantly as selector genes to pattern the second pharyngeal arch

The pharyngeal arches are one of the defining features of the vertebrates, with the first arch forming the mandibles of the jaw and the second forming jaw support structures. The cartilaginous elements of each arch are formed from separate migratory neural crest cell streams, which derive from the dorsal aspect of the neural tube. The second and more posterior crest streams are characterized by specific Hox gene expression. The zebrafish has a larger overall number of Hox genes than the tetrapod vertebrates, as the result of a duplication event in its lineage. However, in both zebrafish and mouse, there are just two members of Hox paralogue group 2 (PG2): Hoxa2 and Hoxb2. Here, we show that morpholino-mediated "knock-down" of both zebrafish Hox PG2 genes results in major defects in second pharyngeal arch cartilages, involving replacement of ventral elements with a mirror-image duplication of first arch structures, and accompanying changes to pharyngeal musculature. In the mouse, null mutants of Hoxa2 have revealed that this single Hox gene is required for normal second arch patterning. By contrast, loss-of-function of either zebrafish Hox PG2 gene individually has no phenotypic consequence, showing that these two genes function redundantly to confer proper pattern to the second pharyngeal arch. We have also used hoxb1a mis-expression to induce localized ectopic expression of zebrafish Hox PG2 genes in the first arch; using this strategy, we find that ectopic expression of either Hox PG2 gene can confer second arch identity onto first arch structures, suggesting that the zebrafish Hox PG2 genes act as "selector genes."     

Functional conservation of a forebrain enhancer from the elephant shark (<Emphasis Type="Italic">Callorhinchus milii</Emphasis>) in zebrafish and mice

Background  

The phylogenetic position of the elephant shark (Callorhinchus milii ) is particularly relevant to study the evolution of genes and gene regulation in vertebrates. Here we examine the evolution of Dlx homeobox gene regulation during vertebrate embryonic development with a particular focus on the forebrain. We first identified the elephant shark sequence orthologous to the URE2 cis -regulatory element of the mouse Dlx1/Dlx2 locus (herein named CmURE2). We then conducted a comparative study of the sequence and enhancer activity of CmURE2 with that of orthologous regulatory sequences from zebrafish and mouse.     

The Mdm2 and p53 genes are conserved in the Arachnids

The p53 protein and its negative regulator the ubiquitin E3 ligase Mdm2 have been shown to be conserved from the Placazoan to man. In common with D.melanogaster and C.elegans, there is a single copy of the p53 gene in T.adhaerens, while in the vertebrates three p53-like genes can be found: p53 , p63 and p73. The Mdm2 gene is not present within the fully sequenced and highly annotated genomes of C.elegans and D.melanogaster. However, it is present in the Placazoan and the presence of multiple distinct p53 genes in the Sea anemone N.vectensis led us to examine the genomes of other phyla for p53 and Mdm2-like genes. We report here the discovery of an Mdm2-like gene and two distinct p53 like genes in the Arachnid Ioxodes scapularis (Northern Deer Tick). The two predicted Deer Tick p53 proteins are much more highly related to the human p53 protein in sequence than are the fruit fly and nematode proteins. One of the Deer tick genes encodes a p53 protein that is initiated within the DNA binding domain of p53 and shows remarkable homology to the newly described N-terminally truncated delta isoforms of human and zebrafish p53.     

斑马鱼IRF11基因的鉴定、亚细胞定位及表达特征

早期的研究表明IRF11是鱼类特有的IRF家族成员。查询最近解析的斑马鱼第九版基因组时,发现斑马鱼IRF1和IRF11命名出现了混乱。通过对脊椎动物IRF1和IRF11基因位点进行同线型分析表明,IRF11与IRF1是两个不同的基因,不宜命名为IRF1b和IRF1a。系统进化树分析发现,在脊椎动物中IRF11基因比IRF1起源更早;两栖类以后的脊椎动物基因组只有IRF1,没有IRF11,其中原因可能是因为基因丢失。斑马鱼IRF11与脊椎动物IRF1一样,其表达蛋白定位在细胞核中。缺失分析揭示斑马鱼IRF11的DBD有一个能引导蛋白定位进入细胞核的序列。表达分析发现poly（I:C）能诱导斑马鱼IRF11的表达,但其表达水平低于IRF1。     

Conserved expression of<Emphasis Type="Italic"> Hoxa1</Emphasis> in neurons at the ventral forebrain/midbrain boundary of vertebrates

The previously described expression patterns of zebrafish and mouse Hoxa1 genes are seemingly very disparate, with mouse Hoxa1 expressed in the gastrula stage hindbrain and the orthologous zebrafish hoxa1a gene expressed in cell clusters within the ventral forebrain and midbrain. To investigate the evolution of Hox gene deployment within the vertebrate CNS, we have performed a comparative expression analysis of Hoxa1 orthologs in a range of vertebrate species, comprising representatives from the two major lineages of vertebrates (actinopterygians and sarcopterygians). We find that fore/midbrain expression of hoxa1a is conserved within the teleosts, as it is shared by the ostariophysan teleost zebrafish (Danio rerio) and the distantly related acanthopterygian teleost medaka (Oryzias latipes). Furthermore, we find that in addition to the described gastrula stage hindbrain expression of mouse Hoxa1, there is a previously unreported neurula stage expression domain, again located more anteriorly at the ventral fore/midbrain boundary. A two-phase expression profile in early hindbrain and later fore/midbrain is shared by the other tetrapod model organisms chick and Xenopus. We show that the anterior Hoxa1 expression domain is localized to the anterior terminus of the medial longitudinal fasciculus (MLF) in mouse, chick, and zebrafish. These findings suggest that anterior expression of Hoxa1 is a primitive characteristic that is shared by the two major vertebrate lineages. We conclude that Hox gene expression within the vertebrate CNS is not confined exclusively to the segmented hindbrain and spinal cord, but rather that a presumptive fore/midbrain expression domain arose early in vertebrate origins and has been conserved for at least 400 million years.