Loss and gain of domains during evolution of cut superclass homeobox genes

The cut superclass of homeobox genes has been divided into three classes: CUX, ONECUT and SATB. Given the various completed genomes, we have now made a comprehensive survey. We find that there are only two cut domain containing genes in Drosophila, one CUX and one ONECUT type. Caenorhabditis elegans has undergone an expansion of the ONECUT subclass genes and has a gene cluster with three ONECUT class genes, one of which has lost the cut domain. Two of these genes contain a conserved sequence motif, termed OCAM, which also occurs in another gene in C. elegans this motif seems to be nematode specific. A recently uncovered C. elegans CUX gene has sequence conservation in its amino-terminus with vertebrate CUX proteins. Further, the 5' end of this gene containing the conserved region can undergo alternative splicing to give rise to a protein with a different carboxy-terminus lacking the cut- and homeodomain. This protein is conserved in its entirety with vertebrate genes termed CASP--which are also alternative splice products of the CUX genes--and with plant and fungal genes. The highly divergent SATB genes share a conserved amino terminal domain, COMPASS, with the Drosophila defective proventriculus gene and a C. elegans ORF. These two "COMPASS" family genes encode two highly divergent homeodomains, may be homologues of the SATB genes and thus probably belong to the cut superclass, too.     

The amphioxus Hox cluster: deuterostome posterior flexibility and Hox14

SUMMARY The amphioxus ( Branchiostoma floridae ) Hox cluster is a model for the ancestral vertebrate cluster, prior to the hypothesized genome-wide duplications that may have facilitated the evolution of the vertebrate body plan. Here we describe the posterior (5') genes of the amphioxus cluster, and report the isolation of four new homeobox genes. Vertebrates possess 13 types of Hox gene (paralogy groups), but we show that amphioxus possesses more than 13 Hox genes. Amphioxus is now the first animal in which a Hox14 gene has been found. Our mapping and phylogenetic analysis of amphioxus "Posterior Class" Hox genes reveals that these genes are evolving at a faster rate in deuterostomes than in protostomes, a phenomenon we term Posterior Flexibility.     

Evidence for the evolution of tenascin and fibronectin early in the chordate lineage

Fibronectin and tenascin are extracellular matrix glycoproteins that play important roles in cell adhesion and motility. In a previous study we provided evidence that tenascin first appeared early in the chordate lineage. As tenascin has been proposed to act, in part, through modulation of cell-fibronectin interactions, we sought here to identify fibronectin genes in non-vertebrate chordates and other invertebrates to determine if tenascin and fibronectin evolved separately or together, and to identify phylogenetically conserved features of both proteins. We found that the genome of the urochordate Ciona savignyi contains both a tenascin gene and a gene encoding a fibronectin-like protein with fibronectin type 1, 2 and 3 repeats. The genome of the cephalochordate Branchiostoma floridae (amphioxus) also has a tenascin gene. However, we could not identify a fibronectin-like gene in B. floridae, nor could we identify fibronectin or tenascin genes in echinoderms, protostomes or cnidarians. If urochordates are more closely related to vertebrates, tenascin may have evolved before fibronectin in an ancestor common to tunicates and amphioxus. Alternatively, tenascin and fibronectin may have evolved in an ancestor common to B. floridae and C. savignyi and the fibronectin gene was subsequently lost in the cephalochordate lineage. The fibronectin-like gene from C. savignyi does not encode the RGD motif for integrin binding found in all vertebrate fibronectins, and it lacks most of the fibronectin type 1 domains believed to be critical for fibrillogenesis. In contrast, the tenascin gene in B. floridae encodes multiple RGD motifs, suggesting that integrin binding is fundamental to tenascin function.     

Amphioxus Evx genes: implications for the evolution of the Midbrain-Hindbrain Boundary and the chordate tailbud.

Evx genes are widely used in animal development. In vertebrates they are crucial in gastrulation, neurogenesis, appendage development and tailbud formation, whilst in protostomes they are involved in gastrulation and neurogenesis, as well as segmentation at least in Drosophila. We have cloned the Evx genes of amphioxus (Branchiostoma floridae), and analysed their expression to understand how the functions of Evx have evolved between invertebrates and vertebrates, and in particular at the origin of chordates and during their subsequent evolution. Amphioxus has two Evx genes (AmphiEvxA and AmphiEvxB) which are genomically linked. AmphiEvxA is prototypical to the vertebrate Evx1 and Evx2 genes with respect to its sequence and expression, whilst AmphiEvxB is very divergent. Mapping the expression of AmphiEvxA onto a phylogeny shows that a role in gastrulation, dorsal-ventral patterning and neurogenesis is probably retained throughout bilaterian animals. AmphiEvxA expression during tailbud development implies a role for Evx throughout the chordates in this process, whilst lack of expression at the homologous region to the vertebrate Midbrain-Hindbrain Boundary (MHB) is consistent with the elaboration of the full organiser properties of this region being a vertebrate innovation.     

Complex history of a chromosomal paralogy region: insights from amphioxus aromatic amino acid hydroxylase genes and insulin-related genes

Aromatic amino acid hydroxylase (AAAH) genes and insulin-like genes form part of an extensive paralogy region shared by human chromosomes 11 and 12, thought to have arisen by tetraploidy in early vertebrate evolution. Cloning of a complementary DNA (cDNA) for an amphioxus (Branchiostoma floridae) hydroxylase gene (AmphiPAH) allowed us to investigate the ancestry of the human chromosome 11/12 paralogy region. Molecular phylogenetic evidence reveals that AmphiPAH is orthologous to vertebrate phenylalanine (PAH) genes; the implication is that all three vertebrate AAAH genes arose early in metazoan evolution, predating vertebrates. In contrast, our phylogenetic analysis of amphioxus and vertebrate insulin-related gene sequences is consistent with duplication of these genes during early chordate ancestry. The conclusion is that two tightly linked gene families on human chromosomes 11 and 12 were not duplicated coincidentally. We rationalize this paradox by invoking gene loss in the AAAH gene family and conclude that paralogous genes shared by paralogous chromosomes need not have identical evolutionary histories.     

Pitx homeobox genes in Ciona and amphioxus show left-right asymmetry is a conserved chordate character and define the ascidian adenohypophysis

All vertebrates have directional asymmetries in the organization of their internal organs. In jawed vertebrates, development of asymmetry is controlled by a conserved molecular pathway that includes Pitx2, which is expressed by lateral plate mesoderm cells on the left side of the embryo. Pitx2 is a member of the Pitx homeobox gene family, the expression of which also marks stomodeal ectoderm and the adenohypophysis. Here we report the characterization of Pitx genes from Branchiostoma floridae (an amphioxus) and Ciona intestinalis (a urochordate), representatives of two basal chordate lineages and successively deeper outgroups to the vertebrates. Expression of B. floridae Pitx is similar to that reported from B. belcheri, a different amphioxus species. Expression of the Ciona Pitx ortholog in the embryonic primordial pharynx and adult neural complex leads us to propose the Ciona primordial pharynx and ciliated funnel are homologous to the adenohypophyseal placode and adenohypophysis, respectively. Additionally, in both species we identify asymmetrical left-sided expression of Pitx genes during embryonic development. This shows that asymmetrical Pitx gene expression, and by inference directional asymmetry, evolved before the radiation of living chordates and should be considered a chordate character.     

Chromosomal mapping of ANTP class homeobox genes in amphioxus: piecing together ancestral genomes

Homeobox genes encode DNA-binding proteins, many of which are implicated in the control of embryonic development. Evolutionarily, most homeobox genes fall into two related clades: the ANTP and the PRD classes. Some genes in ANTP class, notably Hox, ParaHox, and NK genes, have an intriguing arrangement into physical clusters. To investigate the evolutionary history of these gene clusters, we examined homeobox gene chromosomal locations in the cephalochordate amphioxus, Branchiostoma floridae. We deduce that 22 amphioxus ANTP class homeobox genes localize in just three chromosomes. One contains the Hox cluster plus AmphiEn, AmphiMnx, and AmphiDll. The ParaHox cluster resides in another chromosome, whereas a third chromosome contains the NK type homeobox genes, including AmphiMsx and AmphiTlx. By comparative analysis we infer that clustering of ANTP class homeobox genes evolved just once, during a series of extensive cis-duplication events of genes early in animal evolution. A trans-duplication event occurred later to yield the Hox and ParaHox gene clusters on different chromosomes. The results obtained have implications for understanding the origin of homeobox gene clustering, the diversification of the ANTP class of homeobox genes, and the evolution of animal genomes.     

Expression of AmphiCoe, an amphioxus COE/EBF gene, in the developing central nervous system and epidermal sensory neurons

The COE/EBF gene family marks a subset of prospective neurons in the vertebrate central and peripheral nervous system, including neurons deriving from some ectodermal placodes. Since placodes are often considered unique to vertebrates, we have characterised an amphioxus COE/EBF gene with the aim of using it as a marker to examine the timing and location of peripheral neuron differentiation. A single COE/EBF family member, AmphiCoe, was isolated from the amphioxus Branchiostoma floridae. AmphiCoe lies basal to the vertebrate COE/EBF genes in molecular phylogenetic analysis, suggesting that the duplications that formed the vertebrate COE/EBF family were specific to the vertebrate lineage. AmphiCoe is expressed in the central nervous system and in a small number of scattered ectodermal cells on the flanks of neurulae stage embryos. These cells become at least largely recessed beneath the ectoderm. Scanning electron microscopy was used to examine embryos in which the ectoderm had been partially peeled away. This revealed that these cells have neuronal morphology, and we infer that they are the precursors of epidermal primary sensory neurons. These characters lead us to suggest that differentiation of some ectodermal cells into sensory neurons with a tendency to sink beneath the embryonic surface represents a primitive feature that has become incorporated into placodes during vertebrate evolution.     

Sequence analysis of an amphioxus cosmid containing a gene homologous to members of the aldo-keto reductase gene superfamily

To gain an insight into vertebrate genome evolution, we have analysed the organization of an approximately 40-kb genomic clone of an amphioxus (Branchiostoma floridae) cosmid library. Amphioxus is considered as being the last non-vertebrate relative to vertebrates. Sequencing and analysis of the above clone using three different exon prediction programs (Grail, GenScan, Mzef) have led to the identification of a gene of the aldo-keto reductase family as well as further exons that gave a significant database match to known genes.     

Sipunculan ParaHox genes

SUMMARY Our perspective on the origin and evolution of the Hox gene cluster changed with the discovery of the ParaHox gene cluster in amphioxus (Cephalochordata; Branchiostoma floridae ) ( Brooke et al. 1998 ). The ParaHox gene cluster contains three homeobox genes (Gsx, Xlox, Cdx) and is deduced to be a paralogue (evolutionary sister) of the Hox gene cluster. If this deduction is correct, animals with Hox genes should also possess ParaHox genes. Paradoxically, however, only deuterostome animals have thus far been shown to contain all three ParaHox genes. Here we report the cloning of all three ParaHox genes from each of two species within the phylum Sipuncula. This is the first demonstration of all three ParaHox genes in the genome of a protostome animal and confirms that the common ancestor of protostomes and deuterostomes possessed all three ParaHox genes. Furthermore, it implies that the ParaHox genes are of sufficient functional importance in both protostomes and deuterostomes that they have all been conserved in both of these bilaterian clades.     

An amphioxus Msx gene expressed predominantly in the dorsal neural tube

 Genomic and cDNA clones of an Msx class homeobox gene were isolated from amphioxus (Branchiostoma floridae). The gene, AmphiMsx, is expressed in the neural plate from late gastrulation; in later embryos it is expressed in dorsal cells of the neural tube, excluding anterior and posterior regions, in an irregular reiterated pattern. There is transient expression in dorsal cells within somites, reminiscent of migrating neural crest cells of vertebrates. In larvae, mRNA is detected in two patches of anterior ectoderm proposed to be placodes. Evolutionary analyses show there is little phylogenetic information in Msx protein sequences; however, it is likely that duplication of Msx genes occurred in the vertebrate lineage. Received: 12 October 1998 / Accepted: 26 December 1998     

Origin and evolution of vertebrate ABCA genes: a story from amphioxus

Previous studies showed that the vertebrate ABCA subfamily, one subgroup of the ATP-binding-cassette superfamily, has evolved rapidly in terms of gene duplication and loss. To further uncover the evolutionary history of the ABCA subfamily, we characterized ABCA members of two amphioxus species (Branchiostoma floridae and B. belcheri), the closest living invertebrate relative to vertebrates. Phylogenetic analysis indicated that these two species have the same set of ABCA genes (both containing six members). Five of these genes have clear orthologs in vertebrate, including one cephalochordate-specific duplication and one vertebrate-specific duplication. In addition, it is found that human orthologs of amphioxus ABCA1/4/7 and its neighboring genes mainly localize on chromosome 1, 9, 19 and 5. Considering that most of analyzed amphioxus genes have clear orthologs in zebrafish, we conclude these four human paralogous regions might derive from a common ancestral region by genome duplication occurred prior to teleost/tetrapod split. Therefore, the present results provide new evidence for 2R hypothesis.     

Fgfrl1, a fibroblast growth factor receptor-like gene, is found in the cephalochordate Branchiostoma floridae but not in the urochordate Ciona intestinalis

FGFRL1 is a novel member of the fibroblast growth factor receptor family that controls the formation of musculoskeletal tissues. Some vertebrates, including man, cow, dog, mouse, rat and chicken, possess a single copy the FGFRL1 gene. Teleostean fish have two copies, fgfrl1a and fgfrl1b, because they have undergone a whole genome duplication. Vertebrates belong to the chordates, a phylum that also includes the subphyla of the cephalochordates (e.g. Branchiostoma floridae) and urochordates (tunicates, e.g. Ciona intestinalis). We therefore investigated whether other chordates might also possess an FGFRL1 related gene. In fact, a homologous gene was found in B. floridae (amphioxus). The corresponding protein showed 60% sequence identity with the human protein and all sequence motifs identified in the vertebrate proteins were also conserved in amphioxus Fgfrl1. In contrast, the genome of the urochordate C. intestinalis and those from more distantly related invertebrates including the insect Drosophila melanogaster and the nematode Caenorhabditis elegans did not appear to contain any related sequences. Thus, the FGFRL1 gene might have evolved just before branching of the vertebrate lineage from the other chordates.     

Unexpectedly large number of conserved noncoding regions within the ancestral chordate Hox cluster

The single amphioxus Hox cluster contains 15 genes and may well resemble the ancestral chordate Hox cluster. We have sequenced the Hox genomic complement of the European amphioxus Branchiostoma lanceolatum and compared it to the American species, Branchiostoma floridae, by phylogenetic footprinting to gain insights into the evolution of Hox gene regulation in chordates. We found that Hox intergenic regions are largely conserved between the two amphioxus species, especially in the case of genes located at the 3' of the cluster, a trend previously observed in vertebrates. We further compared the amphioxus Hox cluster with the human HoxA, HoxB, HoxC, and HoxD clusters, finding several conserved noncoding regions, both in intergenic and intronic regions. This suggests that the regulation of Hox genes is highly conserved across chordates, consistent with the similar Hox expression patterns in vertebrates and amphioxus.     

Analysis of the NADH-dependent retinaldehyde reductase activity of amphioxus retinol dehydrogenase enzymes enhances our understanding of the evolution of the retinol dehydrogenase family

In vertebrates, multiple microsomal retinol dehydrogenases are involved in reversible retinol/retinal interconversion, thereby controlling retinoid metabolism and retinoic acid availability. The physiologic functions of these enzymes are not, however, fully understood, as each vertebrate form has several, usually overlapping, biochemical roles. Within this context, amphioxus, a group of chordates that are simpler, at both the functional and genomic levels, than vertebrates, provides a suitable evolutionary model for comparative studies of retinol dehydrogenase enzymes. In a previous study, we identified two amphioxus enzymes, Branchiostoma floridae retinol dehydrogenase 1 and retinol dehydrogenase 2, both candidates to be the cephalochordate orthologs of the vertebrate retinol dehydrogenase enzymes. We have now proceeded to characterize these amphioxus enzymes. Kinetic studies have revealed that retinol dehydrogenase 1 and retinol dehydrogenase 2 are microsomal proteins that catalyze the reduction of all-trans-retinaldehyde using NADH as cofactor, a remarkable combination of substrate and cofactor preferences. Moreover, evolutionary analysis, including the amphioxus sequences, indicates that Rdh genes were extensively duplicated after cephalochordate divergence, leading to the gene cluster organization found in several mammalian species. Overall, our data provide an evolutionary reference with which to better understand the origin, activity and evolution of retinol dehydrogenase enzymes.