More genes in vertebrates?

With the acquisition of complete genome sequences from several animals, there is renewed interest in the pattern of genome evolution on our own lineage. One key question is whether gene number increased during chordate or vertebrate evolution. It is argued here that comparing the total number of genes between a fly, a nematode and human is not appropriate to address this question. Extensive gene loss after duplication is one complication; another is the problem of comparing taxa that are phylogenetically very distant. Amphioxus and tunicates are more appropriate animals for comparison to vertebrates. Comparisons of clustered homeobox genes, where gene loss can be identified, reveals a one to four mode of evolution for Hox and ParaHox genes. Analyses of other gene families in amphioxus and vertebrates confirm that gene duplication was very widespread on the vertebrate lineage. These data confirm that vertebrates have more genes than their closest invertebrate relatives, acquired through gene duplication. abbreviations IHGSC, International Human Genome Sequencing Consortium; TCESC, The C. elegans Sequencing Consortium.     

Polyploidy in vertebrate ancestry: Ohno and beyond

Over 30 years ago, Susumu Ohno proposed that two rounds of polyploidy occurred early in vertebrate evolution. We re-examine this proposal using three recent lines of evidence. First, total gene number estimates from completely sequenced genomes suggest an increase in total gene number somewhere along the vertebrate or prevertebrate lineage, compatible with Ohno's model. Second, analyses of homeobox and other genes from amphioxus reveal very extensive gene duplication specifically on the vertebrate lineage. This refines the timing of putative polyploidy to after the divergence of amphioxus and vertebrates. Third, the existence of four-fold paralogy regions in the human genome is suggestive of two rounds of polyploidy, although other explanations are possible. We propose an experimental test, based on chromosomal localization of genes in amphioxus, that should resolve whether paralogy regions are indeed remnants of duplication in vertebrate ancestry.  © 2004 The Linnean Society of London, Biological Journal of the Linnean Society , 2004, 82 , 425–430.     

HomeoDB: a database of homeobox gene diversity

The homeobox genes are a large and diverse group of genes, many of which play important roles in the embryonic development of animals. Comparative study of homeobox genes, both within and between species, requires an evolutionary-based classification. HomeoDB was designed and implemented as a manually curated database to collect and present homeobox genes in an evolutionarily structured way, allowing genes, gene families and gene classes to be compared between species more readily than was possible previously. In its first release, HomeoDB includes all homeobox genes from human, amphioxus (Branchiostoma floridae) and fruitfly (Drosophila melanogaster); additional species can be added. HomeoDB is freely accessible at (http://homeodb.cbi.pku.edu.cn).     

Evolution of CUT class homeobox genes: insights from the genome of the amphioxus, Branchiostoma floridae

CUT class homeobox genes, including CUX/CASP, ONECUT, SATB and COMPASS family genes, are known to exhibit diverse features in the homeodomain and the domain architecture. Furthermore, the intron/exon organization of CUX/CASP is different between vertebrates and protostomes, and SATB genes are only known for vertebrates, whereas COMPASS genes have only been found in protostomes. These observations suggest a complex evolutionary history for the CUT class homeobox genes, but the evolution of CUT class homeobox genes in the lineage to vertebrates remained largely unknown. To obtain clearer insights into this issue, we searched the genome of amphioxus, Branchiostoma floridae, a lower chordate, for CUT class homeobox genes by extensive BLAST survey and phylogenetic analyses. We found that the genome of Branchiostoma floridae encodes each single orthologue of CUX/CASP, ONECUT, and COMPASS, but not the SATB gene, and one atypical CUT gene likely specific to this species. In addition, the genomic structure of the amphioxus CUX/CASP gene turned out to be protostome-type, but not vertebrate-type. Based on these observations, we propose a model in which SATB is suggested to evolve at the expense of COMPASS and this change, together with the structural change in CUX/CASP, is supposed to take place in the lineage to vertebrates after divergence of the amphioxus and vertebrate ancestors. The present study provides an example of dramatic evolution among homeobox gene groups in the vertebrate lineage and highlights the ancient character of amphioxus, retaining genomic features shared by protostomes.     

Isolation of Hox genes from the scyphozoan Cassiopeia xamachana: implications for the early evolution of Hox genes.

The isolation of Hox genes from two cnidarian groups, the Hydrozoa and Anthozoa, has sparked hypotheses on the early evolution of Hox genes and a conserved role for these genes for defining a main body axis in all metazoan animals. We have isolated the first five Hox genes, Scox-1 to Scox-5, from the third cnidarian class, the Scyphozoa. For all but one gene, we report full-length homeobox plus flanking sequences. Four of the five genes show close relationship to previously reported Cnox-1 genes from Hydrozoa and Anthozoa. One gene, Scox-2, is an unambiguous homologue of Cnox-2 genes known from Hydrozoa, Anthozoa, and also Placozoa. Based on sequence similarity and phylogenetic analyses of the homeobox and homeodomain sequences of known Hox genes from cnidarians, we suggest the presence of at least five distinct Hox gene families in this phylum, and conclude that the last common ancestor of the Recent cnidarian classes likely possessed a set of Hox genes representing three different families, the Cnox-1, Cnox-2, and Cnox-5 families. The data presented are consistent with the idea that multiple duplication events of genes have occurred within one family at the expense of conservation of the original set of genes, which represent the three ancestral Hox gene families.     

Phylogenetic analysis of T-Box genes demonstrates the importance of amphioxus for understanding evolution of the vertebrate genome

The duplication of preexisting genes has played a major role in evolution. To understand the evolution of genetic complexity it is important to reconstruct the phylogenetic history of the genome. A widely held view suggests that the vertebrate genome evolved via two successive rounds of whole-genome duplication. To test this model we have isolated seven new T-box genes from the primitive chordate amphioxus. We find that each amphioxus gene generally corresponds to two or three vertebrate counterparts. A phylogenetic analysis of these genes supports the idea that a single whole-genome duplication took place early in vertebrate evolution, but cannot exclude the possibility that a second duplication later took place. The origin of additional paralogs evident in this and other gene families could be the result of subsequent, smaller-scale chromosomal duplications. Our findings highlight the importance of amphioxus as a key organism for understanding evolution of the vertebrate genome.     

The Mnx homeobox gene class defined by HB9, MNR2 and amphioxus AmphiMnx

The HB9 homeobox gene has been cloned from several vertebrates and is implicated in motor neuron differentiation. In the chick, a related gene, MNR2, acts upstream of HB9 in this process. Here we report an amphioxus homologue of these genes and show that it diverged before the gene duplication yielding HB9 and MNR2. AmphiMnx RNA is detected in two irregular punctate stripes along the developing neural tube, comparable to the distribution of 'dorsal compartment' motor neurons, and also in dorsal endoderm and posterior mesoderm. We propose a new homeobox class, Mnx, to include AmphiMnx, HB9, MNR2 and their Drosophila and echinoderm orthologues; we suggest that vertebrate HB9 is renamed Mnx1 and MNR2 be renamed Mnx2.     

Evolutionary and polymorphic organization of the knotted1 homeobox in cereals

 Homeobox genes are the master control genes harbouring the homeobox which is crucial for developmental associated functions. One homeobox gene, knotted1, which has a role in leaf development, is conserved in plants and might have arisen from a single ancestral gene. Using PCR, we identified multiple kn1 homeoboxes in diverse cereals and showed a cereal/ species-specific organization correlating them to evolutionary changes. We postulate the insertion of a large intron preceded by duplication of the kn1 homeobox in the lineage leading to rice. Received: 17 October 1997 / Accepted: 9 December 1997     

A degenerate ParaHox gene cluster in a degenerate vertebrate

The ParaHox genes consist of 3 homeobox gene families, Gsx, Xlox, and Cdx, all of which have fundamental roles in development. Xlox (known as IPF1 or PDX1 in vertebrates), for example, is crucial for development of the vertebrate pancreas and is also involved in regulation of insulin expression. The invertebrate amphioxus has a gene cluster containing one gene from each of the gene families, whereas in all vertebrates examined to date there are additional copies resultant from ParaHox gene cluster duplications at the base of the vertebrate lineage. Extant vertebrates basal to bony and cartilaginous fish are central to the question of when and how these multiple genes arose in the vertebrate genome. Here, we report the mapping of a ParaHox gene cluster in 2 species of hagfishes. Unexpectedly, these basal vertebrates have lost a functional Xlox gene from this cluster, unlike every other vertebrate examined to date. Furthermore, our phylogenetic analyses suggest that hagfishes may have diverged from the vertebrate lineage before the duplications, which created the multiple ParaHox clusters in jawed vertebrates.     

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.     

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.     

Genes of the lipase family: comparison of nucleic and proteinic sequences]

Vertebrates' plasmatic apolipoproteins and a few number of lipases in their metabolism present sequence homologies. They are grouped in genes families. The four exons apolipoproteins gene family includes nine human genes: the divergence rate of their sequences allows to place the first ancestral gene very high in the phylogenetic tree of the evolution. However, a more recent duplication of apolipoprotein C-I gene dating from 40 millions years, may be a phylogenetic marker for the radiation of Monkeys. Pancreatic lipase and isoforms, lipoprotein-lipase and hepatic triacylglycerol-lipase form by their homologies a "superfamily" of genes, which also includes yolk proteins of Dipterians eggs. Sequence homologies of PL, LPL and HL are analysed and compared with multiple alignments of amino-acids and nucleotides on spreadsheets. From these comparisons we may characterize four classes of phylogenetic markers: 1) repetitive DNA sequence (Alu, B1, PRE-1) appeared during Mammals evolution, 2) short insertions or deletions (within N-terminal domain) and a gene conversion in guinea-pig lineage, 3) a progressive reduction of intron number during the lipases evolution, 4) several duplications of genes which have produced the five genes of this superfamily currently known in the human genome.     

Progress in Arabidopsis genome sequencing and functional genomics

Arabidopsis thaliana has a relatively small genome of approximately 130 Mb containing about 10% repetitive DNA. Genome sequencing studies reveal a gene-rich genome, predicted to contain approximately 25000 genes spaced on average every 4.5 kb. Between 10 to 20% of the predicted genes occur as clusters of related genes, indicating that local sequence duplication and subsequent divergence generates a significant proportion of gene families. In addition to gene families, repetitive sequences comprise individual and small clusters of two to three retroelements and other classes of smaller repeats. The clustering of highly repetitive elements is a striking feature of the A. thaliana genome emerging from sequence and other analyses.     

The single amphioxus Mox gene: insights into the functional evolution of Mox genes,somites, and the asymmetry of amphioxus somitogenesis

Mox genes are members of the "extended" Hox-cluster group of Antennapedia-like homeobox genes. Homologues have been cloned from both invertebrate and vertebrate species, and are expressed in mesodermal tissues. In vertebrates, Mox1 and Mox2 are distinctly expressed during the formation of somites and differentiation of their derivatives. Somites are a distinguishing feature uniquely shared by cephalochordates and vertebrates. Here, we report the cloning and expression of the single amphioxus Mox gene. AmphiMox is expressed in the presomitic mesoderm (PSM) during early amphioxus somitogenesis and in nascent somites from the tail bud during the late phase. Once a somite is completely formed, AmphiMox is rapidly downregulated. We discuss the presence and extent of the PSM in both phases of amphioxus somitogenesis. We also propose a scenario for the functional evolution of Mox genes within chordates, in which Mox was co-opted for somite formation before the cephalochordate-vertebrate split. Novel expression sites found in vertebrates after somite formation postdated Mox duplication in the vertebrate stem lineage, and may be linked to the increase in complexity of vertebrate somites and their derivatives, e.g., the vertebrae. Furthermore, AmphiMox expression adds new data into a long-standing debate on the extent of the asymmetry of amphioxus somitogenesis.