Fumiko Yoshizaki

The amphioxus genome illuminates vertebrate origins and cephalochordate biology

Cephalochordates, urochordates, and vertebrates evolved from a common ancestor over 520 million years ago. To improve our understanding of chordate evolution and the origin of vertebrates, we intensively searched for particular genes, gene families, and conserved noncoding elements in the sequenced genome of the cephalochordate Branchiostoma floridae, commonly called amphioxus or lancelets. Special attention was given to homeobox genes, opsin genes, genes involved in neural crest development, nuclear receptor genes, genes encoding components of the endocrine and immune systems, and conserved cis-regulatory enhancers. The amphioxus genome contains a basic set of chordate genes involved in development and cell signaling, including a fifteenth Hox gene. This set includes many genes that were co-opted in vertebrates for new roles in neural crest development and adaptive immunity. However, where amphioxus has a single gene, vertebrates often have two, three, or four paralogs derived from two whole-genome duplication events. In addition, several transcriptional enhancers are conserved between amphioxus and vertebrates--a very wide phylogenetic distance. In contrast, urochordate genomes have lost many genes, including a diversity of homeobox families and genes involved in steroid hormone function. The amphioxus genome also exhibits derived features, including duplications of opsins and genes proposed to function in innate immunity and endocrine systems. Our results indicate that the amphioxus genome is elemental to an understanding of the biology and evolution of nonchordate deuterostomes, invertebrate chordates, and vertebrates.

Primitive complement system of invertebrates.

Summary:  Most components of the human complement system have unmistakable domain architectures, making evolutionary tracing feasible. In contrast to the major genes of the adaptive immune system, which are present only in jawed vertebrates, complement component genes with unique domain structures are present not only in jawed vertebrates but also in jawless fish and non‐vertebrate deuterostomes. Recent progress in genome analysis in several eukaryotes, occupying the phylogenetically critical positions, showed that most individual domains found in the complement components are metazoa specific, being found both in deuterostomes and in protostomes but not in yeast or plant. However, unique domain architecture of complement components is not present in protostomes, suggesting that the complement system has been established in the deuterostome lineage not by invention of new domains but by innovation of unique combination of the pre‐existing domains. The recently assembled Ciona intestinalis draft genome contained the most modular complement genes, except for factor I. However, some possible C. intestinalis complement components show critical structural divergence from the mammalian counterparts, casting doubt on their mutual interaction. Thus, another integrative step seems to have been required to establish the modern complement system of higher vertebrates.

Structure and the evolutionary implication of the triplicated complement factor B genes of a urochordate ascidian, Ciona intestinalis

To elucidate the evolution of the complement system and MHC class III region, we analyzed the complement factor B (Bf) genes of a urochordate ascidian, Ciona intestinalis. Three different cDNA species, termed CiBf-1, CiBf-2 and CiBf-3, were identified. The deduced amino-acid sequences all contained the usual domains of vertebrate Bf and, in addition, three extra domains at the N-terminus. Furthermore, the serine protease domain of these CiBfs shared unique features with vertebrate complement components C1r/s and mannose-binding lectin-associated serine protease (MASP)-2/3, the absence of the disulfide bond designated histidine loop, and the usage of the AGY codon for the catalytic serine residue. These results indicate that complement genes have evolved through extensive exon shuffling events in the early stage of chordate evolution. Overall deduced amino-acid identity between CiBf-1 and -2 was 88%, whereas CiBf-3 showed 49% identity to both CiBf-1 and CiBf-2. These three CiBf genes were located within an approximately 50-kb genomic region, and exons 3 and 5 of all the three Bf genes showed an extremely high degree of nucleotide identity, indicating that the CiBf genes experienced extensive reorganization, such as duplication and gene conversion, since its divergence from the vertebrate Bf/C2 gene. Fluorescent in situ hybridization (FISH) to the chromosomes showed that genetic loci for the CiBfs, CiC3-1 and CiC3-2 genes are present on three different chromosomes, suggesting the possibility that the linkage among the MHC class III complement genes was established in the vertebrate lineage after its divergence from urochordates.

Fluorescent in situ hybridization to ascidian chromosomes.

The draft genome of the ascidian Ciona intestinalis has been sequenced. Mapping of the genome sequence to the Ciona 14 haploid chromosomes is essential for future studies of the genome-wide control of gene expression in this basal chordate. Here we describe an efficient protocol for fluores-cent in situ hybridization for mapping genes to the Ciona chromosomes. We demonstrate how the locations of two BAC clones can be mapped relative to each other. We also show that this method is efficient for coupling two so-far independent scaffolds into one longer scaffold when two BAC clones represent sequences located at either end of the two scaffolds.