Jordi Garcia-Fernàndez

The amphioxus genome and the evolution of the chordate karyotype.

Lancelets (‘amphioxus’) are the modern survivors of an ancient chordate lineage, with a fossil record dating back to the Cambrian period. Here we describe the structure and gene content of the highly polymorphic ∼520-megabase genome of the Florida lancelet Branchiostoma floridae, and analyse it in the context of chordate evolution. Whole-genome comparisons illuminate the murky relationships among the three chordate groups (tunicates, lancelets and vertebrates), and allow not only reconstruction of the gene complement of the last common chordate ancestor but also partial reconstruction of its genomic organization, as well as a description of two genome-wide duplications and subsequent reorganizations in the vertebrate lineage. These genome-scale events shaped the vertebrate genome and provided additional genetic variation for exploitation during vertebrate evolution.

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.

The ParaHox gene cluster is an evolutionary sister of the Hox gene cluster

Genes of the Hox cluster are restricted to the animal kingdom and play a central role in axial patterning in divergent animal phyla. Despite its evolutionary and developmental significance, the origin of the Hox gene cluster is obscure. The consensus is that a primordial Hox cluster arose by tandem gene duplication close to animal origins. Several homeobox genes with high sequence identity to Hox genes are found outside the Hox cluster and are known as ‘dispersed’ Hox-like genes; these genes may have been transposed away from an expanding cluster. Here we show that three of these dispersed homeobox genes form a novel gene cluster in the cephalochordate amphioxus. We argue that this ‘ParaHox’ gene cluster is an ancient paralogue (evolutionary sister) of the Hox gene cluster; the two gene clusters arose by duplication of a ProtoHox gene cluster. Furthermore, we show that amphioxus ParaHox genes have co-linear developmental expression patterns in anterior, middle and posterior tissues. We propose that the origin of distinct Hox and ParaHox genes by gene-cluster duplication facilitated an increase in body complexity during the Cambrian explosion.

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.

Hox, ParaHox, ProtoHox: facts and guesses

The Hox gene cluster has captivated the imagination of evolutionary and developmental biologists worldwide. In this review, the origin of the Hox and ParaHox gene clusters by duplication of a ProtoHox gene cluster, and the changes in their gene numbers in major Metazoan Transitions are reviewed critically. Re-evaluation of existing data and recent findings in Cnidarians, Acoels, and critical stages of vertebrate evolution suggest alternative scenarios for the origin, structure, and changes in Hox gene numbers in relevant events of Metazoan evolution. I discuss opposing views and propose that (i) the ProtoHox cluster had only two genes, and not four as commonly believed: a corollary is that the origin of Bilaterians was coincident with the invention of new Hox and ParaHox gene classes, which may have facilitated such a transition; (ii) the ProtoHox cluster duplication was a cis duplication event, rather than a trans duplication event, as previously suggested, and (iii) the ancestral vertebrate cluster possessed 14 Hox genes, and not the 13 generally assumed. These hypotheses could be verified or refuted in the near future, but they may help critical discussion of the evolution of the Hox/ParaHox family in the metazoan kingdom.

Evolution of the Nitric Oxide Synthase Family in Metazoans

Nitric oxide (NO) is essential to many physiological functions and operates in several signaling pathways. It is not understood how and when the different isoforms of nitric oxide synthase (NOS), the enzyme responsible for NO production, evolved in metazoans. This study investigates the number and structure of metazoan NOS enzymes by genome data mining and direct cloning of Nos genes from the lamprey. In total, 181 NOS proteins are analyzed from 33 invertebrate and 63 vertebrate species. Comparisons among protein and gene structures, combined with phylogenetic and syntenic studies, provide novel insights into how NOS isoforms arose and diverged. Protein domains and gene organization--that is, intron positions and phases--of animal NOS are remarkably conserved across all lineages, even in fast-evolving species. Phylogenetic and syntenic analyses support the view that a proto-NOS isoform was recurrently duplicated in different lineages, acquiring new structural configurations through gains and losses of protein motifs. We propose that in vertebrates a first duplication took place after the agnathan-gnathostome split followed by a paralog loss. A second duplication occurred during early tetrapod evolution, giving rise to the three isoforms--I, II, and III--in current mammals. Overall, NOS family evolution was the result of multiple gene and genome duplication events together with changes in protein architecture.

Gene Expansion and Retention Leads to a Diverse Tyrosine Kinase Superfamily in Amphioxus

Tyrosine kinase (TK) proteins play a central role in cellular behavior and development of animals. The expansion of this superfamily is regarded as a key event in the evolution of the complex signaling pathways and gene networks of metazoans and is a prominent example of how shuffling of protein modules may generate molecular novelties. Using the intron/exon structure within the TK domain (TK intron code) as a complementary tool for the assignment of orthology and paralogy, we identified and studied the 118 TK proteins of the amphioxus Branchiostoma floridae genome to elucidate TK gene family evolution in metazoans and chordates in particular. Unlike all characterized metazoans to date, amphioxus has members of all known widespread TK families, with not a single loss. Putting amphioxus TKs in an evolutionary context, including new data from the cnidarian Nematostella vectensis, the echinoderm Strongylocentrotus purpuratus, and the ascidian Ciona intestinalis, we suggest new evolutionary histories for different TK families and draw a new global picture of gene loss/gain in the different phyla. Surprisingly, our survey also detected an unprecedented expansion of a group of closely related TK families, including TIE, FGFR, PDGFR, and RET, due most probably to massive gene duplication and exon shuffling. Based on their highly similar intron/exon structure at the TK domain, we suggest that this group of TK families constitute a superfamily of TK proteins, which we termed EXpanding TK, after their seemingly unique propensity to gene duplication and exon shuffling, not only in amphioxus but also across all metazoan groups. Due to this extreme tendency to both retention and expansion of TK genes, amphioxus harbors the richest and most diverse TK repertoire among all metazoans studied so far, retaining most of the gene complement of its ancestors, but having evolved its own repertoire of genetic novelties.

Growth, Degrowth and Regeneration as Developmental Phenomena in Adult Freshwater Planarians

Freshwater planarians are Platyhelminthes belonging to the class Turbellaria, order Seriata, suborder Tricladida, infra-order Paludicola. The term Tricladida (or triclads) refers to the three main branches into which their digestive system are divided; Paludicola means members are inhabitants of freshwater habitats. Freshwater planarians are the best known planarians due to there easy culture and ease of handling under laboratory conditions and, because they have been, and still are, the most widely used turbellarian in experimental research, particularly with regards to regeneration (see Bronsted, 1969, and Gremigni, 1988, for general references).

The single AmphiTrk receptor highlights increased complexity of neurotrophin signalling in vertebrates and suggests an early role in developing sensory neuroepidermal cells

Neurotrophins (Nt) and their tyrosine kinase Trk receptors play an essential role in the development and maintenance of the complex vertebrate nervous system. Invertebrate genome sequencing projects have suggested that the Nt/Trk system is a vertebrate innovation. We describe the isolation and characterisation of the amphioxus Trk receptor, AmphiTrk. Its ancestral link to vertebrate Trk receptors is supported by phylogenetic analysis and domain characterisation. The genomic structure of AmphiTrk strongly suggests that a ProtoTrk gene emerged by means of exon-shuffling prior to the cephalochordate/vertebrate split. We also examined the physiological response of AmphiTrk to vertebrate neurotrophins, and found that despite 500 million years of divergence, AmphiTrk transduces signals mediated by NGF, BDNF, NT3 and NT4. Markedly, AmphiTrk is able to activate survival and differentiation pathways, but fails to activate the PLCγ pathway, which is involved in synaptic plasticity in higher vertebrates. AmphiTrk is expressed during amphioxus embryogenesis in sensory neural precursors in the epidermis, which possesses single migratory cells. We propose that the duplication and divergence of the Nt/Trk system, in tandem with recruitment of the PLCγ pathway, may have provided the genetic basis for a key aspect of vertebrate evolution: the complexity of the nervous system.

Transphyletic conservation of developmental regulatory state in animal evolution

Specific regulatory states, i.e., sets of expressed transcription factors, define the gene expression capabilities of cells in animal development. Here we explore the functional significance of an unprecedented example of regulatory state conservation from the cnidarian Nematostella to Drosophila, sea urchin, fish, and mammals. Our probe is a deeply conserved cis-regulatory DNA module of the SRY-box B2 (soxB2), recognizable at the sequence level across many phyla. Transphyletic cis-regulatory DNA transfer experiments reveal that the plesiomorphic control function of this module may have been to respond to a regulatory state associated with neuronal differentiation. By introducing expression constructs driven by this module from any phyletic source into the genomes of diverse developing animals, we discover that the regulatory state to which it responds is used at different levels of the neurogenic developmental process, including patterning and development of the vertebrate forebrain and neurogenesis in the Drosophila optic lobe and brain. The regulatory state recognized by the conserved DNA sequence may have been redeployed to different levels of the developmental regulatory program during evolution of complex central nervous systems.