Guillaume Balavoine

Hox genes in brachiopods and priapulids and protostome evolution

Understanding the early evolution of animal body plans requires knowledge both of metazoan phylogeny and of the genetic and developmental changes involved in the emergence of particular forms. Recent 18S ribosomal RNA phylogenies suggest a three-branched tree for the Bilateria comprising the deuterostomes and two great protostome clades, the lophotrochozoans and ecdysozoans. Here, we show that the complement of Hox genes in critical protostome phyla reflects these phylogenetic relationships and reveals the early evolution of developmental regulatory potential in bilaterians. We have identified Hox genes that are shared by subsets of protostome phyla. These include a diverged pair of posterior (Abdominal-B -like) genes in both a brachiopod and a polychaete annelid, which supports the lophotrochozoan assemblage, and a distinct posterior Hox gene shared by a priapulid, a nematode and the arthropods, which supports the ecdysozoan clade. The ancestors of each of these two major protostome lineages had a minimum of eight to ten Hox genes. The major period of Hox gene expansion and diversification thus occurred before the radiation of each of the three great bilaterian clades.

Molecular Architecture of Annelid Nerve Cord Supports Common Origin of Nervous System Centralization in Bilateria

To elucidate the evolutionary origin of nervous system centralization, we investigated the molecular architecture of the trunk nervous system in the annelid Platynereis dumerilii. Annelids belong to Bilateria, an evolutionary lineage of bilateral animals that also includes vertebrates and insects. Comparing nervous system development in annelids to that of other bilaterians could provide valuable information about the common ancestor of all Bilateria. We find that the Platynereis neuroectoderm is subdivided into longitudinal progenitor domains by partially overlapping expression regions of nk and pax genes. These domains match corresponding domains in the vertebrate neural tube and give rise to conserved neural cell types. As in vertebrates, neural patterning genes are sensitive to Bmp signaling. Our data indicate that this mediolateral architecture was present in the last common bilaterian ancestor and thus support a common origin of nervous system centralization in Bilateria.

Vertebrate-type intron-rich genes in the marine annelid Platynereis dumerilii.

Previous genome comparisons have suggested that one important trend in vertebrate evolution has been a sharp rise in intron abundance. By using genomic data and expressed sequence tags from the marine annelid Platynereis dumerilii, we provide direct evidence that about two-thirds of human introns predate the bilaterian radiation but were lost from insect and nematode genomes to a large extent. A comparison of coding exon sequences confirms the ancestral nature of Platynereis and human genes. Thus, the urbilaterian ancestor had complex, intron-rich genes that have been retained in Platynereis and human.

Hox clusters and bilaterian phylogeny.

A large Hox cluster comprising at least seven genes has evolved by gene duplications in the ancestors of bilaterians. It probably emerged from a mini-cluster of three or four genes that was present before the divergence of cnidarians and bilaterians. The comparison of Hox structural data in bilaterian phyla shows that the genes of the anterior part of the cluster have been more conserved than those of the posterior part. Some specific signature sequences, present in the form of signature residues within the homeodomain or conserved peptides outside the homeodomain, constitute phylogenetic evidence for the monophyly of protostomes and their division into ecdysozoans and lophotrochozoans. These conserved motifs may provide decisive arguments for the phylogenetic position of some enigmatic phyla.

Arthropod-like Expression Patterns of engrailed and wingless in the Annelid Platynereis dumerilii Suggest a Role in Segment Formation

The origin of animal segmentation, the periodic repetition of anatomical structures along the anteroposterior axis, is a long-standing issue that has been recently revived by comparative developmental genetics. In particular, a similar extensive morphological segmentation (or metamerism) is commonly recognized in annelids and arthropods. Mostly based on this supposedly homologous segmentation, these phyla have been united for a long time into the clade Articulata. However, recent phylogenetic analysis dismissed the Articulata and thus challenged the segmentation homology hypothesis. Here, we report the expression patterns of genes orthologous to the arthropod segmentation genes engrailed and wingless in the annelid Platynereis dumerilii. In Platynereis, engrailed and wingless are expressed in continuous ectodermal stripes on either side of the segmental boundary before, during, and after its formation; this expression pattern suggests that these genes are involved in segment formation. The striking similarities of engrailed and wingless expressions in Platynereis and arthropods may be due to evolutionary convergence or common heritage. In agreement with similarities in segment ontogeny and morphological organization in arthropods and annelids, we interpret our results as molecular evidence of a segmented ancestor of protostomes.

caudal and even‐skipped in the annelid Platynereis dumerilii and the ancestry of posterior growth

Summary In order to address the question of the conservation of posterior growth mechanisms in bilaterians, we have studied the expression patterns of the orthologues of the genes caudal, even‐skipped, and brachyury in the annelid Platynereis dumerilii. Annelids belong to the still poorly studied third large branch of the bilaterians, the lophotrochozoans, and have anatomic and developmental characteristics, such as a segmented body plan, indirect development through a microscopic ciliated larva, and building of the trunk through posterior addition, which are all hypothesized by some authors (including us) to be present already in Urbilateria, the last common ancestor of bilaterians. All three genes are shown to be likely involved in the building of the anteroposterior axis around the slit‐like amphistomous blastopore as well as in the patterning of the terminal anus‐bearing piece of the body (the pygidium). In addition, caudal and even‐skipped are likely involved in the posterior addition of segments. Together with the emerging results on the conservation of segmentation genes, these results reinforce the hypothesis that Urbilateria had a segmented trunk developing through posterior addition.

Phylogenetic Analysis of the Wnt Gene Family: Insights from Lophotrochozoan Members

The Wnt gene family encodes secreted signaling molecules that control cell fate specification, proliferation, polarity, and movements during animal development. We investigate here the evolutionary history of this large multigenic family. Wnt genes have been almost exclusively isolated from two of the three main subdivisions of bilaterian animals, the deuterostomes (which include chordates and echinoderms) and the ecdysozoans (e.g., arthropods and nematodes). However, orthology relationships between deuterostome and ecdysozoan Wnt genes, and, more generally, the phylogeny of the Wnt family, are not yet clear. We report here the isolation of several Wnt genes from two species, the annelid Platynereis dumerilii and the mollusc Patella vulgata, which both belong to the third large bilaterian clade, the lophotrochozoans (which constitute, together with ecdysozoans, the protostomes). Multiple phylogenetic analyses of these sequences with a large set of other Wnt gene sequences, in particular, the complete set of Wnt genes of human, nematode, and fly, allow us to subdivide the Wnt family into 12 subfamilies. At least nine of them were already present in the last common ancestor of all bilaterian animals, and this further highlights the genetic complexity of this ancestor. The orthology relationships we present here open new perspectives for future developmental comparisons.

Hedgehog Signaling Regulates Segment Formation in the Annelid Platynereis

Hedgehog and Segmentation Segmentation is a key characteristic of body plan organization in some of the largest animal groups, including annelids, arthropods, and vertebrates, but its evolutionary origins remain debated. In arthropod embryos, the Hedgehog signaling pathway plays a crucial role in the axial patterning of developing segments. Dray et al. (p. 339) analyzed the function of this conserved pathway in the annelid worm Platynereis by using specific small molecule inhibitors and found a similar role for Hedgehog signaling in shaping segments in this animal. Thus, Hedgehog was involved in segment formation in the last common ancestor of the protostome animals, earlier in metazoan evolution than previously assumed. The processes that pattern body segmentation in annelids and arthropods both require the same signaling mechanism. Annelids and arthropods share a similar segmented organization of the body whose evolutionary origin remains unclear. The Hedgehog signaling pathway, prominent in arthropod embryonic segment patterning, has not been shown to have a similar function outside arthropods. We show that the ligand Hedgehog, the receptor Patched, and the transcription factor Gli are all expressed in striped patterns before the morphological appearance of segments in the annelid Platynereis dumerilii. Treatments with small molecules antagonistic to Hedgehog signaling disrupt segment formation. Platynereis Hedgehog is not necessary to establish early segment patterns but is required to maintain them. The molecular similarity of segment patterning functions of the Hedgehog pathway in an annelid and in arthropods supports a common origin of segmentation in protostomes.

The SM19 gene, required for duplication of basal bodies in Paramecium, encodes a novel tubulin, η-tubulin

The discovery of delta-tubulin, the fourth member of the tubulin superfamily, in Chlamydomonas [1] has led to the identification in the genomes of vertebrates and protozoa of putative delta homologues and of additional tubulins, epsilon and zeta [2-4]. These discoveries raise questions concerning the functions of these novel tubulins, their interactions with microtubule arrays and microtubule-organising centres, and their evolutionary status. The sm19-1 mutation of Paramecium specifically inhibits basal body duplication [5] and causes delocalisation of gamma-tubulin, which is also required for basal body duplication [6]. We have cloned the SM19 gene by functional complementation and found that it encodes another new member of the tubulin superfamily. SM19p, provisionally called eta-tubulin (eta-tubulin), shows low sequence identity with the tubulins previously identified in Paramecium, namely, alpha [7], beta [8], gamma [6], delta (this work) and epsilon (P. Dupuis-Williams, personal communication). Phylogenetic analysis indicated that SM19p is not consistently grouped with any phylogenetic entity.

The Segmented Urbilateria: A Testable Scenario

Abstract The idea that the last common ancestor of bilaterian animals (Urbilateria) was segmented has been raised recently on evidence coming from comparative molecular embryology. Leaving aside the complex debate on the value of genetic evidence, the morphological and developmental evidence in favor of a segmented Urbilateria are discussed in the light of the emerging molecular phylogeny of metazoans. Applying a cladistic character optimization procedure to the question of segmentation is vastly complicated by the problem of defining without ambiguity what segmentation is and to what taxa this definition applies. An ancestral segmentation might have undergone many complex derivations in each different phylum, thus rendering the cladistics approaches problematic. Taking the most general definitions of coelom and segmentation however, some remarkably similar patterns are found across the bilaterian tree in the way segments are formed by the posterior addition of mesodermal segments or somites. Postulating that these striking similarities in mesodermal patterns are ancestral, a scenario for the diversification of bilaterians from a metameric ancestor is presented. Several types of evolutionary mechanisms (specialization, tagmosis, progenesis) operating on a segmented ancestral body plan would explain the rapid emergence of body plans during the Cambrian. We finally propose to test this hypothesis by comparing genes involved in mesodermal segmentation.