Limited microsynteny between the genomes of Pristionchus pacificus and Caenorhabditis elegans

Nematodes are an attractive group of organisms for studying the evolution of developmental processes. Pristionchus pacificus was established as a satellite organism for comparing vulva development and other processes to Caenorhabditis elegans. The generation of a genetic linkage map of P.pacificus has provided a first insight into the structure and organization of the genome of this species. Pristionchus pacificus and C.elegans are separated from one another by >100 000 000 years such that the structure of the genomes of these two nematodes might differ substantially. To evaluate the amount of synteny between the two genomes, we have obtained 126 kb of continuous genomic sequence of P.pacificus, flanking the developmental patterning gene pal-1. Of the 20 predicted open reading frames in this interval, 11 have C.elegans orthologs. Ten of these 11 orthologs are located on C.elegans chromosome III, indicating the existence of synteny. However, most of these genes are distributed over a 12 Mb interval of the C.elegans genome and only three pairs of genes show microsynteny. Thus, intrachromosomal rearrange ments occur frequently in nematodes, limiting the likelihood of identifying orthologous genes of P.pacificus and C.elegans based on positional information within the two genomes.     

Changing of the cell division axes drives vulva evolution in nematodes

Vulval epithelial tubes invaginate through concerted cell migration, ring formation, stacking of rings and intra-ring cell fusion in the nematodes Caenorhabditis elegans, Oscheius tipulae and Pristionchus pacificus. The number of rings forming the invaginations is invariantly seven, six, and eight, respectively. We hypothesize that each ring is formed from pairs of symmetrically positioned primordial vulval cells following three premises: If the final cell division is left-right, the daughters will fuse, migrate and form only one ring. If these cells do not divide, one ring will form. If the final division is anterior-posterior, two rings will form. We test the ring hypothesis and found coincidence between the patterns of vulva cell divisions and the number of rings for 12 species. We find heterochronic variations in the timing of division, migration and fusion of the vulval cells between species. We report a unique ring-independent pathway of vulva formation in Panagrellus redivivus. C. elegans lin-11(n389) mutation results in cell fate transformations including changes in the orientation of vulval cell division. lin-11 animals have an additional ring, as predicted by the ring hypothesis. We propose that the genetic pathway determining how vulval cells invaginate evolves through ring-dependent and ring-independent mechanisms.     

The two steps of vulval induction in Oscheius tipulae CEW1 recruit common regulators including a MEK kinase

The cell interactions that specify the spatial pattern of vulval precursor cell (VPC) fates differ between the nematodes Oscheius tipulae CEW1 and Caenorhabditis elegans. In the former, the centered pattern of fates is obtained by two successive inductions from the gonadal anchor cell, whereas in the latter, a single inductive step by the anchor cell (EGF-Ras-MAP kinase pathway) can act as a morphogen and is reinforced by lateral signaling between the vulval precursors (Notch pathway). We performed a genetic screen for vulva mutants in O. tipulae CEW1. Here we present the mutants that specifically affect the vulval induction mechanisms. Phenotypic and epistatic analyses of these mutants show that both vulval induction steps share common components, one of which appears to be MEK kinase(s). Moreover, the inductive pathway (including MEK kinase) influences the competence of the vulval precursor cells and more strikingly their division pattern as well, irrespective of their vulval fate. Finally, a comparison of vulval mutant phenotypes obtained in C. elegans and O. tipulae CEW1 highlights the evolution of vulval induction mechanisms between the two species.     

A subset of naturally isolated Bacillus strains show extreme virulence to the free‐living nematodes Caenorhabditis elegans and Pristionchus pacificus

The main food source of free‐living nematodes in the soil environment is bacteria, which can affect nematode development, fecundity and survival. In order to occupy a reliable source of bacterial food, some nematodes have formed specific relationships with an array of invertebrate hosts (where bacteria proliferate once the hosts dies), thus forming a tritrophic system of nematode, bacteria and insect or other invertebrates. We isolated 768 Bacillus strains from soil (from Germany and the UK), horse dung and dung beetles and fed them to the genetically tractable free‐living nematodes Caenorhabditis elegans and Pristionchus pacificus to isolate nematocidal strains. While C. elegans is a bacteriovorous soil nematode, P. pacificus is an omnivorous worm that is often found in association with scarab beetles. We found 20 Bacillus strains (consisting of B. cereus, B. weihenstephanensis, B. mycoides and Bacillus sp.) that were pathogenic to C. elegans and P. pacificus causing 70% to 100% mortality over 5 days and significantly affect development and brood size. The most pathogenic strains are three B. cereus‐like strains isolated from dung beetles, which exhibit extreme virulence to C. elegans in less than 24 h, but P. pacificus remains resistant. C. elegans Bre mutants were also highly susceptible to the B. cereus‐like strains indicating that their toxins use a different virulence mechanism than B. thuringiensis Cry 5B toxin. Also, mutations in the daf‐2/daf‐16 insulin signaling pathway do not rescue survival. We profiled the toxin genes (bcet, nhe complex, hbl complex, pcpl, sph, cytK, piplc, hly2, hly3, entFM and entS) of these three B. cereus‐like strains and showed presence of most toxin genes but absence of the hbl complex. Taken together, this study shows that the majority of naturally isolated Bacillus from soil, horse dung and Geotrupes beetles are benign to both C. elegans and P. pacificus. Among 20 pathogenic strains with distinct virulence patterns against the two nematodes, we selected three B. cereus‐like strains to investigate resistance and susceptibility immune responses in nematodes.     

The anchor cell initiates dorsal lumen formation during C. elegans vulval tubulogenesis

Tubulogenesis and lumen formation are critical to the development of most organs. We study Caenorhabditis elegans vulval and uterine development to probe the complex mechanisms that mediate these events. Development of the vulva and the ventral uterus is coordinated by the inductive cell-signaling activity of a gonadal cell called the anchor cell (AC). We demonstrate that in addition to its function in specifying fate, the AC directly promotes dorsal vulval tubulogenesis. Two types of mutants with defective anchor cell behavior reveal that anchor cell invasion of the vulva is important for forming the toroidal shape of the dorsal vulval cell, vulF. In fos-1 mutants, where the AC cannot breakdown the basement membranes between the gonad and the vulva, and in mutants in unc-6 netrin or its receptor unc-40, which cause AC migration defects, the AC fails to invade the vulva and no lumen is formed in vulF. By examining GFP markers of dorsal vulval cell fate, we demonstrate that fate specification defects do not account for the aberrant vulF shape. We propose that the presence of the AC in the center of the developing vulF toroid is required for dorsal vulval lumen formation to complete vulval tubulogenesis.     

Phylogeny of the nematode genus <Emphasis Type="Italic">Pristionchus</Emphasis> and implications for biodiversity,biogeography and the evolution of hermaphroditism

Background  

The nematode Pristionchus pacificus has originally been developed as a satellite organism for comparison to Caenorhabditis elegans. A 10X coverage of the whole genome of P. pacificus is available, making P. pacificus the first non- Caenorhabditis nematode with a fully sequenced genome. The macroevolutionary comparison between P. pacificus and C. elegans has been complemented by microevolutionary studies of closely related strains and species within the genus Pristionchus. In addition, new understanding of the biology of Pristionchus from field studies, demonstrating a close association with various scarab beetles and the Colorado potato beetle, supports consideration of this nematode in studies of ecosystems. In the course of field studies on four continents more than 1,200 isolates were established from 15,000 beetle specimens representing 18 Pristionchus species. Two remarkable features of the Pristionchus – beetle association are the high species specificity of the interaction and the interception of the beetle's sex communication system for host recognition by the nematodes, as suggested by chemotaxis studies. Evolutionary interpretations of differences in developmental, behavioral and ecological patterns require a phylogenetic framework of the genus Pristionchus.     

The nematode even-skipped homolog vab-7 regulates gonad and vulva position in Pristionchus pacificus

In free-living nematodes, developmental processes like the formation of the vulva, can be studied at a cellular level. Cell lineage and ablation studies have been carried out in various nematode species and multiple changes in vulval patterning have been identified. In Pristionchus pacificus, vulva formation differs from Caenorhabditis elegans with respect to several autonomous and conditional aspects of cell fate specification. To understand the molecular basis of these evolutionary changes, we have performed a genetic analysis of vulva formation in P. pacificus. Here, we describe two mutants where the vulva is shifted posteriorly, affecting which precursor cells will form vulval tissue in P. pacificus. Mutant animals show a concomitant posterior displacement of the gonadal anchor cell, indicating that the gonad and the vulva are affected in a similar way. We show that mutations in the even-skipped homolog of nematodes, vab-7, cause these posterior displacements. In addition, cell ablation studies in the vab-7 mutant indicate that the altered position of the gonad not only changes the cell fate pattern but also the developmental competence of vulval precursor cells. Investigation of Cel-vab-7 mutant animals showed a similar but weaker vulva defective phenotype to the one described for Ppa-vab-7.     

An integrated physical and genetic map of the nematode<Emphasis Type="Italic"> Pristionchus pacificus</Emphasis>

The free-living nematode Pristionchus pacificus is one of several species that have recently been developed as a satellite system for comparative functional studies in evolutionary developmental biology. Comparisons of developmental processes between P. pacificus and the well established model organism Caenorhabditis elegans at the cellular and genetic levels provide detailed insight into the molecular changes that shape evolutionary transitions. To facilitate genetic analysis and cloning of mutations in P. pacificus, we previously generated a BAC-based genetic linkage map for this organism. Here, we describe the construction of a physical map of the P. pacificus genome based on AFLP fingerprint analysis of 7747 BAC clones. Most of the SSCP markers used to generate the genetic linkage map were derived from BAC ends, so that the physical genome map and the genetic map can be integrated. The contigs that make up the physical map are evenly distributed over the genetic linkage map and no clustering is observed, indicating that the physical map provides a valid representation of the P. pacificus genome. The integrated genome map thus provides a framework for positional cloning and the study of genome evolution in nematodes.Communicated by G. Jürgens     

The nematode Pristionchus pacificus as a model system for integrative studies in evolutionary biology

Comprehensive studies of evolution have historically been hampered by the division among disciplines. Now, as biology moves towards an ‘‐omics’ era, it is more important than ever to tackle the evolution of function and form by considering all those research areas involved in the regulation of phenotypes. Here, we review recent attempts to establish the nematode Pristionchus pacificus as a model organism that allows integrative studies of development and evo‐devo, with ecology and population genetics. Originally developed for comparative study with the nematode Caenorhabditis elegans, P. pacificus provided insight into developmental pathways including dauer formation, vulva and gonad development, chemosensation, innate immunity and neurobiology. Its subsequent discovery across a wide geographic distribution in association with scarab beetles enabled its evaluation in a biogeographic context. Development of an evolutionary field station on La Réunion Island, where P. pacificus is present in high abundance across a number of widespread habitat types, allows examination of the microfacets of evolution – processes of natural selection, adaptation and drift among populations can now be examined in this island setting. The combination of laboratory‐based functional studies with fieldwork in P. pacificus has the long‐term prospective to provide both proximate (mechanistic) and ultimate (evolutionary and ecological) causation and might therefore help to overcome the long‐term divide between major areas in biology.     

Evolution of dnmt-2 and mbd-2-like genes in the free-living nematodes Pristionchus pacificus, Caenorhabditis elegans and Caenorhabditis briggsae

Whole genome sequencing of several metazoan model organisms provides a platform for studying genome evolution. How representative are the genomes of these model organisms for their respective phyla? Within nematodes, for example, the free-living soil nematode Caenorhabditis elegans is a highly derived species with unusual genomic characters, such as a reduced Hox cluster (Curr. Biol., 13, 37–40) and the absence of a Hedgehog signaling system. Here, we describe the recent loss of a DNA methyltransferase-2 gene (dnmt-2) in C.elegans. A dnmt-2-like gene is present in the satellite model organism Pristionchus pacificus, another free-living nematode that diverged from C.elegans 200–300 million years ago. In contrast, C.elegans, Caenorhabditis briggsae and P.pacificus all contain an mbd-2-like gene, which encodes another essential component of the methylation system of higher animals and fungi. Cel-mbd-2 is expressed throughout development and RNA interference (RNAi) experiments result in variable phenotypes. In contrast, Cbr-mbd-2 RNAi results in paralyzed larval or adult worms suggesting recent changes of gene function within the genus Caenorhabditis. We speculate that both genes were part of an ancestral DNA methylation system in nematodes and that gene loss and sequence divergence have abolished DNA methylation in C.elegans.     

Molecular phylogeny of beetle associated diplogastrid nematodes suggests host switching rather than nematode-beetle coevolution

Background  

Nematodes are putatively the most species-rich animal phylum. They have various life styles and occur in a variety of habitats, ranging from free-living nematodes in aquatic or terrestrial environments to parasites of animals and plants. The rhabditid nematode Caenorhabditis elegans is one of the most important model organisms in modern biology. Pristionchus pacificus of the family of the Diplogastridae has been developed as a satellite model for comparison to C. elegans. The Diplogastridae, a monophyletic clade within the rhabditid nematodes, are frequently associated with beetles. How this beetle-association evolved and whether beetle-nematode coevolution occurred is still elusive. As a prerequisite to answering this question a robust phylogeny of beetle-associated Diplogastridae is needed.     

Wnt signaling induces vulva development in the nematode Pristionchus pacificus

The Caenorhabditis elegans vulva is induced by a member of the epidermal growth factor (EGF) family that is expressed in the gonadal anchor cell, representing a prime example of signaling processes in animal development. Comparative studies indicated that vulva induction has changed rapidly during evolution. However, nothing was known about the molecular mechanisms underlying these differences. By analyzing deletion mutants in five Wnt pathway genes, we show that Wnt signaling induces vulva formation in Pristionchus pacificus. A Ppa-bar-1/beta-catenin deletion is completely vulvaless. Several Wnt ligands and receptors act redundantly in vulva induction, and Ppa-egl-20/Wnt; Ppa-mom-2/Wnt; Ppa-lin-18/Ryk triple mutants are strongly vulvaless. Wnt ligands are differentially expressed in the somatic gonad, the anchor cell, and the posterior body region, respectively. In contrast, previous studies indicated that Ppa-lin-17, one of the Frizzled-type receptors, has a negative role in vulva formation. We found that mutations in Ppa-bar-1 and Ppa-egl-20 suppress the phenotype of Ppa-lin-17. Thus, an unexpected complexity of Wnt signaling is involved in vulva induction and vulva repression in P. pacificus. This study provides the first molecular identification of the inductive vulva signal in a nematode other than Caenorhabditis.     

Wnt and EGF pathways act together to induce C. elegans male hook development

Comparative studies of vulva development between Caenorhabditis elegans and other nematode species have provided some insight into the evolution of patterning networks. However, molecular genetic details are available only in C. elegans and Pristionchus pacificus. To extend our knowledge on the evolution of patterning networks, we studied the C. elegans male hook competence group (HCG), an equivalence group that has similar developmental origins to the vulval precursor cells (VPCs), which generate the vulva in the hermaphrodite. Similar to VPC fate specification, each HCG cell adopts one of three fates (1°, 2°, 3°), and 2° HCG fate specification is mediated by LIN-12/Notch. We show that 2° HCG specification depends on the presence of a cell with the 1° fate. We also provide evidence that Wnt signaling via the Frizzled-like Wnt receptor LIN-17 acts to specify the 1° and 2° HCG fate. A requirement for EGF signaling during 1° fate specification is seen only when LIN-17 activity is compromised. In addition, activation of the EGF pathway decreases dependence on LIN-17 and causes ectopic hook development. Our results suggest that WNT plays a more significant role than EGF signaling in specifying HCG fates, whereas in VPC specification EGF signaling is the major inductive signal. Nonetheless, the overall logic is similar in the VPCs and the HCG: EGF and/or WNT induce a 1° lineage, and LIN-12/NOTCH induces a 2° lineage. Wnt signaling is also required for execution of the 1° and 2° HCG lineages. lin-17 and bar-1/β-catenin are preferentially expressed in the presumptive 1° cell P11.p. The dynamic subcellular localization of BAR-1-GFP in P11.p is concordant with the timing of HCG fate determination.     

Connection of vulval and uterine epithelia in Caenorhabditis elegans

In the Caenorhabditis elegans hermaphrodite, the establishment of the egg-laying system requires the connection of two epithelial tubes: the uterus of the gonad and the vulva in the underlying ectoderm. A specialized uterine cell, the anchor cell (AC), plays a central role in specifying the fates of the uterine and vulval precursor cells via the EGF-Ras-MAP kinase and the Notch/Delta signaling pathways. This central and common inducing source ensures that the two sets of cells are in register and it specifies the cell types that build the T-shaped connection between uterus and vulva. On either side, progeny of the induced cells form lumen structures and undergo stereotyped cell-to-cell fusion, thereby building epithelial tubes. Finally, the anchor cell fuses with a uterine syncytium and thus leaves only a thin cellular process between the lumen of the uterus and the vulva. In the adult, the fertilized eggs exit the lumen of the uterus through the vulva. This relatively simple developmental process serves as a model to study the biology of cells during organogenesis, such as intercellular signaling, cell polarity, invasion of basal laminae and epithelia, cell recognition and cell fusion. The anchor cell is a particularly interesting cell as it coordinates the development of its neighboring cells by using different signaling pathways at different times.     

Formation of <Emphasis Type="Italic">Yersinia pseudotuberculosis</Emphasis> biofilms on multiple surfaces on <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis>

Summary A liquid-based assay was used to evaluate the ability of Yersinia pseudotuberculosis to form a bacterial biofilm on the nematode Caenorhabditis elegans. After 3 days of incubation in the liquid assay a biofilm was clearly visible by light microscopy on both the head and vulva region of the worms. At times, the biofilm formation on the vulva appeared to prevent the laying of eggs by the adult hermaphrodite; the eggs would later hatch inside of the worm. One possible explanation for the biofilm formation observed on the vulva may be the increased motion of the cuticle surrounding the vulva when the worm is immersed in a liquid culture. This is the first report of biofilm formation on the vulva of C. elegans.     

Evolution and development — the nematode vulva as a case study

To understand how morphological characters change during evolution, we need insight into the evolution of developmental processes. Comparative developmental approaches that make use of our fundamental understanding of development in certain model organisms have been initiated for different animal systems and flowering plants. Nematodes provide a useful experimental system with which to investigate the genetic and molecular alterations underlying evolutionary changes of cell fate specification in development, by comparing different species to the genetic model system Caenorhabditis elegans. In this review, I will first discuss the different types of evolutionary alterations seen at the cellular level by focusing mainly on the analysis of vulva development in different species. The observed alterations involve changes in cell lineage, cell migration and cell death, as well as induction and cell competence. I then describe a genetic approach in the nematode Pristionchus pacificus that might identify those genetic and molecular processes that cause evolutionary changes of cell fate specification.     

Alterations in cell lineage following laser ablation of cells in the somatic gonad of Caenorhabditis elegans

The postembryonic cell lineage of the somatic gonad is essentially invariant in Caenorhabditis elegans (J.E. Kimble and D. Hirsh, 1979, Develop. Biol.70, 396–417). The two exceptions to this rule of invariance involve a natural ambiguity in the ancestry of certain cells such that each of two precursor cells assumes one of two alternative fates in a given animal. In this paper, experiments are reported in which laser microsurgery is used to kill individual cells in the developing somatic gonad. Such intervention perturbs the normal environment of the remaining cells; a change observed in the expected behavior of these cells suggests that extrinsic cues may normally play a role in controlling that behavior. Several different lineage alterations have been observed after laser microsurgery in the somatic gonad. These include switches in the type of lineage followed by a given precursor cell, reversals in lineage polarity, duplications of a lineage, and alteratiions in the number of cells produced in the lineage. The only cases in which cells switch from one lineage type to another involve pairs of cells which exhibit natural ambiguity. In most cases, the interactions inferred from these changes seem to occur between neighboring somatic gonadal cells. In one case, induction of the vulva, the interaction occurs between a single somatic gonadal cell, the anchor cell, and the precursors to the vulva in a neighboring tissue, the hypodermis. The roles of intrinsic and extrinsic cues in controlling normally invariant cell lineages are discussed.     

hlh-12, a gene that is necessary and sufficient to promote migration of gonadal regulatory cells in Caenorhabditis elegans,evolved within the Caenorhabditis clade

Specialized cells of the somatic gonad primordium of nematodes play important roles in the final form and function of the mature gonad. Caenorhabditis elegans hermaphrodites are somatic females that have a two-armed, U-shaped gonad that connects to the vulva at the midbody. The outgrowth of each gonad arm from the somatic gonad primordium is led by two female distal tip cells (fDTCs), while the anchor cell (AC) remains stationary and central to coordinate uterine and vulval development. The bHLH protein HLH-2 and its dimerization partners LIN-32 and HLH-12 had previously been shown to be required for fDTC specification. Here, we show that ectopic expression of both HLH-12 and LIN-32 in cells with AC potential transiently transforms them into fDTC-like cells. Furthermore, hlh-12 was known to be required for the fDTCs to sustain gonad arm outgrowth. Here, we show that ectopic expression of HLH-12 in the normally stationary AC causes displacement from its normal position and that displacement likely results from activation of the leader program of fDTCs because it requires genes necessary for gonad arm outgrowth. Thus, HLH-12 is both necessary and sufficient to promote gonadal regulatory cell migration. As differences in female gonadal morphology of different nematode species reflect differences in the fate or migratory properties of the fDTCs or of the AC, we hypothesized that evolutionary changes in the expression of hlh-12 may underlie the evolution of such morphological diversity. However, we were unable to identify an hlh-12 ortholog outside of Caenorhabditis. Instead, by performing a comprehensive phylogenetic analysis of all Class II bHLH proteins in multiple nematode species, we found that hlh-12 evolved within the Caenorhabditis clade, possibly by duplicative transposition of hlh-10. Our analysis suggests that control of gene regulatory hierarchies for gonadogenesis can be remarkably plastic during evolution without adverse phenotypic consequence.