A comparative study of sperm morphology, cytology and activation in Caenorhabditis elegans, Caenorhabditis remanei and Caenorhabditis briggsae

Studies of sterile mutants in Caenorhabditis elegans have uncovered new insights into fundamental aspects of gamete cell biology, development, and function at fertilization. The genome sequences of C. elegans, Caenorhabditis briggsae and Caenorhabditis remanei allow for informative comparative studies among these three species. Towards that end, we have examined wild-type sperm morphology and activation (spermiogenesis) in each. Light and electron microscopy studies reveal that general sperm morphology, organization, and ultrastructure are similar in all three species, and activation techniques developed for C. elegans were found to work well in both C. briggsae and C. remanei. Despite important differences in the reproductive mode between C. remanei and the other two species, most genes required for spermiogenesis are conserved in all three. Finally, we have also examined the subcellular distribution of sperm epitopes in C. briggsae and C. remanei that cross-react with anti-sera directed against C. elegans sperm proteins. The baseline data in this study will prove useful for the future analysis and interpretation of sperm gene function across nematode species.     

Major sperm protein signaling promotes oocyte microtubule reorganization prior to fertilization in Caenorhabditis elegans

In most animals, female meiotic spindles assemble in the absence of centrosomes; instead, microtubule nucleation by chromatin, motor activity, and microtubule dynamics drive the self-organization of a bipolar meiotic spindle. Meiotic spindle assembly commences when microtubules gain access to chromatin after nuclear envelope breakdown (NEBD) during meiotic maturation. Although many studies have addressed the chromatin-based mechanism of female meiotic spindle assembly, it is less clear how signaling influences microtubule localization and dynamics prior to NEBD. Here we analyze microtubule behavior in Caenorhabditis elegans oocytes at early stages of the meiotic maturation process using confocal microscopy and live-cell imaging. In C. elegans, sperm trigger oocyte meiotic maturation and ovulation using the major sperm protein (MSP) as an extracellular signaling molecule. We show that MSP signaling reorganizes oocyte microtubules prior to NEBD and fertilization by affecting their localization and dynamics. We present evidence that MSP signaling reorganizes oocyte microtubules through a signaling network involving antagonistic G alpha(o/i) and G alpha(s) pathways and gap-junctional communication with somatic cells of the gonad. We propose that MSP-dependent microtubule reorganization promotes meiotic spindle assembly by facilitating the search and capture of microtubules by meiotic chromatin following NEBD.     

Interactions between two antagonistic reflexes in the nematode Caenorhabditis elegans

1. Antagonistic reflexes that use the same final common path cannot be activated simultaneously; as a consequence one reflex often inhibits the expression of the other. Results of experiments with two antagonistic reflexes in Caenorhabditis elegans showed that the reflex inhibition in this simple animal is the same as in more complex organisms. Thus C. elegans can serve as a model system for studying the neural mechanisms underlying these behavioral patterns. 2. In adult C. elegans tail-touch normally elicits forward movement, while tap normally elicits backward movement. When tail-touch is delivered 1 s before a tap, reversals to the tap are inhibited and the magnitude of any reversal that does occur is reduced. 3. The relative magnitude of the 2 stimuli, tail-touch and tap, affects the amount of inhibition observed. 4. The effectiveness of tail-touch as an inhibitory stimulus can be varied as a result of experience. Habituating the response to tail-touch decreased the inhibition of reversal to tap following a tail-touch. 4. The tail-touch induced inhibition of reversal to tap diminishes over an interval of at least 10 s; however, following the inhibition an enhancement of responding to tap is seen. 6. Inhibition of reversal to tap is present in worms of all stages of development including newly hatched worms.     

Uncover Genetic Interactions in Caenorhabditis elegans by RNA Interference

RNA-mediated interference (RNAi) has emerged recently as one of the most powerful functional genomics tools. RNAi has been particularly effective in the nematode worm C. elegans where RNAi has been used to analyse the loss-of-function phenotypes of almost all predicted genes. In this review, we illustrate how RNAi has been used to analyse gene function in C. elegans as well as pointing to some future directions for using RNAi to examine genetic interactions in a systematic manner.     

Tests for parental imprinting in the nematode Caenorhabditis elegans

Summary The mutation him-6(e1423) leads to generalized chromosomal nondisjunction during meiosis in oogenesis and spermatogenesis of C. elegans. As a result, gametes nullisomic or disomic for each of the six chromosomes occur at appreciable frequency. Crosses utilizing marked him-6 strains were used to generate and identify exceptional euploid progeny which had received both homologues of a marked autosome either from the male parent or from the female parent. Examples of all ten possible exceptions were identified and found to be viable and fertile. These results (together with previous data for the X chromosome) indicate that major chromosomal imprinting effects do not occur during gametogenesis in this organism.     

Dopamine Signaling Architecture in Caenorhabditis elegans

1. Aims: In this review, we highlight the identification and analysis of molecules orchestrating dopamine (DA) signaling in the nematode Caenorhabditis elegans, focusing on recent characterizations of DA transporters and receptors.2. Methods: We illustrate the isolation and characterization of molecules important for C. elegans DA synthesis, packaging, reuptake and signaling and examine how mutations in these proteins are being exploited through in vitro and in vivo paradigms to yield novel insights of protein structure, DA signaling pathways and DA-supported behaviors.3. Results: DA signaling in the worm, as in man, arises by synaptic and nonsynaptic release from a small number of cells that exert modulatory control over a larger network underlying C. elegans behavior.4. Conclusions: The C. elegans model system offers unique opportunities to elucidate ill-defined pathways that support DA release, inactivation, and signaling in addition to clarifying mechanisms of DA-mediated behavioral plasticity. Further use of the model offers prospects for the identification of novel genes and proteins whose study may yield benefits for DA-supported neural disorders in man.     

Comparative analysis of embryonic cell lineage between Caenorhabditis briggsae and Caenorhabditis elegans

Comparative genomic analysis of important signaling pathways in Caenorhabditis briggsae and Caenorhabditis elegans reveals both conserved features and also differences. To build a framework to address the significance of these features we determined the C. briggsae embryonic cell lineage, using the tools StarryNite and AceTree. We traced both cell divisions and cell positions for all cells through all but the last round of cell division and for selected cells through the final round. We found the lineage to be remarkably similar to that of C. elegans. Not only did the founder cells give rise to similar numbers of progeny, the relative cell division timing and positions were largely maintained. These lineage similarities appear to give rise to similar cell fates as judged both by the positions of lineally equivalent cells and by the patterns of cell deaths in both species. However, some reproducible differences were seen, e.g., the P4 cell cycle length is more than 40% longer in C. briggsae than that in C. elegans (p < 0.01). The extensive conservation of embryonic development between such divergent species suggests that substantial evolutionary distance between these two species has not altered these early developmental cellular events, although the developmental defects of transpecies hybrids suggest that the details of the underlying molecular pathways have diverged sufficiently so as to not be interchangeable.     

Checkpoint and physiological apoptosis in germ cells proceeds normally in spaceflown Caenorhabditis elegans

It is important for human life in space to study the effects of environmental factors during spaceflight on a number of physiological phenomena. Apoptosis plays important roles in development and tissue homeostasis in metazoans. In this study, we have analyzed apoptotic activity in germ cells of the nematode C. elegans, following spacefight. Comparison of the number of cell corpses in wild type or ced-1 mutants, grown under either ground or spaceflight conditions, showed that both pachytene-checkpoint apoptosis and physiological apoptosis in germ cells occurred normally under spaceflight conditions. In addition, the expression levels of the checkpoint and apoptosis related genes are comparable between spaceflight and ground conditions. This is the first report documenting the occurrence of checkpoint apoptosis in the space environment and suggests that metazoans, including humans, would be able to eliminate cells that have failed to repair DNA lesions introduced by cosmic radiation during spaceflight.     

2.6 A resolution crystal structure of helices of the motile major sperm protein (MSP) of Caenorhabditis elegans

The amoeboid locomotion of nematode sperm is mediated by the assembly dynamics of the major sperm protein (MSP). MSP forms fibrous networks based on a hierarchy of macromolecular assemblies: helical subfilaments are built from MSP dimers; filaments are formed from two subfilaments coiling round one another; and filaments themselves supercoil to produce bundles. To provide a structural context for understanding the role of these macromolecular assemblies in cell locomotion, we have determined the 2.6 A resolution structure of crystals of Caenorhabditis elegans MSP that are constructed from helices of MSP chains that are analogous to the subfilaments from which filaments are constructed. Comparison with the crystal structures of dimers and helical assemblies of Ascaris suum MSP has identified five conserved interaction interfaces that suggest how subfilaments interact in filaments and how filaments can form bundles. The interfaces frequently involve the loop containing residues 78-85, which is divergent between MSP homologues, and the loop containing residues 98-103, which is highly conserved.     

Phospholipase Cepsilon regulates ovulation in Caenorhabditis elegans

Phospholipase Cepsilon (PLCepsilon) is a novel class of phosphoinositide-specific PLC with unknown physiological functions. Here, we present the first genetic analysis of PLCepsilon in an intact organism, the nematode Caenorhabditis elegans. Ovulation in C. elegans is dependent on an inositol 1,4,5-trisphosphate (IP(3)) signaling pathway activated by the receptor tyrosine kinase LET-23. We generated deletion mutants of the gene, plc-1, encoding C. elegans PLCepsilon. We observed a novel ovulation phenotype whereby oocytes are trapped in the spermatheca due to delayed dilation of the spermatheca-uterine valve. The expression of plc-1 in the adult spermatheca is consistent with its involvement in regulation of ovulation. On the other hand, we failed to observe genetic interaction of plc-1 with let-23-mediated IP(3) signaling pathway genes, suggesting a complex mechanism for control of ovulation.     

Genetic impairment of autophagy intensifies expanded polyglutamine toxicity in Caenorhabditis elegans

Neuronal homeostasis requires a balance between anabolic and catabolic processes. Eukaryotic cells use two distinct systems for the degradation of unused proteins: the ubiquitin-proteasome system and the autophagic system. The autophagic system is also necessary for the degradation of bulk amounts of proteins and organelles. We have searched for new autophagy-related genes in the Caenorhabditis elegans genome and investigated their role in a polyglutamine (polyQ) disease model. Here, we have shown that inactivation of these genes intensified the toxicity of expanded polyQ in C. elegans neurons and muscles, and at the same time inactivation of CeTor reduced the polyQ toxicity.     

The hedgehog-related gene wrt-5 is essential for hypodermal development in Caenorhabditis elegans

The Caenorhabditis elegans genome encodes a series of hedgehog-related genes, which are thought to have evolved and diverged from an ancestral Hh gene. They are classified into several families based on their N-terminal domains. Here, we analyze the expression and function of a member of the warthog gene family, wrt-5, that lacks the Hint/Hog domain. wrt-5 is expressed in seam cells, the pharynx, pharyngeal-intestinal valve cells, neurons, neuronal support cells, the excretory cell, and the reproductive system. WRT-5 protein is secreted into the extracellular space during embryogenesis. Furthermore, during larval development, WRT-5 protein is secreted into the pharyngeal lumen and the pharyngeal expression changes in a cyclical manner in phase with the molting cycle. Deletion mutations in wrt-5 cause embryonic lethality, which are temperature sensitive and more severe at 15 degrees C than at 25 degrees C. Animals that hatch exhibit variable abnormal morphology, for example, bagging worms, blistering, molting defects, or Roller phenotypes. We examined hypodermal cell junctions using the AJM-1Colon, two colonsGFP marker in the wrt-5 mutant background and observed cell boundary abnormalities in the arrested embryos. AJM-1Colon, two colonsGFP protein is also misplaced in pharyngeal muscle cells in the absence of WRT-5. In conclusion, we show that wrt-5 is an essential gene that - despite its lack of a Hint domain - has multiple functions in C. elegans and is implicated in cell shape integrity.     

Knockdown of the centrosomal component SAS-5 results in defects in nuclear morphology in Caenorhabditis elegans

Several different processes must be completed in order to proceed through cell division. First, the centrosomes have to be duplicated and the genomic material is replicated. The separation of the chromatin is achieved by a bipolar spindle, which in turn is organized by the two centrosomes. The last step of cell division involves the separation of cellular content and the cleavage of the cell by cytokinesis. We used RNAi to study the centrosomal component SAS-5 in the early Caenorhabditis elegans embryo. While the first cell division and the establishment of polarity of sas-5 dsRNA-treated embryos was indistinguishable from wild type, subsequent cleavages were abnormal. Time-lapse microscopy studies of worms expressing beta-tubulin::GFP revealed that the absence of SAS-5 results in a failure of mitotic spindle assembly starting at the two-cell stage embryo. Furthermore, the chromatin in at least one of the two cells in the early embryo was dispersed. Yet, this dispersion did neither trigger apoptosis nor affect nuclear envelope assembly. No intrinsic size control for the nucleus seems to exist in the early embryo.     

The Caenorhabditis elegans NR4A nuclear receptor is required for spermatheca morphogenesis

The gene nhr-6 encodes the Caenorhabditis elegans ortholog of the NR4A nuclear receptor. We determined the biological functions of NHR-6 through the isolation and characterization of a deletion allele of nhr-6, lg6001. We demonstrate that nhr-6 has an essential role in the development of the C. elegans somatic gonad. Specifically, nhr-6 is required for the development of the hermaphrodite spermatheca, a somatic gonad organ that serves as the site of sperm storage and oocyte fertilization. Using a variety of spermatheca cell markers, we have determined that loss of nhr-6 function causes severe morphological defects in the spermatheca and associated spermathecal valves. This appears to be due to specific requirements for nhr-6 in regulating cell proliferation and cell differentiation during development of these structures. The improper development of these structures in nhr-6(lg6001) mutants leads to defects in ovulation and significantly reduced fecundity of C. elegans hermaphrodites. The phenotypes of nhr-6(lg6001) mutants are consistent with a role for nhr-6 in organogenesis, similar to the functions of its mammalian homologs.     

The Caenorhabditis elegans innexin INX-3 is localized to gap junctions and is essential for embryonic development

Innexins are the proposed structural components of gap junctions in invertebrates. Antibodies that specifically recognize the Caenorhabditis elegans innexin protein INX-3 were generated and used to examine the patterns of inx-3 gene expression and the subcellular sites of INX-3 localization. INX-3 is first detected in two-cell embryos, concentrated at the intercellular interface, and is expressed ubiquitously throughout the cellular proliferation phase of embryogenesis. During embryonic morphogenesis, INX-3 expression becomes more restricted. Postembryonically, INX-3 is expressed transiently in several cell types, while expression in the posterior pharynx persists throughout development. Through immuno-EM techniques, INX-3 was observed at gap junctions in the adult pharynx, providing supporting evidence that innexins are components of gap junctions. An inx-3 mutant was isolated through a combined genetic and immunocytochemical screen. Homozygous inx-3 mutants exhibit defects during embryonic morphogenesis. At the comma stage of early morphogenesis, variable numbers of cells are lost from the anterior of inx-3(lw68) mutants. A range of terminal defects is seen later in embryogenesis, including localized rupture of the hypodermis, failure of the midbody to elongate properly, abnormal contacts between hypodermal cells, and failure of the pharynx to attach to the anterior of the animal.     

crm-1 facilitates BMP signaling to control body size in Caenorhabditis elegans

We have identified in Caenorhabditis elegans a homologue of the vertebrate Crim1, crm-1, which encodes a putative transmembrane protein with multiple cysteine-rich (CR) domains known to have bone morphogenetic proteins (BMPs) binding activity. Using the body morphology of C. elegans as an indicator, we showed that attenuation of crm-1 activity leads to a small body phenotype reminiscent of that of BMP pathway mutants. We showed that the crm-1 loss-of-function phenotype can be rescued by constitutive supply of sma-4 activity. crm-1 can enhance BMP signaling and this activity is dependent on the presence of the DBL-1 ligand and its receptors. crm-1 is expressed in neurons at the ventral nerve cord, where the DBL-1 ligand is produced. However, ectopic expression experiments reveal that crm-1 gene products act outside the DBL-1 producing cells and function non-autonomously to facilitate dbl/sma pathway signaling to control body size.     

PAR-1 is required for morphogenesis of the Caenorhabditis elegans vulva

The Caenorhabditis elegans vulva provides a simple model for the genetic analysis of pattern formation and organ morphogenesis during metazoan development. We have discovered an essential role for the polarity protein PAR-1 in the development of the vulva. Postembryonic RNA interference of PAR-1 causes a protruding vulva phenotype. We found that depleting PAR-1 during the development of the vulva has no detectable effect on fate specification or precursor proliferation, but instead seems to specifically alter morphogenesis. Using an apical junction-associated GFP marker, we discovered that PAR-1 depletion causes a failure of the two mirror-symmetric halves of the vulva to join into a single, coherent organ. The cells that normally form the ventral vulval rings fail to make contact or adhere and consequently form incomplete toroids, and dorsal rings adopt variably abnormal morphologies. We also found that PAR-1 undergoes a redistribution from apical junctions to basolateral domains during morphogenesis. Despite a known role for PAR-1 in cell polarity, we have observed no detectable differences in the distribution of various markers of epithelial cell polarity. We propose that PAR-1 activity at the cell cortex is critical for mediating cell shape changes, cell surface composition, or cell signaling during vulval morphogenesis.     

Dissection of lin-11 enhancer regions in Caenorhabditis elegans and other nematodes

The Caenorhabditis elegans LIM homeobox gene lin-11 plays crucial roles in the morphogenesis of the reproductive system and differentiation of several neurons. The expression of lin-11 in different tissues is regulated by enhancer regions located upstream as well as within lin-11 introns. These regions are functionally separable suggesting that multiple regulatory inputs operate to control the spatiotemporal pattern of lin-11 expression. To further dissect apart the nature of lin-11 regulation we focused on three Caenorhabditis species C. briggsae, C. remanei, and C. brenneri that are substantially diverged from C. elegans but share almost identical vulval morphology. We show that, in these species, the 5′ region of lin-11 possesses conserved sequences to activate lin-11 expression in the reproductive system. Analysis of the in vivo role of these sequences in C. elegans has led to the identification of three functionally distinct enhancers for the vulva, VC neurons, and uterine π lineage cells. We found that the π enhancer is regulated by FOS homolog FOS-1 and LIN-12/Notch pathway effectors, LAG-1 (Su(H)/CBF1 family) and EGL-43 (EVI1 family). These results indicate that multiple factors cooperate to regulate π-specific expression of lin-11 and together with other findings suggest that the mechanism of lin-11 regulation by LIN-12/Notch signaling is evolutionarily conserved in Caenorhabditis species. Our work demonstrates that 4-way comparison is a powerful tool to study conserved mechanisms of gene regulation in C. elegans and other nematodes.