Cell excitability necessary for male mating behavior in Caenorhabditis elegans is coordinated by interactions between big current and ether-a-go-go family K(+) channels

Variations in K(+) channel composition allow for differences in cell excitability and, at an organismal level, provide flexibility to behavioral regulation. When the function of a K(+) channel is disrupted, the remaining K(+) channels might incompletely compensate, manifesting as abnormal organismal behavior. In this study, we explored how different K(+) channels interact to regulate the neuromuscular circuitry used by Caenorhabditis elegans males to protract their copulatory spicules from their tail and insert them into the hermaphrodite's vulva during mating. We determined that the big current K(+) channel (BK)/SLO-1 genetically interacts with ether-a-go-go (EAG)/EGL-2 and EAG-related gene/UNC-103 K(+) channels to control spicule protraction. Through rescue experiments, we show that specific slo-1 isoforms affect spicule protraction. Gene expression studies show that slo-1 and egl-2 expression can be upregulated in a calcium/calmodulin-dependent protein kinase II-dependent manner to compensate for the loss of unc-103 and conversely, unc-103 can partially compensate for the loss of SLO-1 function. In conclusion, an interaction between BK and EAG family K(+) channels produces the muscle excitability levels that regulate the timing of spicule protraction and the success of male mating behavior.     

Coordination of opposing sex-specific and core muscle groups regulates male tail posture during Caenorhabditis elegans male mating behavior

Background  

To survive and reproduce, animals must be able to modify their motor behavior in response to changes in the environment. We studied a complex behavior of Caenorhabditis elegans, male mating behavior, which provided a model for understanding motor behaviors at the genetic, molecular as well as circuit level. C. elegans male mating behavior consists of a series of six sub-steps: response to contact, backing, turning, vulva location, spicule insertion, and sperm transfer. The male tail contains most of the sensory structures required for mating, in addition to the copulatory structures, and thus to carry out the steps of mating behavior, the male must keep his tail in contact with the hermaphrodite. However, because the hermaphrodite does not play an active role in mating and continues moving, the male must modify his tail posture to maintain contact. We provide a better understanding of the molecular and neuro-muscular pathways that regulate male tail posture during mating.     

Socket cells mediate spicule morphogenesis in Caenorhabditis elegans males.

Caenorhabditis elegans male spicule morphogenesis requires the coordinated cellular behaviors of several types of cells. We found that the spicule neurons and sheath cells, although important for spicule function, are dispensable for spicule morphology. In contrast, the spicule socket cells are essential for both spicule elongation and formation of spicule cuticle. The socket cells are not only necessary but also sufficient to produce spicule cuticle. This functional aspect of socket cells is genetically separable from their function in mediating spicule elongation: elongated spicules with defective spicule cuticle can be formed. During spicule morphogenesis, the expression of an egl-17::GFP reporter gene is found in the spicule socket cells and its expression appears to be regulated in the socket cells. Mutants defective in TGF-beta signaling display a crumpled spicules phenotype as a result of failure of socket cell movement during spicule morphogenesis. These observations suggest that both the FGF and the TGF-beta signaling pathways might be involved in spicule elongation.     

Inositol 1,4,5-trisphosphate signaling regulates rhythmic contractile activity of myoepithelial sheath cells in Caenorhabditis elegans

Intercellular communication between germ cells and neighboring somatic cells is essential for reproduction. Caenorhabditis elegans oocytes are surrounded by and coupled via gap junctions to smooth muscle-like myoepithelial sheath cells. Rhythmic sheath cell contraction drives ovulation and is triggered by a factor secreted from oocytes undergoing meiotic maturation. We demonstrate for the first time that signaling through the epidermal growth factor-like ligand LIN-3 and the LET-23 tyrosine kinase receptor induces ovulatory contractions of sheath cells. Reduction-of-function mutations in the inositol 1,4,5-trisphosphate (IP(3)) receptor gene itr-1 and knockdown of itr-1 expression by RNA interference inhibit sheath contractile activity. itr-1 gain-of-function mutations increase the rate and force of basal contractions and induce tonic sheath contraction during ovulation. Sheath contractile activity is disrupted by RNAi of plc-3, one of six phospholipase C-encoding genes in the C. elegans genome. PLC-3 is a PLC-gamma homolog and is expressed in contractile sheath cells of the proximal gonad. Maintenance of sheath contractile activity requires plasma membrane Ca(2+) entry. We conclude that IP(3) generated by LET-23 mediated activation of PLC-gamma induces repetitive intracellular Ca(2+) release that drives rhythmic sheath cell contraction. Calcium entry may function to trigger Ca(2+) release via IP(3) receptors and/or refill intracellular Ca(2+) stores.     

Polycystin-2 accelerates Ca2+ release from intracellular stores in Caenorhabditis elegans

Polycystin-2, a member of the TRP family of calcium channels, is encoded by the human PKD2 gene. Mutations in that gene can lead to swelling of nephrons into the fluid-filled cysts of polycystic kidney disease. In addition to expression in tubular epithelial cells, human polycystin-2 is found in muscle and neuronal cells, but its cell biological function has been unclear. A homologue in Caenorhabditis elegans is necessary for male mating behavior. We compared the behavior, calcium signaling mechanisms, and electrophysiology of wild-type and pkd-2 knockout C. elegans. In addition to characterizing PKD-2-mediated aggregation and mating behaviors, we found that polycystin-2 is an intracellular Ca(2+) release channel that is required for the normal pattern of Ca(2+) responses involving IP(3) and ryanodine receptor-mediated Ca(2+) release from intracellular stores. Activity of polycystin-2 creates brief cytosolic Ca(2+) transients with increased amplitude and decreased duration. Polycystin-2, along with the IP(3) and ryanodine receptors, acts as a major calcium-release channel in the endoplasmic reticulum in cells where rapid calcium signaling is required, and polycystin-2 activity is essential in those excitable cells for rapid responses to stimuli.     

C. elegans Dopaminergic D2-Like Receptors Delimit Recurrent Cholinergic-Mediated Motor Programs during a Goal-Oriented Behavior

Caenorhabditis elegans male copulation requires coordinated temporal-spatial execution of different motor outputs. During mating, a cloacal circuit consisting of cholinergic sensory-motor neurons and sex muscles maintains the male''s position and executes copulatory spicule thrusts at his mate''s vulva. However, distinct signaling mechanisms that delimit these behaviors to their proper context are unclear. We found that dopamine (DA) signaling directs copulatory spicule insertion attempts to the hermaphrodite vulva by dampening spurious stimulus-independent sex muscle contractions. From pharmacology and genetic analyses, DA antagonizes stimulatory ACh signaling via the D2-like receptors, DOP-2 and DOP-3, and Gα_o/i proteins, GOA-1 and GPA-7. Calcium imaging and optogenetics suggest that heightened DA-expressing ray neuron activities coincide with the cholinergic cloacal ganglia function during spicule insertion attempts. D2-like receptor signaling also attenuates the excitability of additional mating circuits to reduce the duration of mating attempts with unproductive and/or inappropriate partners. This suggests that, during wild-type mating, simultaneous DA-ACh signaling modulates the activity threshold of repetitive motor programs, thus confining the behavior to the proper situational context.     

Initiation of male sperm-transfer behavior in Caenorhabditis elegans requires input from the ventral nerve cord

Background  

The Caenorhabditis elegans male exhibits a stereotypic behavioral pattern when attempting to mate. This behavior has been divided into the following steps: response, backing, turning, vulva location, spicule insertion, and sperm transfer. We and others have begun in-depth analyses of all these steps in order to understand how complex behaviors are generated. Here we extend our understanding of the sperm-transfer step of male mating behavior.     

Regulated disruption of inositol 1,4,5-trisphosphate signaling in Caenorhabditis elegans reveals new functions in feeding and embryogenesis

Inositol 1,4,5-trisphosphate (IP(3)) is an important second messenger in animal cells and is central to a wide range of cellular responses. The major intracellular activity of IP(3) is to regulate release of Ca(2+) from intracellular stores through IP(3) receptors (IP(3)Rs). We describe a system for the transient disruption of IP(3) signaling in the model organism Caenorhabditis elegans. The IP(3) binding domain of the C. elegans IP(3)R, ITR-1, was expressed from heat shock-induced promoters in live animals. This results in a dominant-negative effect caused by the overexpressed IP(3) binding domain acting as an IP(3) "sponge." Disruption of IP(3) signaling resulted in disrupted defecation, a phenotype predicted by previous genetic studies. This approach also identified two new IP(3)-mediated processes. First, the up-regulation of pharyngeal pumping in response to food is dependent on IP(3) signaling. RNA-mediated interference studies and analysis of itr-1 mutants show that this process is also IP(3)R dependent. Second, the tissue-specific expression of the dominant-negative construct enabled us to circumvent the sterility associated with loss of IP(3) signaling through the IP(3)R and thus determine that IP(3)-mediated signaling is required for multiple steps in embryogenesis, including cytokinesis and gastrulation.     

Opposing functions of calcineurin and CaMKII regulate G-protein signaling in egg-laying behavior of C.elegans

Ca(2+)/calmodulin-dependent calcineurin has been shown to have important roles in various Ca(2+) signaling pathways. We have previously reported that cnb-1(jh103) mutants, null mutants of a regulatory B subunit, displayed pleiotropic defects including uncoordinated movement and delayed egg laying in Caenorhabditis elegans. Interestingly, gain-of-function mutants of a catalytic A subunit showed exactly opposite phenotypes to those of cnb-1(null) mutants providing an excellent genetic model to define calcium-mediated signaling pathway at the organism level. Furthermore, calcineurin is also important for normal cuticle formation, which is required for maintenance of normal body size in C.elegans. Genetic interactions between tax-6 and several mutants including egl-30 and egl-10, which are known to be involved in G-protein signaling pathways suggest that calcineurin indeed regulates locomotion and serotonin-mediated egg laying through goa-1(Goalpha) and egl-30(Gqalpha). Our results indicate that, along with CaMKII, calcineurin regulates G-protein-coupled phosphorylation signaling pathways in C.elegans.     

FGF signaling functions in the hypodermis to regulate fluid balance in C. elegans

Signaling by the Caenorhabditis elegans fibroblast growth factor receptor EGL-15 is activated by LET-756, a fibroblast growth factor, and attenuated by CLR-1, a receptor tyrosine phosphatase. Hyperactive EGL-15 signaling results in a dramatic Clr phenotype characterized by the accumulation of clear fluid within the pseudocoelomic space, suggesting that regulated EGL-15 signaling is essential for fluid homeostasis in C. elegans. To determine the cellular focus of EGL-15 signaling, we identified an enhancer element (e15) within the egl-15 promoter, which is both necessary for the promoter activity and sufficient when duplicated to drive either egl-15 or clr-1 rescue activity. This enhancer drives GFP expression in hypodermal cells. Consistent with this finding, immunofluorescence studies of EGL-15 indicate that EGL-15 is expressed in hypodermal cells, and hypodermal promoters can drive full clr-1 and egl-15 rescue activity. Moreover, a mosaic analysis of mpk-1, which acts downstream of egl-15, suggests that its suppression of Clr (Soc) function is required in the hypodermis. These results suggest that EGL-15 and CLR-1 act in the hypodermis to regulate fluid homeostasis in worms.     

TRY-5 is a sperm-activating protease in Caenorhabditis elegans seminal fluid

Seminal fluid proteins have been shown to play important roles in male reproductive success, but the mechanisms for this regulation remain largely unknown. In Caenorhabditis elegans, sperm differentiate from immature spermatids into mature, motile spermatozoa during a process termed sperm activation. For C. elegans males, sperm activation occurs during insemination of the hermaphrodite and is thought to be mediated by seminal fluid, but the molecular nature of this activity has not been previously identified. Here we show that TRY-5 is a seminal fluid protease that is required in C. elegans for male-mediated sperm activation. We observed that TRY-5::GFP is expressed in the male somatic gonad and is transferred along with sperm to hermaphrodites during mating. In the absence of TRY-5, male seminal fluid loses its potency to transactivate hermaphrodite sperm. However, TRY-5 is not required for either hermaphrodite or male fertility, suggesting that hermaphrodite sperm are normally activated by a distinct hermaphrodite-specific activator to which male sperm are also competent to respond. Within males, TRY-5::GFP localization within the seminal vesicle is antagonized by the protease inhibitor SWM-1. Together, these data suggest that TRY-5 functions as an extracellular activator of C. elegans sperm. The presence of TRY-5 within the seminal fluid couples the timing of sperm activation to that of transfer of sperm into the hermaphrodite uterus, where motility must be rapidly acquired. Our results provide insight into how C. elegans has adopted sex-specific regulation of sperm motility to accommodate its male-hermaphrodite mode of reproduction.     

The bromodomain protein LIN-49 and trithorax-related protein LIN-59 affect development and gene expression in Caenorhabditis elegans

We have molecularly characterized the lin-49 and lin-59 genes in C. elegans, and found their products are related to Drosophila trithorax group (trx-G) proteins and other proteins implicated in chromatin remodelling. LIN-49 is structurally most similar to the human bromodomain protein BR140, and LIN-59 is most similar to the Drosophila trx-G protein ASH1. In C. elegans, lin-49 and lin-59 are required for the normal development of the mating structures of the adult male tail, for the normal morphology and function of hindgut (rectum) cells in both males and hermaphrodites and for the maintenance of structural integrity in the hindgut and egg-laying system in adults. Expression of the Hox genes egl-5 and mab-5 is reduced in lin-49 and lin-59 mutants, suggesting lin-49 and lin-59 regulate HOM-C gene expression in C. elegans as the trx-G genes do in Drosophila. lin-49 and lin-59 transgenes are expressed widely throughout C. elegans animals. Thus, in contrast to the C. elegans Polycomb group (Pc-G)-related genes mes-2 and mes-6 that function primarily in the germline, we propose lin-49 and lin-59 function in somatic development similar to the Drosophila trx-G genes.     

A cholinergic-regulated circuit coordinates the maintenance and bi-stable states of a sensory-motor behavior during Caenorhabditis elegans male copulation

Penetration of a male copulatory organ into a suitable mate is a conserved and necessary behavioral step for most terrestrial matings; however, the detailed molecular and cellular mechanisms for this distinct social interaction have not been elucidated in any animal. During mating, the Caenorhabditis elegans male cloaca is maintained over the hermaphrodite's vulva as he attempts to insert his copulatory spicules. Rhythmic spicule thrusts cease when insertion is sensed. Circuit components consisting of sensory/motor neurons and sex muscles for these steps have been previously identified, but it was unclear how their outputs are integrated to generate a coordinated behavior pattern. Here, we show that cholinergic signaling between the cloacal sensory/motor neurons and the posterior sex muscles sustains genital contact between the sexes. Simultaneously, via gap junctions, signaling from these muscles is transmitted to the spicule muscles, thus coupling repeated spicule thrusts with vulval contact. To transit from rhythmic to sustained muscle contraction during penetration, the SPC sensory-motor neurons integrate the signal of spicule's position in the vulva with inputs from the hook and cloacal sensilla. The UNC-103 K(+) channel maintains a high excitability threshold in the circuit, so that sustained spicule muscle contraction is not stimulated by fewer inputs. We demonstrate that coordination of sensory inputs and motor outputs used to initiate, maintain, self-monitor, and complete an innate behavior is accomplished via the coupling of a few circuit components.     

A direct interaction between IP(3) receptors and myosin II regulates IP(3) signaling in C. elegans

Molecular and physiological studies of cells implicate interactions between the cytoskeleton and the intracellular calcium signalling machinery as an important mechanism for the regulation of calcium signalling. However, little is known about the functions of such mechanisms in animals. A key component of the calcium signalling network is the intracellular release of calcium in response to the production of the second messenger inositol 1,4,5-trisphosphate (IP(3)), mediated by the IP(3) receptor (IP(3)R). We show that C. elegans IP(3)Rs, encoded by the gene itr-1, interact directly with myosin II. The interactions between two myosin proteins, UNC-54 and MYO-1, and ITR-1 were identified in a yeast two-hybrid screen and subsequently confirmed in vivo and in vitro. We defined the interaction sites on both the IP(3)R and MYO-1. To test the effect of disrupting the interaction in vivo we overexpressed interacting fragments of both proteins in C. elegans. This decreased the animal's ability to upregulate pharyngeal pumping in response to food. This is a known IP(3)-mediated process [15]. Other IP(3)-mediated processes, e.g., defecation, were unaffected. Thus it appears that interactions between IP(3)Rs and myosin are required for maintaining the specificity of IP(3) signalling in C. elegans and probably more generally.     

ATP-2 interacts with the PLAT domain of LOV-1 and is involved in Caenorhabditis elegans polycystin signaling

Caenorhabditis elegans is a powerful model to study the molecular basis of autosomal dominant polycystic kidney disease (ADPKD). ADPKD is caused by mutations in the polycystic kidney disease (PKD)1 or PKD2 gene, encoding polycystin (PC)-1 or PC-2, respectively. The C. elegans polycystins LOV-1 and PKD-2 are required for male mating behaviors and are localized to sensory cilia. The function of the evolutionarily conserved polycystin/lipoxygenase/alpha-toxin (PLAT) domain found in all PC-1 family members remains an enigma. Here, we report that ATP-2, the beta subunit of the ATP synthase, physically associates with the LOV-1 PLAT domain and that this interaction is evolutionarily conserved. In addition to the expected mitochondria localization, ATP-2 and other ATP synthase components colocalize with LOV-1 and PKD-2 in cilia. Disrupting the function of the ATP synthase or overexpression of atp-2 results in a male mating behavior defect. We further show that atp-2, lov-1, and pkd-2 act in the same molecular pathway. We propose that the ciliary localized ATP synthase may play a previously unsuspected role in polycystin signaling.     

IRI-1, a LIN-15B homologue, interacts with inositol-1,4,5-triphosphate receptors and regulates gonadogenesis, defecation, and pharyngeal pumping in Caenorhabditis elegans

Inositol-1,4,5-triphosphate receptors (IP(3)Rs) are ligand-gated Ca(2+) channels that control Ca(2+) release from intracellular stores. They are central to a wide range of cellular responses. IP(3)Rs in Caenorhabditis elegans are encoded by a single gene, itr-1, and are widely expressed. Signaling through IP(3) and IP(3)Rs is important in ovulation, control of the defecation cycle, modulation of pharyngeal pumping rate, and embryogenesis. To further elucidate the molecular basis of the diversity of IP(3)R function, we used a yeast two-hybrid screen to search for proteins that interact with ITR-1. We identified an interaction between ITR-1 and IRI-1, a previously uncharacterized protein with homology to LIN-15B. Iri-1 is widely expressed, and its expression overlaps significantly with that of itr-1. In agreement with this observation, iri-1 functions in known itr-1-mediated processes, namely, upregulation of pharyngeal pumping in response to food and control of the defecation cycle. Knockdown of iri-1 in an itr-1 loss-of-function mutant potentiates some of these effects and sheds light on the signaling pathways that control pharyngeal pumping rate. Knockdown of iri-1 expression also results in a sterile, evl phenotype, as a consequence of failures in early Z1/Z4 lineage divisions, such that gonadogenesis is severely disrupted.     

Role of phosphatidylinositol-4-phosphate 5' kinase (ppk-1) in ovulation of Caenorhabditis elegans

During Caenorhabditis elegans ovulation, the somatic gonad integrates signals from germ cells and propels a mature oocyte into the spermatheca for fertilization. Previous work suggests that phosphoinositide signaling plays important roles in C. elegans fertility. To fully understand inositol-1,4,5-trisphosphate (IP(3)) signaling in ovulation, we have examined the function of phosphatidylinositol-4-phosphate 5' kinase (PIP5K) in C. elegans. Our results show that the C. elegans PIP5K homolog, ppk-1, is essential for ovulation in C. elegans; ppk-1 is mainly expressed in somatic gonad, and depletion of ppk-1 expression causes defective ovulation, reduced gonad sheath contractility, and sterility. Increased IP(3) signaling compensates for ppk-1 (RNAi)-induced sterility, suggesting that ppk-1 is linked to IP(3) signaling. These results demonstrate that ppk-1 plays an essential role in IP(3) signaling and cytoskeleton organization in somatic gonad.     

Regulation of distinct muscle behaviors controls the C. elegans male's copulatory spicules during mating.

We demonstrate through cell ablation, molecular genetic, and pharmacological approaches that during C. elegans male mating behavior, the male inserts his copulatory spicules into the hermaphrodite by regulating periodic and prolonged spicule muscle contractions. Distinct cholinergic neurons use different ACh receptors and calcium channels in the spicule muscles to mediate these contractile behaviors. The PCB and PCC sensory neurons facilitate periodic contraction through muscle-encoded UNC-68 ryanodine receptor calcium channels. The SPC motor neurons trigger prolonged contraction through EGL-19 L-type voltage-gated calcium channels. The male gonad then lengthens the duration of EGL-19-mediated prolonged muscle contraction. This regulation of muscle contraction provides a paradigm to explain how animals initiate, monitor, and maintain a behavioral motor program.