Faculty Bibliography

The gastrointestinal tract is subjected to extensive mechanosensory stimulation during food ingestion. However, the identities of mechanosensory receptors in the enteric nervous system remain largely unknown. The pharynx of C. elegans is structurally and functionally analogous to the vertebrate foregut, but it contains only 20 neurons embedded among the muscles and epithelial cells of the organ. Here, we report that the DEG/ENaC family ion channel DEGT-1 is a proprioceptor of pharynx movement. DEGT-1 protein is expressed in four pharyngeal neurons (MI, M3, I4, and M5) and localized to their neuronal soma in direct contact with the collagenous pharyngeal basement membrane. degt-1 mutants display abnormally rapid feeding in the presence of food, causing global changes in lipid accumulation. degt-1 mutants also pump rapidly when pumping is induced by the presence of serotonin alone, suggesting that DEGT-1 is required for proprioception of pharyngeal pumping itself rather than for sensing ingested food. DEGT-1 is required in only two pharyngeal neurons (I4 and M5) to control pumping rate. I4 and M5 neurons show a DEGT-1-dependent calcium response. Taken together, these results suggest that DEGT-1 modulates pharyngeal pumping rate by relaying proprioceptive feedback generated by the shear force of the pharynx against its own basement membrane. Thus, mechanosensors in the enteric nervous system modulate organ function by detecting not only the forces from ingested contents but also the movements of the organ itself.

The progression of animal development from embryonic to juvenile life depends on the coordination of organism-wide responses with environmental conditions. We found that two transcription factors that function in interneuron differentiation in Caenorhabditis elegans, fax-1, and unc-42, are required for arousal and progression from embryogenesis to larval life by potentiating insulin signaling. The combination of mutations in either transcription factor and a mutation in daf-2 insulin receptor results in a novel perihatching arrest phenotype; embryos are fully developed but inactive, often remaining trapped within the eggshell, and fail to initiate pharyngeal pumping. This pathway is opposed by an osmotic sensory response pathway that promotes developmental arrest and a sleep state at the end of embryogenesis in response to elevated salt concentration. The quiescent state induced by loss of insulin signaling or by osmotic stress can be reversed by mutations in genes that are required for sleep. Therefore, countervailing signals regulate late embryonic arousal and developmental progression to larval life, mechanistically linking the two responses. Our findings demonstrate a role for insulin signaling in an arousal circuit, consistent with evidence that insulin-related regulation may function in control of sleep states in many animals. The opposing quiescent arrest state may serve as an adaptive response to the osmotic threat from high salinity environments.

The sex-determining genes Double Sex and Fruitless are expressed in sexually differentiated neurons of the Drosophila brain. A tiny cluster of neurons, aDN cells, serves as a key circuit switch with sexually dimorphic properties: those of female flies respond to visual signals in males, while those of male flies respond to smell and humidity in females, supporting effective courtship and communal egg laying behaviors, respectively.

Sex-specific synaptic connectivity is beginning to emerge as a remarkable, but little explored feature of animal brains. We describe here a novel mechanism that promotes sexually dimorphic neuronal function and synaptic connectivity in the nervous system of the nematode Caenorhabditis elegans. We demonstrate that a phylogenetically conserved, but previously uncharacterized Doublesex/Mab-3 related transcription factor (DMRT), dmd-4, is expressed in two classes of sex-shared phasmid neurons specifically in hermaphrodites but not in males. We find dmd-4 to promote hermaphrodite-specific synaptic connectivity and neuronal function of phasmid sensory neurons. Sex-specificity of DMD-4 function is conferred by a novel mode of posttranslational regulation that involves sex-specific protein stabilization through ubiquitin binding to a phylogenetically conserved but previously unstudied protein domain, the DMA domain. A human DMRT homolog of DMD-4 is controlled in a similar manner, indicating that our findings may have implications for the control of sexual differentiation in other animals as well.

Sexual differentiation is controlled by diverse master regulatory factors across the animal kingdom. The transcription factor TRA-1 is the master regulator of somatic sexual differentiation in the nematode C. elegans, where it was reported to be expressed sex-specifically in the non-gonadal soma of hermaphrodites. Using a gfp-tagged allele of tra-1, we reveal unanticipated dynamics of TRA-1 protein expression in five dimensions: space, time, sex, environment, and subcellular localization. We show temporal regulation of TRA-1 protein accumulation in somatic tissues with different onsets of expression in different tissue types, indicating that sexual identity is not uniformly imposed. In hermaphrodites, neuronal expression is initially highly restricted and then increases variably between individuals during larval development until reaching panneuronal expression in the fourth larval stage. Unexpectedly, TRA-1 also accumulates in a subset of sex-shared neurons in the male. Additionally, a food signal is required to turn on TRA-1 expression in the intestine, and environmental stressors shut off TRA-1 expression in the entire non-gonadal soma, suggesting that somatic sexual differentiation may be affected by external conditions. We show that, in contrast to the protein degradation mechanisms that control TRA-1 accumulation in the adult, the temporal, sexual, and spatial specificities of TRA-1 accumulation during development are regulated transcriptionally. A nuclear hormone receptor, daf-12, previously implicated in developmental timing in C. elegans, contributes to temporal accumulation of TRA-1 in the nervous system. Our studies reveal a mosaic and dynamic nature of sexual identity acquisition and uncover hormonal control mechanisms for sexual differentiation of the brain.

Knowledge of connectivity in the nervous system is essential to understanding its function. Here we describe connectomes for both adult sexes of the nematode Caenorhabditis elegans, an important model organism for neuroscience research. We present quantitative connectivity matrices that encompass all connections from sensory input to end-organ output across the entire animal, information that is necessary to model behaviour. Serial electron microscopy reconstructions that are based on the analysis of both new and previously published electron micrographs update previous results and include data on the male head. The nervous system differs between sexes at multiple levels. Several sex-shared neurons that function in circuits for sexual behaviour are sexually dimorphic in structure and connectivity. Inputs from sex-specific circuitry to central circuitry reveal points at which sexual and non-sexual pathways converge. In sex-shared central pathways, a substantial number of connections differ in strength between the sexes. Quantitative connectomes that include all connections serve as the basis for understanding how complex, adaptive behavior is generated.

Differences between female and male brains exist across the animal kingdom and extend from molecular to anatomical features. Here we show that sexually dimorphic anatomy, gene expression and function in the nervous system can be modulated by past experiences. In the nematode Caenorhabditis elegans, sexual differentiation entails the sex-specific pruning of synaptic connections between neurons that are shared by both sexes, giving rise to sexually dimorphic circuits in adult animals¹. We discovered that starvation during juvenile stages is memorized in males to suppress the emergence of sexually dimorphic synaptic connectivity. These circuit changes result in increased chemosensory responsiveness in adult males following juvenile starvation. We find that an octopamine-mediated starvation signal dampens the production of serotonin (5-HT) to convey the memory of starvation. Serotonin production is monitored by a 5-HT1A serotonin receptor homologue that acts cell-autonomously to promote the pruning of sexually dimorphic synaptic connectivity under well-fed conditions. Our studies demonstrate how life history shapes neurotransmitter production, synaptic connectivity and behavioural output in a sexually dimorphic circuit.

One goal of modern day neuroscience is the establishment of molecular maps that assign unique features to individual neuron types. Such maps provide important starting points for neuron classification, for functional analysis, and for developmental studies aimed at defining the molecular mechanisms of neuron identity acquisition and neuron identity diversification. In this resource paper, we describe a nervous system-wide map of the potential expression sites of 244 members of the largest gene family in the C. elegans genome, rhodopsin-like (class A) G-protein-coupled receptor (GPCR) chemoreceptors, using classic gfp reporter gene technology. We cover representatives of all sequence families of chemoreceptor GPCRs, some of which were previously entirely uncharacterized. Most reporters are expressed in a very restricted number of cells, often just in single cells. We assign GPCR reporter expression to all but two of the 37 sensory neuron classes of the sex-shared, core nervous system. Some sensory neurons express a very small number of receptors, while others, particularly nociceptive neurons, coexpress several dozen GPCR reporter genes. GPCR reporters are also expressed in a wide range of inter- and motorneurons, as well as non-neuronal cells, suggesting that GPCRs may constitute receptors not just for environmental signals, but also for internal cues. We observe only one notable, frequent association of coexpression patterns, namely in one nociceptive amphid (ASH) and two nociceptive phasmid sensory neurons (PHA, PHB). We identified GPCRs with sexually dimorphic expression and several GPCR reporters that are expressed in a left/right asymmetric manner. We identified a substantial degree of GPCR expression plasticity; particularly in the context of the environmentally-induced dauer diapause stage when one third of all tested GPCRs alter the cellular specificity of their expression within and outside the nervous system. Intriguingly, in a number of cases, the dauer-specific alterations of GPCR reporter expression in specific neuron classes are maintained during postdauer life and in some case new patterns are induced post-dauer, demonstrating that GPCR gene expression may serve as traits of life history. Taken together, our resource provides an entry point for functional studies and also offers a host of molecular markers for studying molecular patterning and plasticity of the nervous system.