Abstract
How sensory perception is processed by the two sexes of an organism is still only partially understood. Despite some evidence for sexual dimorphism in auditory and olfactory perception, whether touch is sensed in a dimorphic manner has not been addressed. Here we find that the neuronal circuit for tail mechanosensation in C. elegans is wired differently in the two sexes and employs a different combination of sex-shared sensory neurons and interneurons in each sex. Reverse genetic screens uncovered cell- and sex-specific functions of the alpha-tubulin mec-12 and the sodium channel tmc-1 in sensory neurons, and of the glutamate receptors nmr-1 and glr-1 in interneurons, revealing the underlying molecular mechanisms that mediate tail mechanosensation. Moreover, we show that only in males, the sex-shared interneuron AVG is strongly activated by tail mechanical stimulation, and accordingly is crucial for their behavioral response. Importantly, sex reversal experiments demonstrate that the sexual identity of AVG determines both the behavioral output of the mechanosensory response and the molecular pathways controlling it. Our results present extensive sexual dimorphism in a mechanosensory circuit at both the cellular and molecular levels.
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Introduction
In sexually reproducing species, evolutionary forces have shaped the nervous systems of the two sexes such that they feature overt sex-specific behaviors. These dimorphic behaviors can result from differences in sensory neuron perception, downstream neuronal processing, or both. Sexually dimorphic sensory perception has been observed in both vertebrate and invertebrate models. In C. elegans, the differential expression of a G-protein-coupled receptor (GPCR) in a sensory neuron determines the different behavioral outcome1. In frogs, sexually dimorphic auditory tuning has been documented2,3,4. In mice, sexually dimorphic olfactory perception5,6 and integration of sensory information were observed. The sexually dimorphic behavior in response to the pheromone ESP1, for example, was shown to be mediated through dimorphic processing in third- and fourth-order brain areas7,8. Integration downstream to the sensory level is also evident in aggressive behavior in Drosophila and nociceptive behavior in C. elegans, where sexually dimorphic processing by downstream interneurons regulates the dimorphic behavior9,10. These examples demonstrate that for different types of sensory modalities, be it olfactory, auditory or chemo-aversion, sex differences can originate from dimorphism in distinct neuronal layers.
The perception of mechanical forces, or mechanosensation, includes the perception of touch, hearing, proprioception and pain, all of which involve the transduction of mechanical forces into a cellular signal11,12. Numerous studies have focused on understanding the molecular and cellular pathways involved in mechanosensation in both mammalian and invertebrate systems13,14,15. Although recent evidence has provided insight into sex differences in mechanical nociception16,17,18,19,20, it is still unknown whether males and females sense innocuous touch differently.
C. elegans has been used extensively to explore the cells and molecules that govern mechanosensation, and specifically touch sensation15,21. Touch sensation in this species can generally be divided into two different modalities: gentle touch and harsh touch, each involving different cellular and molecular mechanisms22,23,24,25. The cellular mechanisms mediating harsh mechanical stimulation applied to the tail, or tail mechanosensation, have only recently begun to be examined. Studies focused on harsh-touch-induced tail mechanosensation discovered that the sensory neurons PHA, PHB and PHC and the interneurons PVC and DVA are required for tail mechanosensation in hermaphrodites25,26. These studies, however, did not identify the molecular mechanisms mediating touch sensitivity in these cells, nor did they address whether the same cells constitute or are part of the male tail mechanosensation circuit.
The neuronal connectome of both sexes in C. elegans27,28,29 indicates that many circuits, including those mediating mechanosensation, contain sexually dimorphic connections (Fig. 1a). Here we report that while males and hermaphrodites respond similarly to harsh touch of the tail, they sense and integrate mechanosensory information differently, in terms of the neurons involved, the underlying circuits and the molecular components mediating and transducing touch. Our results establish the circuit architecture for tail mechanosensation in both sexes and reveal a role for the sex-shared interneuron AVG as an integrator of mechanosensory information. We further identify several key components of the molecular machinery controlling the activity of this circuit and reveal the sex-specific functions of these molecules at both the sensory and interneuron levels. Our results demonstrate that the propagation of harsh-touch tail mechanosensory information is sexually dimorphic and provide a unique example of how neuronal circuits evolved sex-specific features while maintaining the same sensory modality and its behavioral output.
Results
Sensory level sexual dimorphism in the tail mechanosensation circuit
By combining data from the published connectome maps of both C. elegans sexes27 with behavioral data from previous studies25,26, we revealed that some of the sensory cells in the tail mechanosensation circuit are connected differently in the two sexes (Fig. 1a). To explore the contribution of each sensory neuron to tail mechanosensation, we silenced individual neurons by cell-specific expression of the inhibitory Drosophila histamine-gated chloride channel (HisCl1)30 and then tested both sexes for tail-touch response (see Methods). Silencing the PHB neuron diminished the tail-touch response equally in both sexes, suggesting it has a sex-independent role in touch sensitivity (Fig. 1b). However, silencing PHA and PHC revealed that PHC is necessary only in hermaphrodites (corroborating previous findings)26, while PHA is required only in males (Fig. 1b). These results show that at the sensory level, each sex utilizes a different combination of sensory cells in tail-touch perception.
We next asked whether the molecular mechanisms that govern tail mechanosensation at the sensory level are, too, sexually dimorphic. We carried out a reverse genetic screen targeting ion channels and other proteins previously suggested to be involved in mechanosensation that are known to be expressed in the tail sensory cells22,31,32,33,34,35,36,37 (Fig. 1c). Assaying tail-touch responses of RNA interference (RNAi)-fed or mutant animals led to the identification of two genes whose silencing caused sex-specific defects in tail mechanosensation.
First, targeting mec-12 by using both RNAi or a mec-12 mutant, reduced tail mechanosensation only in males (Fig. 1d, e). mec-12 (expressed in PHA, PHB and PHC, Fig. 1c) encodes an alpha-tubulin protein, is one of several genes required for touch receptor neuron (TRN) function in C. elegans and is specifically responsible for generating 15-protofilament microtubules in TRNs38.
Second, we found that RNAi of tmc-1 elicited a sexually dimorphic response, and tmc-1 mutant hermaphrodites exhibited a significantly reduced tail-touch response (Fig. 1d, e). TMC-1 (expressed in PHA and PHC, Fig. 1c) is a mechanosensitive ion channel and an ortholog of the mammalian TMC proteins important for hair-cell mechanotransduction32,39,40,41. Taken together, our screen uncovered two molecules that play a role in mediating tail mechanosensation in a sex-dependent manner, possibly functioning through different types of sensory cells (Fig. 1f).
Cell- and sex-specific function of mec-12 and tmc-1 in tail mechanosensation
Having established a role for mec-12 in mechanosensation in males, we turned to explore whether it functions sex-specifically through the phasmid neurons. Since PHA and PHB are required for tail mechanosensation in males (Fig. 1b), we restored the expression of mec-12 in mutant animals under either the srg-13 or the gpa-6 promoters, which drive expression in PHA and PHB respectively, or the che-12 promoter, which drives expression in ciliated neurons, including PHA and PHB42,43. We found that mec-12 expression in PHA but not PHB is sufficient to rescue the tail touch phenotype (Fig. 2a, Supplementary Fig. 1a), suggesting that mec-12 functions in PHA. Supporting this finding, we observed the expression of the mec-12 gene and protein in PHA in males (Supplementary Fig. 1b, c). To further examine whether mec-12 expression is sufficient to render an animal sensitive to tail touch, we exploited the fact that tmc-1 mutant hermaphrodites have a reduced tail-touch response (Fig. 1e), and force-expressed mec-12 in PHA in tmc-1 mutant hermaphrodites. Indeed, tmc-1 mutant hermaphrodites which express mec-12 specifically in PHA restored their tail-touch responses (Fig. 2b), strongly arguing for a functional role for mec-12 in tail mechanosensation.
tmc-1 was shown to be expressed in PHA and PHC in hermaphrodites34 (Fig. 1c). Since PHC is required for tail mechanosensation in hermaphrodites and not PHA (Fig. 1b), we hypothesized that tmc-1 mediates tail mechanosensation through PHC in hermaphrodites. Indeed, expressing tmc-1 specifically in PHC rescued the defective tail-touch response of tmc-1 mutant hermaphrodites (Fig. 2c). This finding is supported by the evident expression of a tmc-1::mKate2 transcriptional reporter in PHC in both sexes (Supplementary Fig. 1d). Taken together, our results demonstrate that not only do different sensory neurons participate in the processing of mechanosensory information in each sex, the molecules involved in this processing in the sensory neurons are, too, distinct between the sexes (Fig. 2d).
The tail mechanosensation circuit is sexually dimorphic at the interneuron level
The predicted sexually dimorphic connectivity of the sensory neurons (Fig. 1a) suggests dimorphic activities for the downstream interneurons. The sex-shared interneuron AVG is predicted to possess a striking dimorphic connectivity pattern according to the published connectomes, receiving more inputs in males compared to hermaphrodites (Supplementary Fig. 2). Given that the sensory cells connected to AVG in males are the ones with a suggested role in mechanosensation, we speculated that AVG might be involved in tail mechanosensation. Therefore, we silenced AVG using a cell-specific driver (Supplementary Fig. 3a, b) and tested animals for tail-touch responses in both sexes. We found that silencing AVG elicits a sexually dimorphic effect on tail mechanosensation, reducing only the male response (Fig. 3a), in agreement with AVG’s predicted dimorphic connectivity.
If AVG connectivity to the sensory neurons plays a significant role, rewiring AVG’s connections should affect tail-mechanosensation responses. Namely, adding connections in hermaphrodites would elicit an effect, and vice-versa for males. We therefore manipulated the sex-determination pathway of the worm specifically in AVG to switch its sexual identity and connectivity to that of the opposite sex43,44,45. Sex-reversals were done by manipulating the activity of the Gli transcription factor TRA-1, the master regulator of sexual differentiation in C. elegans46,47. TRA-1 is expressed ubiquitously in hermaphrodites and is thought to autonomously control cell-type-specific transcription programs that, in turn, control specific sexually dimorphic features48. In males, TRA-1 is downregulated via protein degradation49,50. To feminize, we expressed the intracellular domain of TRA-2, tra-2(ic), which constitutively signals to prevent TRA-1 downregulation and to masculinize, we cell-specifically expressed FEM-344,45. We found that sex-reversing AVG is sufficient to convert the phenotype of the AVG-silenced tail-touch response: In hermaphrodites with a masculinized AVG, the tail-touch response was impaired when AVG was silenced compared to wild-type hermaphrodites, and in males with feminized AVG, the tail-touch response was rescued when AVG was silenced compared to wild-type males (Fig. 3b). These results suggest that the sexual identity of AVG and consequently its wiring pattern, can shape tail mechanosensory behavior.
Since the behavioral output of harsh touch applied to the tail is a forward movement, we asked whether optogenetic activation of AVG will result in forward movement only in males, as was shown for the sensory phasmid neurons in hermaphrodites25. Optogenetic activation of AVG did not affect the forward or total (forward + reverse) speed of the animals in both sexes (Supplementary Fig. 4). However, optogenetic inhibition of AVG reduced the total speed of males only (Fig. 3c, d). Thus, AVG is required for locomotion in a sexually dimorphic manner.
We next tested whether the sex-shared interneurons DVA and PVC also have a dimorphic role in tail mechanosensation. As we were unable to generate a PVC-specific driver, in accordance with previous observations51 (Supplementary Fig. 5), we focused on the role of DVA. A tail-touch assay on DVA-silenced animals revealed that only hermaphrodites are affected (Fig. 3a, Supplementary Fig. 3c), in agreement with the predicted connectivity (Fig. 1a). Taken together, our results uncover the sex-specific use of different interneurons in the circuit for tail mechanosensation, and assign a functional role for AVG in locomotion and mechanosensation.
Since we uncovered sexually dimorphic functions of the interneuron level in the circuit, we explored potential molecular mechanisms that might govern these differences. To this end, we screened a list of glutamate receptor genes expressed in the relevant interneurons (AVG, DVA and PVC34,52; Fig. 3e), as the sensory neurons required for tail mechanosensation are glutamatergic53. We found that two glutamate receptors are required for tail mechanosensation in a sexually dimorphic manner: glr-1 (AMPA type) is needed only in hermaphrodites, while nmr-1 (NMDA type), which operates in both sexes, has a stronger effect in males (Fig. 3f–h, Fig. 4a). Taken together, our data suggest that the dimorphic nature of the tail mechanosensation circuit spans beyond mere neuronal connectivity to include also different receptor dependency (Fig. 3i).
NMDA receptor nmr-1 is required specifically in AVG to mediate tail mechanosensation in males
We next sought to assess the cell-autonomous role of nmr-1 in tail mechanosensation in AVG. We found that cell-specific expression of nmr-1 in AVG rescues the defective tail-touch phenotype of mutant males and not of hermaphrodites (Fig. 4a), suggesting that nmr-1 functions cell autonomously in male AVG. In line with this observation, the expression of nmr-1 fosmid in AVG was higher in males (Fig. 4b, c).
Since we observed that the sexual identity of AVG is sufficient to determine the behavioral outcome of the circuit when AVG is silenced (Fig. 3b), we asked whether this is also true in nmr-1 mutant animals. Sex-reversing AVG in nmr-1 mutant animals switched the tail-touch phenotype to that of the opposite sex, i.e., it reduced the tail-touch response in hermaphrodites with masculinized AVG and enhanced it in males with feminized AVG (Fig. 4d, e). These results corroborate the observations of the cell-specific rescue experiment, and point to a cell-autonomous role for nmr-1 in AVG in males that mediates tail mechanosensation. Importantly, the sexual identity of AVG not only dictates the connectivity pattern43, but also the cell-autonomous molecular pathway that mediates the behavior. Does the sexual identity of AVG modulate the circuit architecture at the sensory level? To test this notion, we checked the tail-touch responses of AVG masculinized hermaphrodites or AVG feminized males in nmr-1 mutant background, with either PHA or PHC silencing. Remarkably, hermaphrodites with masculinized AVG that show reduced tail-touch responses in the absence of nmr-1 required PHA and not PHC (Fig. 4f). On the other hand, males with feminized AVG that show enhanced tail-touch responses in the absence of nmr-1 do not require PHA or PHC for their responses (Fig. 4f). This result demonstrates that manipulating the circuit organization of the hermaphrodites by masculinizing AVG is sufficient to achieve sensory level processing similar to that of males (requirement of PHA, Fig. 1f). However, in males, switching the sex of AVG is only sufficient to abolish the requirement of PHA at the sensory level. Taken together, the contribution of different sensory neurons in tail mechanosensation is dramatically changed by sex reversal of AVG with a stronger effect in hermaphrodites compared to males.
Our reverse genetic screen uncovered a sex-specific role also for glr-1 in tail mechanosensation in hermaphrodites (Fig. 3f). However, cell specific rescue experiments of glr-1 in AVG or DVA did not restore the defective tail-touch response of the hermaphrodites (Supplementary Fig. 6), suggesting glr-1 operates through a different unidentified interneuron/s.
Our results also show a subtle defect in tail mechanosensation in nmr-1 mutant hermaphrodites (Fig. 4a, d). Since DVA is required for tail-touch response only in hermaphrodites (Fig. 3a), and nmr-1 is known to be expressed in hermaphrodites in DVA (Fig. 3e), we checked whether nmr-1 functions through DVA to mediate tail mechanosensation. Re-expressing nmr-1 in DVA did not rescue the response of nmr-1 mutant hermaphrodites (Fig. 4g), suggesting nmr-1 might be required in a different interneuron, such as PVC, for tail mechanosensation (Fig. 4h).
Mechanical stimulation of the tail elicits a sexually dimorphic neuronal response in AVG
Since AVG has a role in integrating mechanical information specifically in males, we asked whether it is activated in response to the application of mechanical force to the tail, and whether such activation occurs sex-specifically. We recorded the calcium traces of AVG in both sexes in response to tail mechanical stimulation using a microfluidic device that was adjusted to fit the male body54 (Supplementary Fig. 7). Similar to previous observations in touch receptor neurons54, we found that AVG exhibits blue-light-evoked Ca2+ transients even in the absence of a mechanical stimulus, suggesting a stimulatory effect of LITE-1 on AVG (Supplementary Fig. 8). We therefore measured the mechanosensitive activity of AVG under a lite-1 mutant background. Three consecutive tail mechanical stimulations, but not posterior stimulations (mock), elicited neuronal responses in AVG (Fig. 5a–c, Supplementary Movie 1). Importantly, these responses were sexually dimorphic, being significantly lower in hermaphrodites compared to males (Fig. 5a, b; Supplementary Fig. 9a). These findings support our behavioral results, and further indicate that AVG integrates mechanosensory information in a dimorphic manner. In line with the cell-autonomous role we uncovered for nmr-1 in AVG in tail mechanosensation, we found that AVG responses to mechanical stimulations were reduced in nmr-1 mutant males compared to controls (Fig. 5d, Supplementary Fig. 9b).
We next asked how the sensory processing of mechanical stimulation is translated at the interneuron level. To explore this issue, we recorded the calcium traces of AVG in response to tail mechanical stimulation in mec-12 mutant males, where sensory processing of mechanical stimulation is compromised (Fig. 2). Interestingly, mec-12 mutant males showed significantly lower AVG responses compared to wild-type (Fig. 5f, Supplementary Fig. 9c). This result indicates that proper sensory perception of mechanical stimulation through mec-12 is critical for the integration at the interneuron level. We also observed lower AVG responses both in nmr-1 and mec-12 mutant hermaphrodites, suggesting a role for the two genes in AVG integration of mechanical stimulation in hermaphrodites as well (Fig. 5e, g). We then hypothesized that if mec-12 re-expression in PHA rescues the behavioral phenotype (Fig. 2a), it would also rescue the neuronal activity of AVG in males. Indeed, re-expression of mec-12 in PHA was sufficient to restore the neuronal activity in AVG (Supplementary Fig. 9d, e). Taken together, AVG integrates tail mechanosensation in a sexually dimorphic manner, and requires mec-12- input from PHA and the glutamate receptor nmr-1 for this purpose.
TMC-1 over-expression in PHA reshapes the circuit for tail mechanosensation
To further support a functional role for tmc-1 in tail touch sensation, we imaged AVG neuronal activity in hermaphrodites in which we over-expressed tmc-1 in PHA. In hermaphrodites, PHA is connected directly to AVG and both neurons are not normally required for tail mechanosensation (Figs. 1a, b, 3a). We hypothesized that tmc-1 over expression in PHA would be able to increase the neuronal response of AVG in hermaphrodites. Indeed, over-expressing tmc-1 in PHA in hermaphrodites resulted in a robust response to tail mechanical stimulation in AVG which was not observed in wild-type hermaphrodites (Fig. 6a). We next wondered whether this ectopic activation of AVG in response to tail touch in PHA::tmc-1 hermaphrodites is translated to a rescue of the behavioral response of tmc-1 mutants, despite the fact that normally hermaphrodites do not require PHA for mechanosensation (Fig. 1). Expressing tmc-1 specifically in PHA resulted in partial but significant rescue of the defective tail-touch responses of tmc-1 mutant hermaphrodites (Fig. 6b). This result shows that high expression of tmc-1 in the tail has the power to rearrange the hermaphrodite circuit to activate AVG and elicit a behavioral response, thus supporting an instructive role for tmc-1 in tail mechanosensation.
nmr-1 and mec-12 play a role in the male mating behavior
The male tail bears the copulatory apparatus and contains specialized sensory structures required for mating55. We thus wondered whether the male-specific use of particular neurons and genes for tail mechanosensation may reflect a broader role they have in the mating circuit. To test this, we performed mating assays on mutants for the male-specific genes we discovered, mec-12 and nmr-1. While mec-12 mutant males did not show any defects in mating, nmr-1 mutant males were defective in their response to contact with hermaphrodites, and in their ability to locate the hermaphrodite vulva, crucial steps in the mating sequence (Fig. 7a, b). Moreover, double mutant males for nmr-1 and mec-12 were defective also in the time that passed until successful mating (Fig. 7c), revealing a synthetic interaction between the two genes that enhances the mating defects. These findings demonstrate that nmr-1 and mec-12 work in tandem in males to mediate optimal mating, and suggest that the same mechanisms that mediate tail mechanosensation are also at play in executing appropriate mating behavior.
We therefore tested whether the tail mechanosensation circuit is already functional at earlier stages, even before maturation of the mating circuit of males. We performed tail-touch assay on juvenile wild-type animals and found that the response of both sexes is very low at this stage, compared to adult animals (Supplementary Fig. 10). In addition, juvenile responses of both sexes were unaffected by mutations in the sex-specific genes required later for adult tail mechanosensation i.e. nmr-1, mec-12 and tmc-1 (Supplementary Fig. 10). These findings suggest that the full scope and dimorphic nature of the tail mechanosensation circuit develops only after sexual maturation, enabling proper response of adult animals.
Discussion
In this study, we present a unique example for a simple sensory circuit that displays extensive sexual dimorphism, engaging different combinations of cells, connections and molecular pathways in the two sexes to mediate the same sensory modality, i.e., tail mechanosensation (Fig. 8). While very few studies have analyzed the dimorphic properties of sensory circuits in detail in vertebrates, several examples exist in C. elegans for either cellular or molecular sensory dimorphism. For example, hermaphrodites detect food-related olfactory cues better than males due to enhanced expression of the odorant receptor ODR-10 in the AWA neuron1. Conversely, in the anterior nociceptive circuit, sensory detection of aversive cues seems identical in the two sexes, but the downstream connectivity to interneurons is highly dimorphic10. These topographical differences drive sexually dimorphic behavioral responses to nociceptive cues. Notably, in these examples, the dimorphic properties of the circuit lead to dimorphic behavioral outputs, whereas in the circuit we studied here, wild-type males and hermaphrodites respond to the stimulus in the same manner, suggesting that this modality is crucial for the survival of both sexes. It is tempting to speculate that one key driver for the observed dimorphisms in this circuit is the need for males to integrate the mating circuit into the shared nervous system, forcing the redistribution of cells and genes in a different configuration from that of hermaphrodites.
We found four genes that function sex-specifically in the circuit: mec-12 and tmc-1 in sensory cells, and glr-1 and nmr-1 in interneurons. Previous reports indicate that the alpha-tubulin MEC-12 is required with the beta-tubulin MEC-7 for 15-protofilament microtubule assembly in touch receptor neurons (TRNs), responsible for the transduction of gentle touch38,56. Our data suggests that MEC-12 functions through PHA to mediate tail mechanosensation in males, but whether this function requires MEC-7 remains to be determined. The involvement of PHA a ciliated neuron, in tail mechanosensation in males and not the non-ciliated PHC suggests that the defects in mec-12 mutant males are likely due to aberrant cilia formation in these neurons. It appears that MEC-12, a molecule required for gentle touch22, is also required for harsh touch, suggesting some overlap between the molecular mechanisms mediating the two modalities, as was previously shown for MEC-10 and MEC-323,24.
We also found that the ion channel TMC-1 is a hermaphrodite-specific mediator of tail mechanosensation. This finding adds to a growing repertoire of sensory functions attributed to tmc-1 in C. elegans, including salt sensation, avoidance of noxious alkaline environments, egg laying, gentle-nose touch response, and the inhibition of egg-laying in response to a harsh mechanical stimulus32,39,57,58,59. Taken together, TMC-1 appears to function as a polymodal ion channel, enabling the processing of different types of information. In Drosophila, tmc is required for mechanosensitive proprioception60, whereas in mice, Tmc1 is expressed in cochlear hair cells and is required for proper mechanotransduction40,41,61,62. In both mice and humans, dominant and recessive mutations in Tmc1 leading to deafness have been identified61,62. Sex differences in hearing loss have been documented in mice63,64,65,66, raising the possibility that sex-specific mechanisms involving Tmc1 may also exist in vertebrates. While a possible dimorphic role for Tmc1 in higher organisms is yet to be discovered, our results highlight the importance of research on sex-differences for future sex-specific therapeutic approaches.
Our previous and current work together show that AVG is a key dimorphic hub interneuron, responding differently in males and hermaphrodites to at least two separate modalities, tail mechanosensation and nociception67. The response of AVG to mechanical stimulation is achieved only when the tail is stimulated but not when other posterior body areas are touched, emphasizing that the input arrives from the tail sensory neurons and that the response to a harsh touch in the tail and the posterior body are distinct modalities involving different cellular and molecular mechanisms25. Blue-light-evoked activity in AVG independently of mechanical stimulation suggests that LITE-1 has a role in or upstream to AVG. Supporting this possibility are the findings that AVG is the neuron with the strongest expression of lite-134 and that PHA requires LITE-1 for H2O2 sensation68.
While most studies focus on sex differences between sensory neurons and motor neurons, we emphasize the importance of interneuron plasticity by exposing the intricate use of sex-shared interneurons as dimorphic hubs for different circuits. For example, the AVG interneuron is necessary only in males both for tail-touch and for locomotion speed, whereas the DVA interneuron is necessary for tail-touch only in hermaphrodites and for locomotion speed only in males69. Our work also reveals some overlap between the male mechanosensory circuit and the mating circuit, suggesting that males utilize similar mechanisms to execute different behaviors, both in terms of the cells involved (e.g., AVG and PHB in this study, and see also43) and the molecular mechanisms (nmr-1 and partially mec-12 in this study).
The published connectivity maps suggest that PVC probably plays a critical role in the integration of mechanosensation in both sexes, together with AVG in males and DVA in hermaphrodites. Therefore, a combinatorial system of interneurons seems to be at play to mediate multiple different circuits in each sex.
Despite the superficial similarity in the response of both sexes to touch, we uncover here that the propagation of mechanosensory information is dramatically different, providing evidence for a sexually dimorphic integration of touch signals. Our results contribute to the understanding of how sexually dimorphic circuits function to provide the organism with both the sensation of the environment and the behaviors that ensure its fitness.
Methods
C. elegans strains
Wild-type strains were C. elegans variety Bristol, strain N2. him-5(e1490) or him-8(e1489) were treated as wild-type controls for strains with these alleles in their background. Worms were maintained according to standard methods70. Worms were grown at 20 °C on nematode growth media (NGM) plates seeded with bacteria (E. coli OP50) as a food source. All the transgenic animals used in this study are listed in Supplementary Table 1, ordered by figures.
Histamine-induced silencing
NGM-Histamine plates were prepared as described30. 10 mM NGM-histamine was prepared by adding 5 mL of 1 M histamine dihydrochloride to 500 mL of the agar while stirring. NGM-histamine and control-agar (with no addition of histamine) were then poured into labeled petri dishes. NGM-histamine (10 mM) and control plates were stored at 4 °C for no longer than 2 months. Histamine plates were tested using worms that carry a transgene with a pan-neuronal HisCl1 (tag-168::HisCl1::SL2::GFP)30. After a few minutes on histamine plates, these worms were paralyzed completely, validating the potency of the histamine plates.
Tail-touch assay
The assay was based on25. In brief, L4 animals were isolated the day before the experiment and stored at 20 °C overnight. On the day of the experiment, single 1-day adult animals were transferred into NGM plates freshly seeded with 30 μl OP50. After 30 min of habituation, animals were tested by applying a touch to the tail with a flattened platinum wire pick. Touch was applied to worms that did not move or moved very slowly. Each worm was tested five times with intervals of at least 10 s between each trial. The tested worm was given a score of one if it moved forward in response to the touch, and zero if it did not move forward. The response index was then calculated as the average of the forward responses. For assays using histamine-gated chloride channels, animals were grown on histamine plates or control plates seeded with 200–300 μl OP50 overnight. On the day of the experiment, single 1-day adult animals were assayed on histamine plates or control plates seeded with 30 μl OP50. For assays using RNAi, him-5(e1490) animals were grown on RNAi plates or control plates seeded with 200 μl of the RNAi bacteria. For assays using juvenile animals, worms were bleached and grown at 25 °C for one day to reach L3. The assay was done at L3 stage and animals were kept on the assay plate and scored for the sex when they reached L4. Experiment was done until a sufficient number of males (13 or more) was collected, and statistics was done with an equal number of hermaphrodites from the same experiment that were chosen randomly. All statistical analysis for behavioral assays were computed using GraphPad version 9.
Molecular cloning
To generate the mec-12 rescue constructs pYS55 and pYS57 (srg-13p::mec-12 for PHA rescue and gpa-6::mec-12 for PHB rescue, respectively), mec-12 cDNA was amplified from a N2 mixed-stage cDNA library and cloned by Gibson assembly71 into srg-13p or gpa-6p plasmid backbones.
To generate the mec-12 rescue construct pHS16 (che-12p::mec-12), mec-12 cDNA was amplified from a N2 mixed-stage cDNA library and cloned by Gibson assembly71 into a che-12p plasmid backbone.
To express tmc-1 cDNA specifically in PHC, tmc-1 cDNA was amplified from pEK158 (kind gift from Eva Kaulich and Bill Schafer) and fused to a plasmid backbone containing the eat-4p11 promoter and upstream of an SL2::NLS::tagRFP cassette by Gibson assembly, creating pYS54. The tmc-1 cDNA::SL2::NLS::tagRFP was then subcloned under the srg-13 promoter by Gibson assembly to generate the PHA rescue plasmid pYS56.
To generate the optogenetics plasmids (pHS5 - inx-18p::NpHR::mCherry and pHS6 - inx-18p::Chr2::mCherry), NpHR and Chr2 were amplified from plasmids provided by Alon Zaslaver and cloned into pMO4643.
To generate the nmr-1 rescue constructs pHS14 (inx-18p::nmr-1 cDNA) and pYS53 (WT300::pes-10::nmr-1 cDNA), nmr-1 cDNA was amplified from a N2 mixed-stage cDNA library and cloned by Gibson assembly into an inx-18p plasmid backbone, and pHS11 (WT300::pes-10::mCherry, swapping the mCherry fragment), respectively. WT300 was amplified from genomic DNA72. To generate pYS52 (WT300::pes-10::HisCl1::SL2::GFP), HisCl1::SL2::GFP was amplified from pMO4643 and cloned into pHS11 (WT300::pes-10::mCherry, swapping the mCherry fragment) using Gibson assembly.
pYS56 (WT300::pes-10::glr-1 cDNA) was created by amplifying glr-1 cDNA from a N2 mixed-stage cDNA library and cloned by Gibson assembly into pYS53 (WT300::pes-10::nmr-1), swapping nmr-1 with glr-1 cDNA.
The translational mec-12p::mec-12::GFP construct was created by PCR fusion73. A 10.6Kb mec-12 genomic fragment encompassing 3Kb upstream of TSS and the full mec-12 cDNA was amplified from N2 genomic DNA and connected by PCR fusion to a pPD95.75-based GFP::unc-54 3’UTR fragment.
RNAi
RNA interference was performed using the feeding method74. L4 hermaphrodites were fed HT115 bacteria carrying dsRNA for the relevant genes or a control empty vector, and their progeny were assayed for a tail-touch response at 1-day adult. pos-1 RNAi served as a positive control for RNAi efficiency. A fresh pos-1 control was prepared for each RNAi experiment.
DiD staining
Worms were washed with M9 buffer and incubated overnight in 1 ml M9 and 5 µl DiD dye (Vybrant™ DiD Cell-Labeling Solution, ThermoFisher) at ~10–20 rpm. The worms were then centrifuged and transferred to a fresh plate.
Microscopy
Animals were mounted on a 5% agarose pad on a glass slide, on a drop of M9 containing 100–200 mM sodium azide (NaN3), which served as an anesthetic. A Zeiss LSM 880 confocal microscope was used with 63x or 10x magnification. Zen software was used for imaging (version 2.3). For nmr-1 fosmid, AVG was identified using mCherry expression, and the z-plane with the strongest signal was chosen to measure the fluorescence intensity using ImageJ version 1.52p. All statistical analysis imaging were computed using GraphPad version 9.
Optogenetics
For optogenetic inhibition or activation, we used worms expressing NpHR or Chr2, respectively, only in AVG (inx-18p::NpHR::mCherry/inx-18p::Chr2::mCherry). L4 worms were picked a day before the experiment and separated into hermaphrodite and male control and experiment groups. They were transferred to newly seeded plates with 300 μl OP50 that was concentrated 1:10. ATR (all-trans-retinal) was added only to the experimental groups’ plates, to a final concentration of 100 μM. As ATR is sensitive to light, all plates were handled in the dark. Tracking and optogenetics was done on unseeded NGM plates. On the day of the experiment, the plates were seeded with 30 μl OP50, and ATR was added to the experimental group’s plates. To keep the worms in the camera field of view, a plastic ring was placed on the agar and a single worm was placed inside the ring. After 10 min of habituation, the worm was tracked for 90 s, with 30 s of 540 nm LED activation initiated 30 s after tracking commencement. The LED intensity was 0.167 mW/mm2. Speed measurements were extracted for the different time periods from WormLab (MBF Bio-science75) using “label-analysis”. The head position trajectory quadrants were also extracted from WormLab, and inserted into a graph using MATLAB (version R2019B). Statistical were computed using GraphPad version 9.
For optogenetic activation, 3–5 worms were placed inside a plastic ring on the agar each time. After 10 min of habituation, the worms were tracked for 60 s, with a 2-second blue-light stimulus introduced every 10 s (5 stimuli in total). The LED intensity was 1.47 mW/mm2. Speed measurements were extracted for all the time points from WormLab. For each stimulus, the mean total speed was calculated before the stimulus (3 s) and after the stimulus (5 s). Calculations were done using MATLAB (version R2019B).
Calcium imaging of animals in the microfluidic chip
Mold design and preparation
Microfluidic devices are based on the body wall touch device54. Subtle modification in the trapping channel (width and height have been adjusted to 30 µm) were applied to fit male animals, which are skinnier than hermaphrodites, and the devices were cast with a PDMS base polymer/curing agent ratio to allow for large deflection of the diaphragm. The male body wall touch design, drawn with AutoCAD 2021, is illustrated in Supplementary Fig. 7a; its file is available to download in the Supplementary Material (Supplementary Data 1). Supplementary Fig. 7a shows how perfectly the modified trapping channel fits the males. To further enable a larger deflection, the size of the diaphragm was decreased to 10 microns. The deflection of the actuator under different pressure levels is presented in Supplementary Fig. 7c; the graph highlights the consistency of the numerical results with the experimental data.
The mold was prepared using a standard soft-lithography technique in a class ISO2 cleanroom76. In short, 4-inch silicon wafers were cleaned in Piranha and dehydrated by baking at 150 °C. The dried, cleaned wafers were spin-coated with 1 ml/inch SU8-50 (MicroChem, Newton Massachusetts, USA) to obtain a 30-micron height (500 RPM (100 RPM/s acceleration for 15 s)) and then ramped to a final speed 3300 RPM for 45 s (300 RPM/s acceleration). The SU8 layer was pre-baked at 65 °C for 5 min and then at 95 °C for 15 min. The device design was ‘printed’ with a UV laser onto the SU8 substrate with a mask-less aligner (MLA, Heidelberg Germany). Once the printing process was finished, the wafer was post-baked for 1 min at 65 °C and then for 4 min at 95 °C. The exposed SU8 was developed for 6 min in an SU8 developer (MicroChemicals) and rinsed with propanol, to remove unexposed resin. Thereafter, the wafer was hard-baked for 2 h at 135 °C and used for replica-molding PDMS devices. First, the surface of the structured wafer was vapor-phase silanized with Chlorodimethylsilane (Sigma-Aldrich, Missouri, United States) to prevent adhesion of the PDMS to the substrate and facilitate lift-off of the PDMS during the peeling process. The PDMS base polymer and curing agent were mixed at a ratio of 15:1 and approximately 40 mL per wafer were prepared and degassed before pouring to prevent bubbles. The degassed PDMS was poured into the mold and cured in the oven at 85 °C for two hours. After lift-off and trimming the devices to fit onto standard #1.5 cover glasses, all inlets and outlets were punched with a biopsy punch (0.75 mm), which served as a receptacle for the connection tubes. Finally, to bind the PDMS with the cleaned cover slip, the surface of the coverslip was activated by a plasma treatment (Plasma Asher PVA TePla 300), and to increase the bonding quality, the bonded chip was placed on a hotplate (120 °C) for 10 min. The punch holes were plugged with SC22/15-gauge metal tubes connected to 22-gauge catheter tubing.
Animal loading, stimulation and fluorescence microscopy
Animals were placed in the device exactly as described and shown in77. In brief, 3–4 synchronized day-one adult animals (males or hermaphrodites) were picked from an NGM plate containing OP50 bacteria and transferred into a 15 µL droplet of M9 buffer. Using a stereo dissecting scope (Leica S9), the animals were aspirated into a SC22/15-gauge metal tube (Phymep) connected to a 3 mL syringe (Henke Sass Wolf) with a PE tube (McMaster-Carr) pre-filled with M9 buffer. The loading tube was inserted into the inlet port of the device, while gentle pressure to the plunger of the syringe released the animals into the loading chamber. The microfluidic chip was then transferred to a compound fluorescence microscope (Leica DMi8), and with the 25 × 0.95 water immersion lens, the animal was positioned such that the tail aligned with an actuator (Fig. 5a), ready to accept a mechanical stimulus. Once positioned properly, AVG was brought into focus and the stimulation protocol was started. GCaMP in AVG was excited with a cyan LED of a Lumencor SpectraX light engine (470 nm @ 2% transmission or 0.32 mW at the sample plane). The incident power of the excitation light was measured with a microscope slide powermeter head (Thorlabs, S170C) attached to PM101A power meter console (Thorlabs). Emission was collected through a 515/15 nm emission filter (Semrock) and videos were captured at a 10 Hz acquisition rate (85 ms exposure time) with a Hamamatsu Orca Flash 4.3 for 65 or 75 s, using HCImage software. A master-pulse was used to synchronize the camera acquisition with the light exposure. Likewise, the camera SMA trigger was connected to the OB1 pressure controller and used to synchronize the image acquisition with the pressure protocol through the ElveFlow sequencer software prior to the imaging routine, ensuring precise and repetitive timing of the pressure protocol. The sequence consisted of 100 pre-stimulus frames and three consecutive mechanical stimuli, each separated by 20 s. The stimulus profile consisted of a 2-second 250 kPa pressure step, overlayed with a 150 kPa oscillation, resulting in a maximum deflection of 9 µm (Supplementary Fig. 7c).
Analysis
Image processing and analysis were performed as described in20. In brief, to extract GCaMP intensity over time, images were preprocessed in ImageJ and then imported into python to extract signal intensity using in-house procedures written in Python (Version 2.7) or IgroPro (Version 6.370). In short, the image sequence was cropped to a small area surrounding the cell body (or the axon, Supplementary Fig. 9d) of the neuron of interest and a Gaussian filter was applied. All pixel values in the ROI were ranked and the background intensity was extracted from the 0–10th percentile and the GCaMP signal was extracted from the 90–100th percentile. After background subtraction, signal intensity (F) was normalized to the median value of the first 100 frames (Fb, before the mechanical stimulus was applied according to (F-Fb)/Fb).
To calculate a time-varying p-value comparing two datasets derived from different conditions, we first calculated the average calcium response after performing a non-linear baseline subtraction (bleach correction, drift) of each individual recording, taking advantage of an iterative algorithm to suppress the baseline by means in local windows78. To minimize spurious fluctuations in p-values due to imaging noise, a smoothing kernel based on the 2nd derivative penalty, known as a Whittaker smoother79, was applied. The t-test statistics was then used to calculate the p-value considering the degrees of freedom, df = N1 + N2-2; the null hypothesis was rejected if the absolute value of t was larger than its critical value at the level of significance alpha = 0.01. Outliers were identified based on a z-score > |7| , which means that Calcium recordings that appeared different than 7 standard deviation from the mean were omitted from the statistical analysis according to z = (t-µ)/sigma (with z as the z score, t as the testable variable, µ and sigma as the mean or the standard deviation of the population). In total 2 outliers in two different data sets have been identified. All operations were performed in R version 4.0.2 (2020-06-22), using custom routines involving the baseline package V1.3-1.
Mating assay
Mating assays were as described in ref. 43. In brief, Early L4 males were transferred to fresh plates and kept apart from hermaphrodites until they reached sexual maturation. Single virgin males were assayed for their mating behavior in the presence of 10–15 adult unc-31(e928) hermaphrodites on a plate covered with a thin fresh E. coli OP50 lawn. Mating behavior was scored within a 12-minute time window or until the male ejaculated, whichever occurred first. Mating was recorded using a Zeiss Axiocam ERc 5 s mounted on a Zeiss stemi 508. The movie sequence was analyzed and the males were tested for their ability to perform an intact mating sequence80. Males were scored for their time until successful mating, contact response and vulva location efficiency. Males that did not mate within 12 min were not analyzed for time until successful mating. Contact response requires tail apposition and initiation of backward locomotion. Percentage response to contact = 100 × (the number of times a male exhibited contact response/the number of times the male makes contact with a hermaphrodite via the rays)43,81. Vulva location efficiency (L.E.)82, or the ability to locate the vulva, was calculated as 1 divided by the number of passes or hesitations at the vulva until the male first stops at the vulva or until the end of the recording. All statistical analysis for mating assays were computed using GraphPad version 9.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
The authors declare that all data generated or analyzed during this study are included in this published article (and its supplementary information files). The raw data generated in this study are provided in the Source Data file. Source data are provided with this paper.
Code availability
The code generated in this study has been deposited at https://doi.org/10.34933/wis.000652 and is publicly available as of the date of publication.
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Acknowledgements
We thank members of the Oren-Suissa lab for their critical insights regarding the manuscript. The plasmids to amplify Chr2 and NpHR were a generous gift from Alon Zaslaver. The primer sequences to generate pHS11 were a kind recommendation of Carmine Puckett Robinson. The pEK158 plasmid and the AQ4330 strain were a kind gift from Eva Kaulich and Bill Schafer. Some strains were provided by the CGC, which is funded by the NIH Office of Research Infrastructure Programs (P40 OD010440). This work was supported by the European Research Council ERC-2019-STG 850784 (MOS), Israel Science Foundation grant 961/21 (MOS). MOS is grateful to the Azrieli Foundation for the award of an Azrieli Fellowship, and is the incumbent of the Jenna and Julia Birnbach Family Career Development Chair. MK acknowledges financial support from the ERC (MechanoSystems, 715243), HFSP (CDA00023/2018), Spanish Ministry of Economy and Competitiveness through the Plan Nacional (PGC2018-097882-A-I00), FEDER (EQC2018-005048-P), “Severo Ochoa” program for Centres of Excellence in R&D (CEX2019-000910-S; RYC-2016-21062), Fundació Privada Cellex, Fundació Mir-Puig, and from Generalitat de Catalunya through the CERCA and Research program (2017 SGR 1012).
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H.S., Y.S. conducted and analyzed the experiments, S.K. conducted and analyzed the calcium imaging experiments, E.B.B. contributed to behavioral experiments (tail-touch assays). M.K. and M.O.S. supervised and designed the experiments. H.S., Y.S. and M.O.S. wrote the paper.
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Setty, H., Salzberg, Y., Karimi, S. et al. Sexually dimorphic architecture and function of a mechanosensory circuit in C. elegans. Nat Commun 13, 6825 (2022). https://doi.org/10.1038/s41467-022-34661-3
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DOI: https://doi.org/10.1038/s41467-022-34661-3
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