Mechanotransduction: Touch and Feel at the Molecular Level as Modeled in <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis>

The survival of an organism depends on its ability to respond to its environment through its senses. The sense of touch is one of the most vital; still, it is the least understood. In the process of touch sensation, a mechanical stimulus is converted into electrical signals. Groundbreaking electrophysiological experiments in organisms ranging from bacteria to mammals have suggested that this conversion may occur through the activation of ion channels that gate in response to mechanical stimuli. However, the molecular identity of these channels has remained elusive for a very long time. Breakthroughs in our understanding of the cellular and molecular mechanisms of touch sensation have come from the analysis of touch-insensitive mutants in model organisms such as Caenorhabditis elegans and Drosophila melanogaster. This review will focus on the elegant genetic, molecular, imaging, and electrophysiological studies that demonstrate that a channel complex composed of two members of the DEG/ENaC gene family of channel subunits (named for the C. elegans degenerins and the related mammalian epithelial amiloride-sensitive Na channel), MEC-4 and MEC-10, and accessory subunits is gated by mechanical forces in touch-sensing neurons from C. elegans. I also report here electrophysiological and behavioral studies employing knockout mice that have recently shown that mammalian homologues of MEC-4, MEC-10, and accessory subunits are needed for normal mechanosensitivity in mouse, suggesting a conserved function for this channel family across species. The C. elegans genome encodes 28 DEG/ENaC channels: I discuss here the global role of DEG/ENaCs in mechanosensation, reporting findings on the role of other three nematode DEG/ENaCs (UNC-8, DEL-1, and UNC-105) in mechanosensitive and stretch-sensitive behaviors. Finally, this review will discuss findings in which members of another family of ion channels, the Transient Receptor Potential channels family, have been implicated in mechanosensitive behaviors in organisms ranging from C. elegans to mammals.     

The Multipurpose 15-Protofilament Microtubules in C. elegans Have Specific Roles in Mechanosensation

Because microtubules perform many essential functions in neurons, delineating unique roles attributable to these organelles presents a formidable challenge. Microtubules endow neurons with shape and structure and are required for developmental processes including neurite outgrowth [1], intracellular transport [2], and synapse formation and plasticity [3] and [4]; microtubules in sensory neurons may be required for the above processes in addition to a specific sensory function. In Caenorhabditis elegans, six touch receptor neurons (TRNs) sense gentle touch [5] and uniquely contain 15-protofilament microtubules [6]. Disruption of these microtubules by loss of either the MEC-7 β-tubulin [7] or MEC-12 α-tubulin [8] or by growth in 1 mM colchicine causes touch insensitivity [5] and [6], altered distribution of the touch transduction channel, and a general reduction in protein levels. We show that the effect on touch sensitivity can be separated from the others; microtubule depolymerization in mature TRNs causes touch insensitivity but does not result in protein distribution and production defects. In addition, the mec-12(e1605) mutation selectively causes touch insensitivity without affecting microtubule formation and other cellular processes. Touching e1605 animals produces a reduced mechanoreceptor current that inactivates more rapidly than in wild-type, suggesting a specific role of the microtubules in mechanotransduction.     

Genetic Analysis of a Novel Tubulin Mutation That Redirects Synaptic Vesicle Targeting and Causes Neurite Degeneration in C. elegans

Neuronal cargos are differentially targeted to either axons or dendrites, and this polarized cargo targeting critically depends on the interaction between microtubules and molecular motors. From a forward mutagenesis screen, we identified a gain-of-function mutation in the C. elegans α-tubulin gene mec-12 that triggered synaptic vesicle mistargeting, neurite swelling and neurodegeneration in the touch receptor neurons. This missense mutation replaced an absolutely conserved glycine in the H12 helix with glutamic acid, resulting in increased negative charges at the C-terminus of α-tubulin. Synaptic vesicle mistargeting in the mutant neurons was suppressed by reducing dynein function, suggesting that aberrantly high dynein activity mistargeted synaptic vesicles. We demonstrated that dynein showed preference towards binding mutant microtubules over wild-type in microtubule sedimentation assay. By contrast, neurite swelling and neurodegeneration were independent of dynein and could be ameliorated by genetic paralysis of the animal. This suggests that mutant microtubules render the neurons susceptible to recurrent mechanical stress induced by muscle activity, which is consistent with the observation that microtubule network was disorganized under electron microscopy. Our work provides insights into how microtubule-dynein interaction instructs synaptic vesicle targeting and the importance of microtubule in the maintenance of neuronal structures against constant mechanical stress.     

Stochastic formulation for a partial neural circuit of <Emphasis Type="Italic">C. elegans</Emphasis>

We present a stochastic formulation for a partial neural circuit of Caenorhabditis elegans. This study is concerned with how to reduce the degree of freedom in a large neural circuit. In the presented formulation, neurons in the whole neural circuit are divided into two complementary groups. One is the neurons which are mainly associated with a certain behavior, and the other is the remaining neurons of C. elegans. In an ordinary study on a partial neural circuit, the influence of the latter (the remaining neurons) on the former (the associated neurons) is completely neglected. In the presented formulation, however, the influence is expressed by a stochastic variable. The structure of the ensemble for the stochastic variable is appropriately evaluated by the neural connectivity of C. elegans since the neural connectivity of C. elegans has been completely determined. In this way, the degree of freedom is effectively reduced. We apply the presented formulation to determine the synaptic signs in the touch sensitivity circuit of C. elegans. The synaptic signs are determined to satisfy the locomotory behaviors in C. elegans. We find that the influence of the remaining neurons on the touch sensitivity circuit is important to determine the synaptic signs.     

High copy arrays containing a sequence upstream of mec-3 alter cell migration and axonal morphology in C. elegans

Background

The Caenorhabditis elegans gene mec-3 encodes a LIM-homeodomain protein that is a master regulator of touch receptor neuron genes. Two of the touch neurons, the ALM neurons, are generated in the anterior of the animal and then migrate to near the middle of the animal. In animals transformed with a sequence upstream of mec-3, the ALM touch receptor neurons failed to migrate to their normal positions and sometimes migrated in the wrong direction, and the PLM touch receptor neurons showed axonal defects. Here we characterize this effect and identify the sequence causing the cell migration and axonal defects.

Results

The ALM migration defect did not result from RNA interference (RNAi), nonspecific effects of carrying a transgenic array, expression of GFP, or the marker gene used to make the transformants. Instead, the ALM migration defect resulted from transgenic arrays containing many copies of a specific 104 bp DNA sequence. Transgenic arrays containing this sequence did not affect all cell migrations.

Conclusions

The mec-3 upstream sequence appeared to be sequestering (titrating out) a specific DNA-binding factor that is required for the ALMs to migrate correctly. Because titration of this factor could reverse the direction of ALM migrations, it may be part of a program that specifies both the direction and extent of ALM migrations. mec-3 is a master regulator of touch receptor neuron genes, so the factor or factors that bind this sequence may also be involved in specifying the fate of touch receptor neurons.     

Epistatic,synthetic, and balancing interactions among tubulin missense mutations affecting neurite growth in Caenorhabditis elegans

Mutations in tubulins affect microtubule (MT) dynamics and functions during neuronal differentiation and their genetic interaction provides insights into the regulation of MT functions. We previously used Caenorhabditis elegans touch receptor neurons to analyze the cellular impact of tubulin mutations and reported the phenotypes of 67 tubulin missense mutations, categorized into three classes: loss-of-function (lf), antimorphic (anti), and neomorphic (neo) alleles. In this study, we isolated 54 additional tubulin alleles through suppressor screens in sensitized backgrounds that caused excessive neurite growth. These alleles included 32 missense mutations not analyzed before, bringing the total number of mutations in our collection to 99. Phenotypic characterization of these newly isolated mutations identified three new types of alleles: partial lf and weak neo alleles of mec-7/β-tubulin that had subtle effects and strong anti alleles of mec-12/α-tubulin. We also discovered complex genetic interactions among the tubulin mutations, including the suppression of neo mutations by intragenic lf and anti alleles, additive and synthetic effects between mec-7 neo alleles, and unexpected epistasis, in which weaker neo alleles masked the effects of stronger neo alleles in inducing ectopic neurite growth. We also observed balancing between neo and anti alleles, whose respective MT-hyperstablizing and -destabilizing effects neutralized each other.     

Functional constraint and divergence in the G protein family in <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis> and <Emphasis Type="Italic">Caenorhabditis briggsae</Emphasis>

Part of the challenge of the post-genomic world is to identify functional elements within the wide array of information generated by genome sequencing. Although cross-species comparisons and investigation of rates of sequence divergence are an efficient approach, the relationship between sequence divergence and functional conservation is not clear. Here, we use a comparative approach to examine questions of evolutionary rates and conserved function within the guanine nucleotide-binding protein (G protein) gene family in nematodes of the genus Caenorhabditis. In particular, we show that, in cases where the Caenorhabditis elegans ortholog shows a loss-of-function phenotype, G protein genes of C. elegans and Caenorhabditis briggsae diverge on average three times more slowly than G protein genes that do not exhibit any phenotype when mutated in C. elegans, suggesting that genes with loss of function phenotypes are subject to stronger selective constraints in relation to their function in both species. Our results also indicate that selection is as strong on G proteins involved in environmental perception as it is on those controlling other important processes. Finally, using phylogenetic footprinting, we identify a conserved non-coding motif present in multiple copies in the genomes of four species of Caenorhabditis. The presence of this motif in the same intron in the gpa-1 genes of C. elegans, C. briggsae and Caenorhabditis remanei suggests that it plays a role in the regulation of gpa-1, as well as other loci.Electronic Supplementary Material Supplementary material is available for this article at     

The Caenorhabditis elegans spalt-like gene sem-4 restricts touch cell fate by repressing the selector Hox gene egl-5 and the effector gene mec-3

Members of the spalt (sal) gene family encode zinc-finger proteins that are putative tumor suppressors and regulate anteroposterior (AP) patterning, cellular identity, and, possibly, cell cycle progression. The mechanism through which sal genes carry out these functions is unclear. The Caenorhabditis elegans sal gene sem-4 controls the fate of several different cell types, including neurons, muscle and hypodermis. Mutation of sem-4 transforms particular tail neurons into touch-neuron-like cells. In wild-type C. elegans, six touch receptor neurons mediate the response of the worm to gentle touch. All six touch neurons normally express the LIM homeobox gene mec-3. A subset, the two PLM cells, also express the Hox gene egl-5, an Abdominal-B homolog, which we find is required for correct mec-3 expression in these cells. The abnormal touch-neuron-like-cells in sem-4 animals express mec-3; we show that a subset also express egl-5. We report: (1) that ectopic expression of sem-4 in normal touch cells represses mec-3 expression and reduces touch cell function; (2) that egl-5 expression is required for both the fate of normal PLM touch neurons in wild-type animals and the fate of a subset of abnormal touch neurons in sem-4 animals, and (3) that SEM-4 specifically binds a shared motif in the mec-3 and egl-5 promoters that mediates repression of these genes in cells in the tail. We conclude that sem-4 represses egl-5 and mec-3 through direct interaction with regulatory sequences in the promoters of these genes, that sem-4 indirectly modulates mec-3 expression through its repression of egl-5 and that this negative regulation is required for proper determination of neuronal fates. We suggest that the mechanism and targets of regulation by sem-4 are conserved throughout the sal gene family: other sal genes might regulate patterning and cellular identity through direct repression of Hox selector genes and effector genes.     

The F-Box Protein MEC-15 (FBXW9) Promotes Synaptic Transmission in GABAergic Motor Neurons in C. elegans

Ubiquitination controls the activity of many proteins and has been implicated in almost every aspect of neuronal cell biology. Characterizing the precise function of ubiquitin ligases, the enzymes that catalyze ubiquitination of target proteins, is key to understanding distinct functions of ubiquitination. F-box proteins are the variable subunits of the large family of SCF ubiquitin ligases and are responsible for binding and recognizing specific ubiquitination targets. Here, we investigated the function of the F-box protein MEC-15 (FBXW9), one of a small number of F-box proteins evolutionarily conserved from C. elegans to mammals. mec-15 is widely expressed in the nervous system including GABAergic and cholinergic motor neurons. Electrophysiological and behavioral analyses indicate that GABAergic synaptic transmission is reduced in mec-15 mutants while cholinergic transmission appears normal. In the absence of MEC-15, the abundance of the synaptic vesicle protein SNB-1 (synaptobrevin) is reduced at synapses and increased in cell bodies of GABAergic motor neurons, suggesting that MEC-15 affects the trafficking of SNB-1 between cell bodies and synapses and may promote GABA release by regulating the abundance of SNB-1 at synapses.     

High polymorphism and resolution in targeted fingerprinting with combined β-tubulin introns

Tubulin-Based-Polymorphism (TBP) was originally introduced as a novel method for assaying genetic diversity in plants. TBP is based on polymorphism resulting from the PCR-mediated amplification of the first intron in the coding region of the β-tubulin gene family. Although, the method was successful in genetic assessment of some plant species and varieties, it suffered from low number of molecular markers due to limited variation in the first intron of β-tubulin gene family. We have now rectified this limitation by introducing the second intron of the β-tubulin genes as a valuable source of molecular markers. We show that the combined use of the two introns substantially increases the number of molecular markers and results in a reliable assessment of species/varieties relationships. After a preliminary validation on Brassica, this new combinatorial method was tested on species of Eleusine and Arachis. For both, reliable assessment of species relationships were obtained that were consistent with recently published studies resulting from more elaborated methods including DNA sequencing. Combinatorial TBP is a reliable, reproducible, simple, fast, and easy to score method that is very useful for breeding programs and species and variety assessments.     

h-TBP: an approach based on intron-length polymorphism for the rapid isolation and characterization of the multiple members of the β-tubulin gene family in <Emphasis Type="Italic">Camelina sativa</Emphasis> (L.) Crantz

We have developed a new version of the cTBP (combinatorial tubulin-based polymorphism) method, a previously described approach based on intron-length polymorphism (ILP), to rapidly characterize the β-tubulin gene family of Camelina sativa (L.) Crantz, a plant species of importance for oil production but still largely unexplored at genomic level. The method, named h-TBP, allows the rapid cloning of the β-tubulin genomic sequences that encompass the two introns, invariantly present at fixed positions within the coding region of the vast majority of the plant species. The β-tubulin sequences cloned by h-TBP also comprise part of exon1 and exon3 and the whole sequence of exon2. The h-TBP method has then been used to isolate, clone and characterize the β-tubulin gene family of C. sativa, composed of at least 20 different β-tubulin isotypes, named CsTUB1 through CsTUB20. The relatively high number of β-tubulin genes has been further substantiated by Southern-blot analysis. Comparison of the β-tubulin exon sequences of C. sativa with those of Arabidopsis thaliana, the closest relative among crucifers, defines distinct groups of putative orthologous genes, identified by a UPMGA cluster analysis. Analysis of the C. sativa β-tubulin intron sequences reveals some molecular features that can provide the first hints for the understanding of intron plasticity and evolution. From a more immediate perspective, these data provide the first substantial contribution to the characterization of the largely unexplored genome of C. sativa, and the tools for assisting programmes of breeding and selection of the most productive plants.     

Diapause Formation and Downregulation of Insulin-Like Signaling via DAF-16/FOXO Delays Axonal Degeneration and Neuronal Loss

Axonal degeneration is a key event in the pathogenesis of neurodegenerative conditions. We show here that mec-4d triggered axonal degeneration of Caenorhabditis elegans neurons and mammalian axons share mechanistical similarities, as both are rescued by inhibition of calcium increase, mitochondrial dysfunction, and NMNAT overexpression. We then explore whether reactive oxygen species (ROS) participate in axonal degeneration and neuronal demise. C. elegans dauers have enhanced anti-ROS systems, and dauer mec-4d worms are completely protected from axonal degeneration and neuronal loss. Mechanistically, downregulation of the Insulin/IGF-1-like signaling (IIS) pathway protects neurons from degenerating in a DAF-16/FOXO–dependent manner and is related to superoxide dismutase and catalase-increased expression. Caloric restriction and systemic antioxidant treatment, which decrease oxidative damage, protect C. elegans axons from mec-4d-mediated degeneration and delay Wallerian degeneration in mice. In summary, we show that the IIS pathway is essential in maintaining neuronal homeostasis under pro-degenerative stimuli and identify ROS as a key intermediate of neuronal degeneration in vivo. Since axonal degeneration represents an early pathological event in neurodegeneration, our work identifies potential targets for therapeutic intervention in several conditions characterized by axonal loss and functional impairment.     

Redirection of the phenylpropanoid pathway to feruloyl malate in <Emphasis Type="Italic">Arabidopsis</Emphasis> mutants deficient for cinnamoyl-CoA reductase 1

Cinnamoyl-CoA reductase 1 (CCR1, gene At1g15950) is the main CCR isoform implied in the constitutive lignification of Arabidopsis thaliana. In this work, we have identified and characterized two new knockout mutants for CCR1. Both have a dwarf phenotype and a delayed senescence. At complete maturity, their inflorescence stems display a 25–35% decreased lignin level, some alterations in lignin structure with a higher frequency of resistant interunit bonds and a higher content in cell wall-bound ferulic esters. Ferulic acid-coniferyl alcohol ether dimers were found for the first time in dicot cell walls and in similar levels in wild-type and mutant plants. The expression of CCR2, a CCR gene usually involved in plant defense, was increased in the mutants and could account for the biosynthesis of lignins in the CCR1-knockout plants. Mutant plantlets have three to four-times less sinapoyl malate (SM) than controls and accumulate some feruloyl malate. The same compositional changes occurred in the rosette leaves of greenhouse-grown plants. By contrast and relative to the control, their stems accumulated unusually high levels of both SM and feruloyl malate as well as more kaempferol glycosides. These findings suggest that, in their hypolignified stems, the mutant plants would avoid the feruloyl-CoA accumulation by its redirection to cell wall-bound ferulate esters, to feruloyl malate and to SM. The formation of feruloyl malate to an extent far exceeding the levels reported so far indicates that ferulic acid is a potential substrate for the enzymes involved in SM biosynthesis and emphasizes the remarkable plasticity of Arabidopsis phenylpropanoid metabolism.     

Effects of voltage‐gated calcium channel subunit genes on calcium influx in cultured C. elegans mechanosensory neurons

Voltage‐gated calcium channels (VGCCs) serve as a critical link between electrical signaling and diverse cellular processes in neurons. We have exploited recent advances in genetically encoded calcium sensors and in culture techniques to investigate how the VGCC α₁ subunit EGL‐19 and α₂/δ subunit UNC‐36 affect the functional properties of C. elegans mechanosensory neurons. Using the protein‐based optical indicator cameleon, we recorded calcium transients from cultured mechanosensory neurons in response to transient depolarization. We observed that in these cultured cells, calcium transients induced by extracellular potassium were significantly reduced by a reduction‐of‐function mutation in egl‐19 and significantly reduced by L‐type calcium channel inhibitors; thus, a main source of touch neuron calcium transients appeared to be influx of extracellular calcium through L‐type channels. Transients did not depend directly on intracellular calcium stores, although a store‐independent 2‐APB and gadolinium‐sensitive calcium flux was detected. The transients were also significantly reduced by mutations in unc‐36, which encodes the main neuronal α₂/δ subunit in C. elegans. Interestingly, while egl‐19 mutations resulted in similar reductions in calcium influx at all stimulus strengths, unc‐36 mutations preferentially affected responses to smaller depolarizations. These experiments suggest a central role for EGL‐19 and UNC‐36 in excitability and functional activity of the mechanosensory neurons. © 2006 Wiley Periodicals, Inc. J Neurobiol, 2006     

The NemaGENETAG initiative: large scale transposon insertion gene-tagging in <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis>

The nematode Caenorhabditis elegans is a widely appreciated, powerful platform in which to study important biological mechanisms related to human health. More than 65% of human disease genes have homologues in the C. elegans genome, and essential aspects of mammalian cell biology, neurobiology and development are faithfully recapitulated in this organism. The EU-funded NemaGENETAG project was initiated with the aim to develop cutting-edge tools and resources that will facilitate modelling of human pathologies in C. elegans, and advance our understanding of animal development and physiology. The main objective of the project involves the generation and evaluation of a large collection of transposon-tagged mutants. In the process of achieving this objective the NemaGENETAG consortium also endeavours to optimize and automate existing transposon-mediated mutagenesis methodologies based on the Mos1 transposable element, in addition to developing alternatives using other transposon systems. The final product of this initiative—a comprehensive collection of transposon-tagged alleles—together with the acquisition of efficient transposon-based tools for mutagenesis and transgenesis in C. elegans, should yield a wealth of information on gene function, immediately relevant to key biological processes and to pharmaceutical research and development.