Focal and segmental glomerulosclerosis (FSGS) is a common, non-specific renal lesion. Although it is often secondary to other disorders, including HIV infection, obesity, hypertension and diabetes, FSGS also appears as an isolated, idiopathic condition. FSGS is characterized by increased urinary protein excretion and decreasing kidney function. Often, renal insufficiency in affected patients progresses to end-stage renal failure, a highly morbid state requiring either dialysis therapy or kidney transplantation. Here we present evidence implicating mutations in the gene encoding alpha-actinin-4 (ACTN4; ref. 2), an actin-filament crosslinking protein, as the cause of disease in three families with an autosomal dominant form of FSGS. In vitro, mutant alpha-actinin-4 binds filamentous actin (F-actin) more strongly than does wild-type alpha-actinin-4. Regulation of the actin cytoskeleton of glomerular podocytes may be altered in this group of patients. Our results have implications for understanding the role of the cytoskeleton in the pathophysiology of kidney disease and may lead to a better understanding of the genetic basis of susceptibility to kidney damage.
gamma-Aminobutyric acid (GABA) is the most abundant inhibitory neurotransmitter in vertebrates and invertebrates. GABA receptors are the target of anxiolytic, antiepileptic and antispasmodic drugs, as well as of commonly used insecticides. How does a specific neurotransmitter such as GABA control animal behaviour? To answer this question, we identified all neurons that react with antisera raised against the neurotransmitter GABA in the nervous system of the nematode Caenorhabditis elegans. We determined the in vivo functions of 25 of the 26 GABAergic neurons by killing these cells with a laser microbeam in living animals and by characterizing a mutant defective in GABA expression. On the basis of the ultrastructurally defined connectivity of the C. elegans nervous system, we deduced how these GABAergic neurons act to control the body and enteric muscles necessary for different behaviours. Our findings provide evidence that GABA functions as an excitatory as well as an inhibitory neurotransmitter.
How does the nervous system encode environmental stimuli as sensory experiences? Both the type (visual, olfactory, gustatory, mechanical or auditory) and the quality of a stimulus (spatial position, intensity or frequency) are represented as a neural code. Here we undertake a genetic analysis of sensory modality coding in Caenorhabditis elegans. The ASH sensory neurons respond to two distinct sensory stimuli (nose touch and osmotic stimuli). A mutation in the glr-1 (glutamate receptor) gene eliminates the response to nose touch but not to osmotic repellents. The predicted GLR-1 protein is roughly 40% identical to mammalian AMPA-class glutamate receptor (GluR) subunits. Analysis of glr-1 expression and genetic mosaics indicates that GLR-1 receptors act in synaptic targets of the ASH neurons. We propose that discrimination between the ASH sensory modalities arises from differential release of ASH neurotransmitters in response to different stimuli.
After light touch to its nose, the nematode Caenorhabdids elegans halts forward locomotion and initiates backing. Here we show that three classes of neurons (ASH, FLP, and OLQ) sense touch to the nose and hence are required for this avoidance response. ASH, FLP, and OLQ have sensory endings that contain axonemal cilia. Mutant animals that have defective ciliated sensory endings as well as laser-operated animals that lack ASH, FLP, and OLQ fail to respond to touch to the nose. Together with the previous work of others, these results demonstrate that C. elegans has at least five morphologically distinct classes of mechanosensory neurons. Interestingly, the ASH neuron also acts as a chemosensory neuron; it mediates the avoidance of noxious chemicals. Since ASH possesses both chemosensory and mechanosensory modalities, this neuron might be functionally analogous to vertebrate nociceptors, which mediate the sensation of pain.Animals are exquisitely sensitive to a wide variety of mechanical stimuli, which are sensed by many distinct classes of mechanosensory neurons. For example, in mammals, the vestibular cells of the ear sense gravity (1), muscle receptors sense limb position and movement (2), and five classes of neurons sense cutaneous mechanical stimuli (3). Each class of mechanosensory neuron is morphologically distinct and can be distinguished histologically. Each class typically responds to a single type of mechanical stimulus and hence corresponds to a distinct sensory modality (e.g., sense of equilibrium, sense of spatial position, and sense of touch). However, some neurons (polymodal neurons) are sensitive to multiple types of stimuli. For example, a class of mammalian neurons that sense painful stimuli (polymodal nociceptors) responds to thermal, chemical, and mechanical stimuli (4).One class of Caenorhabditis elegans mechanosensory neurons has been extensively characterized (5-7). The neurons ALM, AVM, PLM, and PVM ( Fig. 1) have sensory endings that contain 15-protofilament microtubules rather than the 11-protofilament microtubules found in most C. elegans neurons (10) and hence are called the microtubule touch cells.These neurons sense touch; they divide the worm's body into two apparent sensory fields, anterior and posterior. Mutations in 20 genes disrupt either the development or function of the microtubule touch cells (7).We report here our characterization of an additional mechanosensory reflex, avoidance of touch to the worm's nose. Light touch to the nose causes worms to halt forward locomotion and initiate backing. We found that normal animals responded to this stimulus in 90% of the trials (Table 1, row 1). Here we identify three additional classes of mechanosensory neurons (ASH, FLP, and OLQ) that mediate this avoidance response (Fig. 1) Laser Microsurgery and Culture. In general, neurons were identified in first-stage (Li) larvae by the anatomical positions and the morphologies of their nuclei (14) and were killed by focusing a laser microbeam on identified nuclei by using the system de...
Chemical synapses are complex structures that mediate rapid intercellular signalling in the nervous system. Proteomic studies suggest that several hundred proteins will be found at synaptic specializations. Here we describe a systematic screen to identify genes required for the function or development of Caenorhabditis elegans neuromuscular junctions. A total of 185 genes were identified in an RNA interference screen for decreased acetylcholine secretion; 132 of these genes had not previously been implicated in synaptic transmission. Functional profiles for these genes were determined by comparing secretion defects observed after RNA interference under a variety of conditions. Hierarchical clustering identified groups of functionally related genes, including those involved in the synaptic vesicle cycle, neuropeptide signalling and responsiveness to phorbol esters. Twenty-four genes encoded proteins that were localized to presynaptic specializations. Loss-of-function mutations in 12 genes caused defects in presynaptic structure.
Regulated delivery and removal of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) glutamate receptors (GluRs) from postsynaptic elements has been proposed as a mechanism for regulating synaptic strength. Here we test the role of ubiquitin in regulating synapses that contain a C. elegans GluR, GLR-1. GLR-1 receptors were ubiquitinated in vivo. Mutations that decreased ubiquitination of GLR-1 increased the abundance of GLR-1 at synapses and altered locomotion behavior in a manner that is consistent with increased synaptic strength. By contrast, overexpression of ubiquitin decreased the abundance of GLR-1 at synapses and decreased the density of GLR-1-containing synapses, and these effects were prevented by mutations in the unc-11 gene, which encodes a clathrin adaptin protein (AP180). These results suggest that ubiquitination of GLR-1 receptors regulates synaptic strength and the formation or stability of GLR-1-containing synapses.
The secretion of neurotransmitters and neuropeptides is mediated by distinct organelles-synaptic vesicles (SVs) and dense-core vesicles (DCVs), respectively. Relatively little is known about the factors that differentially regulate SV and DCV secretion. Here we show that protein kinase C-1 (PKC-1), which is most similar to the vertebrate PKC eta and epsilon isoforms, regulates exocytosis of DCVs in Caenorhabditis elegans motor neurons. Mutants lacking PCK-1 activity had delayed paralysis induced by the acetylcholinesterase inhibitor aldicarb, whereas mutants with increased PKC-1 activity had more rapid aldicarb-induced paralysis. Imaging and electrophysiological assays indicated that SV release occurred normally in pkc-1 mutants. By contrast, genetic analysis of aldicarb responses and imaging of fluorescently tagged neuropeptides indicated that mutants lacking PKC-1 had reduced neuropeptide secretion. Similar neuropeptide secretion defects were found in mutants lacking unc-31 (encoding the protein CAPS) or unc-13 (encoding Munc13). These results suggest that PKC-1 selectively regulates DCV release from neurons.
LIN-10 Is a Shared Component of the Polarized Protein Localization Pathways in Neurons and Epithelia
We tested the model that neurons and epithelial cells use a shared mechanism for polarized protein sorting by comparing the pathways for localizing basolateral and postsynaptic proteins in C. elegans. GLR-1 glutamate receptors are localized to postsynaptic elements of central synapses and, when ectopically expressed, to basolateral membranes of epithelial cells. Proper localization of GLR-1 in both neurons and epithelia requires the PDZ protein LIN-10, defining LIN-10 as a shared component of the basolateral and postsynaptic localization pathways. Changing the GLR-1 carboxy-terminal sequence from a group I PDZ-binding consensus (-TAV) to a group II consensus (-FYV) restores GLR-1 synaptic localization in lin-10 mutants. Thus, these interneurons utilize at least two separate postsynaptic localization pathways.
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