Your search keyword '"Hall, David H."' showing total 17 results

1. PGP-14 establishes a polar lipid permeability barrier within the C. elegans pharyngeal cuticle.

Author

Kamal, Muntasir, Tokmakjian, Levon, Knox, Jessica, Han, Duhyun, Moshiri, Houtan, Magomedova, Lilia, Nguyen, Ken CQ, Zheng, Hong, Burns, Andrew R., Cooke, Brittany, Lacoste, Jessica, Yeo, May, Hall, David H., Cummins, Carolyn L., and Roy, Peter J.

Subjects

CAENORHABDITIS elegans, CUTICLE, SMALL molecules, STAINS & staining (Microscopy), LIPIDS, P-glycoprotein

Abstract

The cuticles of ecdysozoan animals are barriers to material loss and xenobiotic insult. Key to this barrier is lipid content, the establishment of which is poorly understood. Here, we show that the p-glycoprotein PGP-14 functions coincidentally with the sphingomyelin synthase SMS-5 to establish a polar lipid barrier within the pharyngeal cuticle of the nematode C. elegans. We show that PGP-14 and SMS-5 are coincidentally expressed in the epithelium that surrounds the anterior pharyngeal cuticle where PGP-14 localizes to the apical membrane. pgp-14 and sms-5 also peak in expression at the time of new cuticle synthesis. Loss of PGP-14 and SMS-5 dramatically reduces pharyngeal cuticle staining by Nile Red, a key marker of polar lipids, and coincidentally alters the nematode's response to a wide-range of xenobiotics. We infer that PGP-14 exports polar lipids into the developing pharyngeal cuticle in an SMS-5-dependent manner to safeguard the nematode from environmental insult. Author summary: An infinite number of small molecules have the potential to threaten life. Not surprisingly then, animals have evolved multiple mechanisms to defend against such threats. One defense mechanism employed by many animals is the creation of an outer protective layer called the cuticle. Lipids within the cuticle act as a barrier to retard small molecule passage into the underlying tissues. Water-loving small molecules cannot traverse a lipid barrier and fat-loving molecules can get trapped within the barrier. How this lipid barrier is established is incompletely understood. Here, we describe our discovery of a conserved protein called PGP-14 that is expressed in the tissue that makes the cuticle that protects the mouth and pharynx of the nematode worm C. elegans. We show that PGP-14 peaks in expression at the end of new cuticle synthesis and is necessary for lipid deposition within it. Without PGP-14, many small molecules adversely accumulate within the animal and consequently kill it. Hence, PGP-14 is a key component employed by the animal to help protect it from small molecule threats. [ABSTRACT FROM AUTHOR]

Published

2023

2. A transient apical extracellular matrix relays cytoskeletal patterns to shape permanent acellular ridges on the surface of adult C. elegans.

Author

Katz, Sophie S., Barker, Trevor J., Maul-Newby, Hannah M., Sparacio, Alessandro P., Nguyen, Ken C. Q., Maybrun, Chloe L., Belfi, Alexandra, Cohen, Jennifer D., Hall, David H., Sundaram, Meera V., and Frand, Alison R.

Subjects

CAENORHABDITIS elegans, EXTRACELLULAR matrix, PERMANENTS (Matrices), EXTRACELLULAR matrix proteins, CYTOSKELETON

Abstract

Epithelial cells secrete apical extracellular matrices to form protruding structures such as denticles, ridges, scales, or teeth. The mechanisms that shape these structures remain poorly understood. Here, we show how the actin cytoskeleton and a provisional matrix work together to sculpt acellular longitudinal alae ridges in the cuticle of adult C. elegans. Transient assembly of longitudinal actomyosin filaments in the underlying lateral epidermis accompanies deposition of the provisional matrix at the earliest stages of alae formation. Actin is required to pattern the provisional matrix into longitudinal bands that are initially offset from the pattern of longitudinal actin filaments. These bands appear ultrastructurally as alternating regions of adhesion and separation within laminated provisional matrix layers. The provisional matrix is required to establish these demarcated zones of adhesion and separation, which ultimately give rise to alae ridges and their intervening valleys, respectively. Provisional matrix proteins shape the alae ridges and valleys but are not present within the final structure. We propose a morphogenetic mechanism wherein cortical actin patterns are relayed to the laminated provisional matrix to set up distinct zones of matrix layer separation and accretion that shape a permanent and acellular matrix structure. Author summary: Animal surfaces are often decorated with intricately shaped structures such as denticles, ridges, or scales that are composed of extracellular matrix materials. We don't understand how those extracellular materials get sculpted into appropriate shapes, but most models propose that cellular protrusions initiate the process. Here we investigated the formation of nematode adult alae, which are three racing stripe-like cuticle ridges that run along the left and right sides of the body. We found that alae development requires the actin cytoskeleton and a set of temporary matrix components, both of which organize into longitudinal stripes that presage the final structure. Using electron microscopy, we saw no evidence for cell membrane protrusion or folding that would explain a ridged matrix pattern. Instead, we observed that the first sign of alae formation is the appearance of four small separations between different layers of the temporary matrix. We propose that cytoskeletal patterns are relayed to the to the temporary matrix to trigger delamination and subsequent zonal differences in matrix accumulation that establish the alternating valley and ridge pattern of the alae. [ABSTRACT FROM AUTHOR]

Published

2022

3. Kinesin-3 mediated axonal delivery of presynaptic neurexin stabilizes dendritic spines and postsynaptic components.

Author

Oliver, Devyn, Ramachandran, Shankar, Philbrook, Alison, Lambert, Christopher M., Nguyen, Ken C. Q., Hall, David H., and Francis, Michael

Subjects

DENDRITIC spines, CELL adhesion molecules, NEURAL circuitry, MOTOR neurons, GABAERGIC neurons, NERVOUS system, CELL adhesion

Abstract

The functional properties of neural circuits are defined by the patterns of synaptic connections between their partnering neurons, but the mechanisms that stabilize circuit connectivity are poorly understood. We systemically examined this question at synapses onto newly characterized dendritic spines of C. elegans GABAergic motor neurons. We show that the presynaptic adhesion protein neurexin/NRX-1 is required for stabilization of postsynaptic structure. We find that early postsynaptic developmental events proceed without a strict requirement for synaptic activity and are not disrupted by deletion of neurexin/nrx-1. However, in the absence of presynaptic NRX-1, dendritic spines and receptor clusters become destabilized and collapse prior to adulthood. We demonstrate that NRX-1 delivery to presynaptic terminals is dependent on kinesin-3/UNC-104 and show that ongoing UNC-104 function is required for postsynaptic maintenance in mature animals. By defining the dynamics and temporal order of synapse formation and maintenance events in vivo, we describe a mechanism for stabilizing mature circuit connectivity through neurexin-based adhesion. Author summary: The nervous system is composed of networks of interconnecting cells called neurons. Within these networks, individual neurons establish connections or synapses with partnering neurons. Key connections within these networks must be stabilized and preserved throughout the lifetime of an animal in order for the nervous system to function properly. Alterations in synapse connectivity and stability are linked with numerous neurodevelopmental and neurodegenerative diseases. Therefore, it is crucial to gain a complete understanding of the steps in assembly of a developing synapse, and of the mechanisms involved in synapse maturation and maintenance. Using microscopy and live imaging approaches at newly characterized spiny synapses in a genetic model organism, the nematode Caenorhabdtis elegans, we describe the sequence of events by which developing synapses are constructed. In addition, we show that the cell adhesion molecule, neurexin, is required for stabilization of these synapses into adulthood. In the absence of neurexin, neuronal connections begin to form but then disappear. A specific motor protein, called kinesin-3, is required to deliver neurexin to synapses in order to stabilize specific connections between neurons. An improved understanding of the sequence of events in synapse formation and how neurexin is delivered to developing synapses for stabilizing connections may help to advance our understanding of disorders and diseases that arise from disruptions of these processes. [ABSTRACT FROM AUTHOR]

Published

2022

4. Glial loss of the metallo β-lactamase domain containing protein, SWIP-10, induces age- and glutamate-signaling dependent, dopamine neuron degeneration.

Author

Gibson, Chelsea L., Balbona, Joseph T., Niedzwiecki, Ashlin, Rodriguez, Peter, Nguyen, Ken C. Q., Hall, David H., and Blakely, Randy D.

Subjects

BETA lactamases, GLUTAMIC acid, DOPAMINERGIC neurons, NEURODEGENERATION, CELL death

Abstract

Across phylogeny, glutamate (Glu) signaling plays a critical role in regulating neural excitability, thus supporting many complex behaviors. Perturbed synaptic and extrasynaptic Glu homeostasis in the human brain has been implicated in multiple neuropsychiatric and neurodegenerative disorders including Parkinson’s disease, where theories suggest that excitotoxic insults may accelerate a naturally occurring process of dopamine (DA) neuron degeneration. In C. elegans, mutation of the glial expressed gene, swip-10, results in Glu-dependent DA neuron hyperexcitation that leads to elevated DA release, triggering DA signaling-dependent motor paralysis. Here, we demonstrate that swip-10 mutations induce premature and progressive DA neuron degeneration, with light and electron microscopy studies demonstrating the presence of dystrophic dendritic processes, as well as shrunken and/or missing cell soma. As with paralysis, DA neuron degeneration in swip-10 mutants is rescued by glial-specific, but not DA neuron-specific expression of wildtype swip-10, consistent with a cell non-autonomous mechanism. Genetic studies implicate the vesicular Glu transporter VGLU-3 and the cystine/Glu exchanger homolog AAT-1 as potential sources of Glu signaling supporting DA neuron degeneration. Degeneration can be significantly suppressed by mutations in the Ca2+ permeable Glu receptors, nmr-2 and glr-1, in genes that support intracellular Ca2+ signaling and Ca2+-dependent proteolysis, as well as genes involved in apoptotic cell death. Our studies suggest that Glu stimulation of nematode DA neurons in early larval stages, without the protective actions of SWIP-10, contributes to insults that ultimately drive DA neuron degeneration. The swip-10 model may provide an efficient platform for the identification of molecular mechanisms that enhance risk for Parkinson’s disease and/or the identification of agents that can limit neurodegenerative disease progression. [ABSTRACT FROM AUTHOR]

Published

2018

5. Shigella flexneri infection in Caenorhabditis elegans: cytopathological examination and identification of host responses

Author

George, Divya T., Behm, Carolyn A., Hall, David H., Mathesius, Ulrike, Rug, Melanie, Nguyen, Ken C. Q., Verma, Naresh K., George, Divya T., Behm, Carolyn A., Hall, David H., Mathesius, Ulrike, Rug, Melanie, Nguyen, Ken C. Q., and Verma, Naresh K.

Abstract

The Gram-negative bacterium Shigella flexneri is the causative agent of shigellosis, a diarrhoeal disease also known as bacillary dysentery. S. flexneri infects the colonic and rectal epithelia of its primate host and induces a cascade of inflammatory responses that culminates in the destruction of the host intestinal lining. Molecular characterization of host-pathogen interactions in this infection has been challenging due to the host specificity of S. flexneri strains, as it strictly infects humans and non-human primates. Recent studies have shown that S. flexneri infects the soil dwelling nematode Caenorhabditis elegans, however, the interactions between S. flexneri and C. elegans at the cellular level and the cause of nematode death are unknown. Here we attempt to gain insight into the complex host-pathogen interactions between S. flexneri and C. elegans. Using transmission electron microscopy, we show that live S. flexneri cells accumulate in the nematode intestinal lumen, produce outer membrane vesicles and invade nematode intestinal cells. Using two-dimensional differential in-gel electrophoresis we identified host proteins that are differentially expressed in response to S. flexneri infection. Four of the identified genes, aco-1, cct-2, daf-19 and hsp-60, were knocked down using RNAi and ACO-1, CCT-2 and DAF-19, which were identified as up-regulated in response to S. flexneri infection, were found to be involved in the infection process. aco-1 RNAi worms were more resistant to S. flexneri infection, suggesting S. flexneri-mediated disruption of host iron homeostasis. cct-2 and daf-19 RNAi worms were more susceptible to infection, suggesting that these genes are induced as a protective mechanism by C. elegans. These observations further our understanding of the processes involved in S. flexneri infection of C. elegans, which is immensely beneficial to the routine use of this new in vivo model to study S. flexneri pathogenesis.

Published

2014

6. Integrity of Narrow Epithelial Tubes in the C. elegans Excretory System Requires a Transient Luminal Matrix.

Author

Gill, Hasreet K., Cohen, Jennifer D., Ayala-Figueroa, Jesus, Forman-Rubinsky, Rachel, Poggioli, Corey, Bickard, Kevin, Parry, Jean M., Pu, Pu, Hall, David H., and Sundaram, Meera V.

Subjects

CAENORHABDITIS elegans, EPITHELIAL cells, GLYCOPROTEINS, EXTRACELLULAR matrix, ZONA pellucida

Abstract

Most epithelial cells secrete a glycoprotein-rich apical extracellular matrix that can have diverse but still poorly understood roles in development and physiology. Zona Pellucida (ZP) domain glycoproteins are common constituents of these matrices, and their loss in humans is associated with a number of diseases. Understanding of the functions, organization and regulation of apical matrices has been hampered by difficulties in imaging them both in vivo and ex vivo. We identified the PAN-Apple, mucin and ZP domain glycoprotein LET-653 as an early and transient apical matrix component that shapes developing epithelia in C. elegans. LET-653 has modest effects on shaping of the vulva and epidermis, but is essential to prevent lumen fragmentation in the very narrow, unicellular excretory duct tube. We were able to image the transient LET-653 matrix by both live confocal imaging and transmission electron microscopy. Structure/function and fluorescence recovery after photobleaching studies revealed that LET-653 exists in two separate luminal matrix pools, a loose fibrillar matrix in the central core of the lumen, to which it binds dynamically via its PAN domains, and an apical-membrane-associated matrix, to which it binds stably via its ZP domain. The PAN domains are both necessary and sufficient to confer a cyclic pattern of duct lumen localization that precedes each molt, while the ZP domain is required for lumen integrity. Ectopic expression of full-length LET-653, but not the PAN domains alone, could expand lumen diameter in the developing gut tube, where LET-653 is not normally expressed. Together, these data support a model in which the PAN domains regulate the ability of the LET-653 ZP domain to interact with other factors at the apical membrane, and this ZP domain interaction promotes expansion and maintenance of lumen diameter. These data identify a transient apical matrix component present prior to cuticle secretion in C. elegans, demonstrate critical roles for this matrix component in supporting lumen integrity within narrow bore tubes such as those found in the mammalian microvasculature, and reveal functional importance of the evolutionarily conserved ZP domain in this tube protecting activity. [ABSTRACT FROM AUTHOR]

Published

2016

7. FLCN and AMPK Confer Resistance to Hyperosmotic Stress via Remodeling of Glycogen Stores.

Author

Possik, Elite, Ajisebutu, Andrew, Manteghi, Sanaz, Gingras, Marie-Claude, Vijayaraghavan, Tarika, Flamand, Mathieu, Coull, Barry, Schmeisser, Kathrin, Duchaine, Thomas, van Steensel, Maurice, Hall, David H., and Pause, Arnim

Subjects

ORGANISMS, CAENORHABDITIS elegans, GLYCOGEN, OSMOLAR concentration, DEHYDROGENASES

Abstract

Mechanisms of adaptation to environmental changes in osmolarity are fundamental for cellular and organismal survival. Here we identify a novel osmotic stress resistance pathway in Caenorhabditis elegans (C. elegans), which is dependent on the metabolic master regulator 5’-AMP-activated protein kinase (AMPK) and its negative regulator Folliculin (FLCN). FLCN-1 is the nematode ortholog of the tumor suppressor FLCN, responsible for the Birt-Hogg-Dubé (BHD) tumor syndrome. We show that flcn-1 mutants exhibit increased resistance to hyperosmotic stress via constitutive AMPK-dependent accumulation of glycogen reserves. Upon hyperosmotic stress exposure, glycogen stores are rapidly degraded, leading to a significant accumulation of the organic osmolyte glycerol through transcriptional upregulation of glycerol-3-phosphate dehydrogenase enzymes (gpdh-1 and gpdh-2). Importantly, the hyperosmotic stress resistance in flcn-1 mutant and wild-type animals is strongly suppressed by loss of AMPK, glycogen synthase, glycogen phosphorylase, or simultaneous loss of gpdh-1 and gpdh-2 enzymes. Our studies show for the first time that animals normally exhibit AMPK-dependent glycogen stores, which can be utilized for rapid adaptation to either energy stress or hyperosmotic stress. Importantly, we show that glycogen accumulates in kidneys from mice lacking FLCN and in renal tumors from a BHD patient. Our findings suggest a dual role for glycogen, acting as a reservoir for energy supply and osmolyte production, and both processes might be supporting tumorigenesis. [ABSTRACT FROM AUTHOR]

Published

2015

8. The nphp-2 and arl-13 Genetic Modules Interact to Regulate Ciliogenesis and Ciliary Microtubule Patterning in C. elegans.

Author

Warburton-Pitt, Simon R. F., Silva, Malan, Nguyen, Ken C. Q., Hall, David H., and Barr, Maureen M.

Subjects

GENETIC research, CILIARY body, MICROTUBULES, CAENORHABDITIS elegans, PLASMID genetics

Abstract

Cilia are microtubule-based cellular organelles that mediate signal transduction. Cilia are organized into several structurally and functionally distinct compartments: the basal body, the transition zone (TZ), and the cilia shaft. In vertebrates, the cystoprotein Inversin localizes to a portion of the cilia shaft adjacent to the TZ, a region termed the “Inversin compartment” (InvC). The mechanisms that establish and maintain the InvC are unknown. In the roundworm C. elegans, the cilia shafts of amphid channel and phasmid sensory cilia are subdivided into two regions defined by different microtubule ultrastructure: a proximal doublet-based region adjacent to the TZ, and a distal singlet-based region. It has been suggested that C. elegans cilia also possess an InvC, similarly to mammalian primary cilia. Here we explored the biogenesis, structure, and composition of the C. elegans ciliary doublet region and InvC. We show that the InvC is conserved and distinct from the doublet region. nphp-2 (the C. elegans Inversin homolog) and the doublet region genes arl-13, klp-11, and unc-119 are redundantly required for ciliogenesis. InvC and doublet region genes can be sorted into two modules—nphp-2+klp-11 and arl-13+unc-119—which are both antagonized by the hdac-6 deacetylase. The genes of this network modulate the sizes of the NPHP-2 InvC and ARL-13 doublet region. Glutamylation, a tubulin post-translational modification, is not required for ciliary targeting of InvC and doublet region components; rather, glutamylation is modulated by nphp-2, arl-13, and unc-119. The ciliary targeting and restricted localization of NPHP-2, ARL-13, and UNC-119 does not require TZ-, doublet region, and InvC-associated genes. NPHP-2 does require its calcium binding EF hand domain for targeting to the InvC. We conclude that the C. elegans InvC is distinct from the doublet region, and that components in these two regions interact to regulate ciliogenesis via cilia placement, ciliary microtubule ultrastructure, and protein localization. [ABSTRACT FROM AUTHOR]

Published

2014

9. Folliculin Regulates Ampk-Dependent Autophagy and Metabolic Stress Survival.

Author

Possik, Elite, Jalali, Zahra, Nouët, Yann, Yan, Ming, Gingras, Marie-Claude, Schmeisser, Kathrin, Panaite, Lorena, Dupuy, Fanny, Kharitidi, Dmitri, Chotard, Laëtitia, Jones, Russell G., Hall, David H., and Pause, Arnim

Subjects

MEDICAL genetics, TUMOR suppressor genes, BIRT-Hogg-Dube syndrome, AUTOPHAGY, APOPTOSIS, CELLULAR bioenergetics

Abstract

Dysregulation of AMPK signaling has been implicated in many human diseases, which emphasizes the importance of characterizing AMPK regulators. The tumor suppressor FLCN, responsible for the Birt-Hogg Dubé renal neoplasia syndrome (BHD), is an AMPK-binding partner but the genetic and functional links between FLCN and AMPK have not been established. Strikingly, the majority of naturally occurring FLCN mutations predisposing to BHD are predicted to produce truncated proteins unable to bind AMPK, pointing to the critical role of this interaction in the tumor suppression mechanism. Here, we demonstrate that FLCN is an evolutionarily conserved negative regulator of AMPK. Using Caenorhabditis elegans and mammalian cells, we show that loss of FLCN results in constitutive activation of AMPK which induces autophagy, inhibits apoptosis, improves cellular bioenergetics, and confers resistance to energy-depleting stresses including oxidative stress, heat, anoxia, and serum deprivation. We further show that AMPK activation conferred by FLCN loss is independent of the cellular energy state suggesting that FLCN controls the AMPK energy sensing ability. Together, our data suggest that FLCN is an evolutionarily conserved regulator of AMPK signaling that may act as a tumor suppressor by negatively regulating AMPK function. [ABSTRACT FROM AUTHOR]

Published

2014

10. Correction: Kinesin-3 mediated axonal delivery of presynaptic neurexin stabilizes dendritic spines and postsynaptic components.

Author

Oliver, Devyn, Ramachandran, Shankar, Philbrook, Alison, Lambert, Christopher M., Nguyen, Ken C. Q., Hall, David H., and Francis, Michael M.

Subjects

DENDRITIC spines, GRANTS (Money)

Abstract

In the Funding section, the grant number from the funder NIH to author DHH is listed incorrectly. Reference 1 Oliver D, Ramachandran S, Philbrook A, Lambert CM, Nguyen KCQ, Hall DH, et al. (2022) Kinesin-3 mediated axonal delivery of presynaptic neurexin stabilizes dendritic spines and postsynaptic components. [Extracted from the article]

Published

2022

11. Neuronal Target Identification Requires AHA-1-Mediated Fine-Tuning of Wnt Signaling in C. elegans.

Author

Zhang, Jingyan, Li, Xia, Jevince, Angela R., Guan, Liying, Wang, Jiaming, Hall, David H., Huang, Xun, and Ding, Mei

Subjects

GAP junctions (Cell biology), WNT genes, CAENORHABDITIS elegans, TRANSCRIPTION factors, TYROSINE, PROTEIN-tyrosine kinases

Abstract

Electrical synaptic transmission through gap junctions is a vital mode of intercellular communication in the nervous system. The mechanism by which reciprocal target cells find each other during the formation of gap junctions, however, is poorly understood. Here we show that gap junctions are formed between BDU interneurons and PLM mechanoreceptors in C. elegans and the connectivity of BDU with PLM is influenced by Wnt signaling. We further identified two PAS-bHLH family transcription factors, AHA-1 and AHR-1, which function cell-autonomously within BDU and PLM to facilitate the target identification process. aha-1 and ahr-1 act genetically upstream of cam-1. CAM-1, a membrane-bound receptor tyrosine kinase, is present on both BDU and PLM cells and likely serves as a Wnt antagonist. By binding to a cis-regulatory element in the cam-1 promoter, AHA-1 enhances cam-1 transcription. Our study reveals a Wnt-dependent fine-tuning mechanism that is crucial for mutual target cell identification during the formation of gap junction connections. [ABSTRACT FROM AUTHOR]

Published

2013

12. Computer Assisted Assembly of Connectomes from Electron Micrographs: Application to Caenorhabditis elegans.

Author

Meng Xu, Jarrell, Travis A., Yi Wang, Cook, Steven J., Hall, David H., and Emmons, Scott W.

Subjects

CAENORHABDITIS elegans, MICROGRAPHICS, ELECTRON microscopes, NERVOUS system, NEUROPILINS, NEMATODES

Abstract

A rate-limiting step in determining a connectome, the set of all synaptic connections in a nervous system, is extraction of the relevant information from serial electron micrographs. Here we introduce a software application, Elegance, that speeds acquisition of the minimal dataset necessary, allowing the discovery of new connectomes. We have used Elegance to obtain new connectivity data in the nematode worm Caenorhabditis elegans. We analyze the accuracy that can be obtained, which is limited by unresolvable ambiguities at some locations in electron microscopic images. Elegance is useful for reconstructing connectivity in any region of neuropil of sufficiently small size. [ABSTRACT FROM AUTHOR]

Published

2013

13. Structural Properties of the Caenorhabditis elegans Neuronal Network.

Author

Varshney, Lav R., Chen, Beth L., Paniagua, Eric, Hall, David H., and Chklovskii, Dmitri B.

Subjects

CAENORHABDITIS elegans, NEURAL transmission, NEURONS, CEREBRAL cortex, INTERSEXUALITY in animals

Abstract

Despite recent interest in reconstructing neuronal networks, complete wiring diagrams on the level of individual synapses remain scarce and the insights into function they can provide remain unclear. Even for Caenorhabditis elegans, whose neuronal network is relatively small and stereotypical from animal to animal, published wiring diagrams are neither accurate nor complete and self-consistent. Using materials from White et al. and new electron micrographs we assemble whole, selfconsistent gap junction and chemical synapse networks of hermaphrodite C. elegans. We propose a method to visualize the wiring diagram, which reflects network signal flow. We calculate statistical and topological properties of the network, such as degree distributions, synaptic multiplicities, and small-world properties, that help in understanding network signal propagation. We identify neurons that may play central roles in information processing, and network motifs that could serve as functional modules of the network. We explore propagation of neuronal activity in response to sensory or artificial stimulation using linear systems theory and find several activity patterns that could serve as substrates of previously described behaviors. Finally, we analyze the interaction between the gap junction and the chemical synapse networks. Since several statistical properties of the C. elegans network, such as multiplicity and motif distributions are similar to those found in mammalian neocortex, they likely point to general principles of neuronal networks. The wiring diagram reported here can help in understanding the mechanistic basis of behavior by generating predictions about future experiments involving genetic perturbations, laser ablations, or monitoring propagation of neuronal activity in response to stimulation. [ABSTRACT FROM AUTHOR]

Published

2011

14. A Homolog of FHM2 Is Involved in Modulation of Excitatory Neurotransmission by Serotonin in C. elegans.

Author

Govorunova, Elena G., Moussaif, Mustapha, Kullyev, Andrey, Nguyen, Ken C. Q., McDonald, Thomas V., Hall, David H., and Sze, Ji Y.

Subjects

NEURAL transmission, SEROTONIN, CAENORHABDITIS elegans, MIGRAINE, NEUROLOGICAL disorders, ALDICARB, ACETYLCHOLINESTERASE, GENETIC mutation, GENE expression

Abstract

The C. elegans eat-6 gene encodes a Na+, K+-ATPase a subunit and is a homolog of the familial hemiplegic migraine candidate gene FHM2. Migraine is the most common neurological disorder linked to serotonergic dysfunction. We sought to study the pathophysiological mechanisms of migraine and their relation to serotonin (5-HT) signaling using C. elegans as a genetic model. In C. elegans, exogenous 5-HT inhibits paralysis induced by the acetylcholinesterase inhibitor aldicarb. We found that the eat-6(ad467) mutation or RNAi of eat-6 increases aldicarb sensitivity and causes complete resistance to 5-HT treatment, indicating that EAT-6 is a component of the pathway that couples 5-HT signaling and ACh neurotransmission. While a postsynaptic role of EAT-6 at the bodywall NMJs has been well established, we found that EAT-6 may in addition regulate presynaptic ACh neurotransmission. We show that eat-6 is expressed in ventral cord ACh motor neurons, and that cell-specific RNAi of eat-6 in the ACh neurons leads to hypersensitivity to aldicarb. Electron microscopy showed an increased number of synaptic vesicles in the ACh neurons in the eat-6(ad467) mutant. Genetic analyses suggest that EAT-6 interacts with EGL-30 Gaq, EGL-8 phospholipase C and SLO-1 BK channel signaling to modulate ACh neurotransmission and that either reduced or excessive EAT-6 function may lead to increased ACh neurotransmission. Study of the interaction between eat-6 and 5-HT receptors revealed both stimulatory and inhibitory 5-HT inputs to the NMJs. We show that the inhibitory and stimulatory 5-HT signals arise from distinct 5-HT neurons. The role of eat-6 in modulation of excitatory neurotransmission by 5-HT may provide a genetic explanation for the therapeutic effects of the drugs targeting 5-HT receptors in the treatment of migraine patients. [ABSTRACT FROM AUTHOR]

Published

2010

15. An ALS-Linked Mutant SOD1 Produces a Locomotor Defect Associated with Aggregation and Synaptic Dysfunction When Expressed in Neurons of Caenorhabditis elegans.

Author

Jiou Wang, Farr, George W., Hall, David H., Fei Li, Furtak, Krystyna, Dreier, Lars, and Horwich, Arthur L.

Subjects

NEUROTOXICOLOGY, NEURODEGENERATION, DEGENERATION (Pathology), NEURONS, TRANSGENIC animals

Abstract

The nature of toxic effects exerted on neurons by misfolded proteins, occurring in a number of neurodegenerative diseases, is poorly understood. One approach to this problem is to measure effects when such proteins are expressed in heterologous neurons. We report on effects of an ALS-associated, misfolding-prone mutant human SOD1, G85R, when expressed in the neurons of Caenorhabditis elegans. Stable mutant transgenic animals, but not wild-type human SOD1 transgenics, exhibited a strong locomotor defect associated with the presence, specifically in mutant animals, of both soluble oligomers and insoluble aggregates of G85R protein. A whole-genome RNAi screen identified chaperones and other components whose deficiency increased aggregation and further diminished locomotion. The nature of the locomotor defect was investigated. Mutant animals were resistant to paralysis by the cholinesterase inhibitor aldicarb, while exhibiting normal sensitivity to the cholinergic agonist levamisole and normal muscle morphology. When fluorescently labeled presynaptic components were examined in the dorsal nerve cord, decreased numbers of puncta corresponding to neuromuscular junctions were observed in mutant animals and brightness was also diminished. At the EM level, mutant animals exhibited a reduced number of synaptic vesicles. Neurotoxicity in this system thus appears to be mediated by misfolded SOD1 and is exerted on synaptic vesicle biogenesis and/or trafficking. [ABSTRACT FROM AUTHOR]

Published

2009

16. Six Innexins Contribute to Electrical Coupling of C. elegans Body-Wall Muscle.

Author

Liu, Ping, Chen, Bojun, Altun, Zeynep F., Gross, Maegan J., Shan, Alan, Schuman, Benjamin, Hall, David H., and Wang, Zhao-Wen

Subjects

MUSCLE cells, CAENORHABDITIS elegans, GAP junctions (Cell biology), CELL populations, EPITOPES, CELL physiology

Abstract

C. elegans body-wall muscle cells are electrically coupled through gap junctions. Previous studies suggest that UNC-9 is an important, but not the only, innexin mediating the electrical coupling. Here we analyzed junctional current (Ij) for mutants of additional innexins to identify the remaining innexin(s) important to the coupling. The results suggest that a total of six innexins contribute to the coupling, including UNC-9, INX-1, INX-10, INX-11, INX-16, and INX-18. The Ij deficiency in each mutant was rescued completely by expressing the corresponding wild-type innexin specifically in muscle, suggesting that the innexins function cell-autonomously. Comparisons of Ij between various single, double, and triple mutants suggest that the six innexins probably form two distinct populations of gap junctions with one population consisting of UNC-9 and INX-18 and the other consisting of the remaining four innexins. Consistent with their roles in muscle electrical coupling, five of the six innexins showed punctate localization at muscle intercellular junctions when expressed as GFP- or epitope-tagged proteins, and muscle expression was detected for four of them when assessed by expressing GFP under the control of innexin promoters. The results may serve as a solid foundation for further explorations of structural and functional properties of gap junctions in C. elegans body-wall muscle. [ABSTRACT FROM AUTHOR]

Published

2013

17. Neuronal Target Identification Requires AHA-1-Mediated Fine-Tuning of Wnt Signaling in C. elegans.

Author

Zhang, Jingyan, Li, Xia, Jevince, Angela R., Guan, Liying, Wang, Jiaming, Hall, David H., Huang, Xun, and Ding, Mei

Subjects

*GAP junctions (Cell biology), *WNT genes, *CAENORHABDITIS elegans, *TRANSCRIPTION factors, *TYROSINE, *PROTEIN-tyrosine kinases

Abstract

Electrical synaptic transmission through gap junctions is a vital mode of intercellular communication in the nervous system. The mechanism by which reciprocal target cells find each other during the formation of gap junctions, however, is poorly understood. Here we show that gap junctions are formed between BDU interneurons and PLM mechanoreceptors in C. elegans and the connectivity of BDU with PLM is influenced by Wnt signaling. We further identified two PAS-bHLH family transcription factors, AHA-1 and AHR-1, which function cell-autonomously within BDU and PLM to facilitate the target identification process. aha-1 and ahr-1 act genetically upstream of cam-1. CAM-1, a membrane-bound receptor tyrosine kinase, is present on both BDU and PLM cells and likely serves as a Wnt antagonist. By binding to a cis-regulatory element in the cam-1 promoter, AHA-1 enhances cam-1 transcription. Our study reveals a Wnt-dependent fine-tuning mechanism that is crucial for mutual target cell identification during the formation of gap junction connections. [ABSTRACT FROM AUTHOR]

Published

2013