Your search keyword '"Nash, Howard A."' showing total 19 results

1. Visual Mutations Reveal Opposing Effects of Illumination on Arousal in Drosophila.

Author

Yuzhong Cheng and Nash, Howard A.

Subjects

*DROSOPHILA, *FLIES, *GENETIC mutation, *GENETICS, *LIGHT

Abstract

The effect of illumination on alertness can be assessed by comparing the efficacy of an anesthetic under light vs. dark conditions. Results from such tests on wild-type flies and visual mutants demonstrate that, surprisingly, light has both positive and negative influences on arousal. These dual effects may explain aspects of the fly's daily activity and have potential clinical implications. [ABSTRACT FROM AUTHOR]

Published

2008

2. Drosophila TRP channels require a protein with a distinctive motif encoded by the inaF locus.

Author

Yuzhong Cheng and Nash, Howard A.

Subjects

*MEMBRANE proteins, *ION channels, *ACTIVE biological transport, *FRUIT flies, *NEMATODES, *ION-permeable membranes

Abstract

In both vertebrates and invertebrates, ion channels of the TRP superfamily are known to be influenced by a variety of accessory factors, but the list of interacting proteins is acknowledged to be incomplete. Although previous work showed that Drosophila TRP function is disrupted by mutations in the inaF locus, the mechanism of this effect has remained obscure. Here we show that a previously overlooked small protein, INAF-B, is encoded by the locus and fulfills its critical role in retinal physiology. The 81-aa INAF-B gene product is an integral membrane protein that colocalizes to rhabdomeres along with TRP channels. Immunoprecipitation experiments demonstrate that the two proteins participate in a complex. and blotting experiments show that neither protein survives in the absence of the other. Both proteins are normally part of a large supramolecular assembly, the signalplex, but their interaction persists even in the absence of the scaffold for this structure. The inaF locus encodes three other proteins, each of which has diverged from INAF-B except for a 32-aa block of residues that encompasses a transmembrane domain. This conserved sequence defines an inaF motif, representatives of which are found in proteins from organisms as diverse as nematodes, fish, and humans. Given the role of INAF-B, these proteins are good candidates for interacting partners of other members of the TRP superfamily. [ABSTRACT FROM AUTHOR]

Published

2007

3. An Unusual Cation Channel Mediates Photic Control of Locomotion in Drosophila

Author

Nash, Howard A., Scott, Robert L., Lear, Bridget C., and Allada, Ravi

Subjects

*ION channels, *NERVOUS system, *DROSOPHILA

Abstract

A unique family of putative ion channels that are related to voltage-gated sodium and calcium channels has been identified in genomic and cDNA studies of metazoans . Aside from evidence for expression of family members in the nervous system , little is known about the operation of the channel or its functional significance. In the present study, this conserved family''s sole Drosophila member, a gene known both as CG1517 and as Dmα1U , is shown to correspond to the narrow abdomen (na) gene and is the locus of a set of mutations that affect sensitivity to anesthetics . Immunohistochemistry of adult heads reveals that the channel is expressed in the neuropil of the central complex and optic lobe; expression is severely depressed in the mutants. In addition to previously described defects, the mutant phenotype is demonstrated here to include dysfunction in the coupling between light and locomotor behavior. Most dramatically, mutant flies have an inversion of relative locomotor activity in light versus dark. The involvement of the channel in daily rhythms of the fruit fly is especially provocative because the human ortholog lies in a candidate region linked to bipolar disorder , a disease frequently associated with altered diurnal behavior . [Copyright &y& Elsevier]

Published

2002

4. Influence of general anesthetics on a specific neural pathway in Drosophila melanogaster.

Author

Lin, Meiqiu and Nash, Howard A.

Subjects

*VISUAL pathways, *DROSOPHILA, *ANESTHESIA, *NERVOUS system

Abstract

Shows that the neural pathway involved in the visual escape response of Drosophila has the desired combination and thus is an excellent tool for exploring the genetics of the anesthetic response. Definition of the visual escape response (VER); Parameters of three distinct responses to electrical stimulation of the VER; Effect of general anesthetics on VER.

Published

1996

5. INTEGRATION AND EXCISION OF BACTERIOPHAGE λ THE MECHANISM OF CONSERVATIVE SITE SPECIFIC RECOMBINATION.

Author

Nash, Howard A.

Subjects

*BACTERIOPHAGES, *GENETIC recombination, *CHROMOSOMES, *BACTERIAL transformation, *GENETIC transformation, *GENETICS

Abstract

Discusses the mechanism of conservative site-specific recombination in a bacteriophage lambda. Study of the integration/excision cycle of the bacteriophage; Organization of the studies around a model for integration and excision; Developments that elaborate the mechanism of the integration and excision reactions.

Published

1981

6. Topological nuts and bolts.

Author

Nash, Howard A.

Subjects

*DNA topoisomerase I, *SCISSION (Chemistry), *DNA, *CHEMICAL structure

Abstract

Studies the structure and mechanisms of action of topoisomerases. Mechanical changes in topoisomerases; Research in this issue; Structure of human topoisomerase I and its importance; Traits of DNA molecules without free ends; What reversible cleavage is; Resemblance of parts of topoisomerase I with other proteins; Implications of structure for agents that inhibit topoisomerase I.

Published

1998

7. Drug Targets: Turning the Channel (on) for Sedation

Author

Sandstrom, David J. and Nash, Howard

Subjects

*DRUG target, *GENETICS, *ALCOHOL, *ANESTHETICS

Abstract

Genetic techniques have recently implicated two different ion channels as critical molecular targets for the sedative action of ethanol and intravenous anesthetics. In each case, the target is hyperactivated by the drug. [Copyright &y& Elsevier]

Published

2004

8. The mushroom body defect Gene Product Is an Essential Component of the Meiosis II Spindle Apparatus in Drosophila Oocytes.

Author

Yu, James X., Guan, Zhonghui, and Nash, Howard A.

Subjects

*DROSOPHILA, *MEIOSIS, *EMBRYOS, *PROTEINS, *SPINDLE apparatus

Abstract

In addition to their well-known effects on the development of the mushroom body, mud mutants are also female sterile. Here we show that, although the early steps of ovary development are grossly normal, a defect becomes apparent in meiosis II when the two component spindles fail to cohere and align properly. The products of meiosis are consequently mispositioned within the egg and, with or without fertilization, soon undergo asynchronous and spatially disorganized replication. In wild-type eggs, Mud is found associated with the central spindle pole body that lies between the two spindles of meiosis II. The mutant defect thus implies that Mud should be added to the short list of components that are required for the formation and/or stability of this structure. Mud protein is also normally found in association with other structures during egg development: at the spindle poles of meiosis I, at the spindle poles of early cleavage and syncytial embryos, in the rosettes formed from the unfertilized products of meiosis, with the fusomes and spectrosomes that anchor the spindles of dividing cystoblasts, and at the nuclear rim of the developing oocyte. In contrast to its important role at the central spindle pole body, in none of these cases is it clear that Mud plays an essential role. But the commonalities in its location suggest potential roles for the protein in development of other tissues. [ABSTRACT FROM AUTHOR]

Published

2006

9. Retrograde signaling from the brain to the retina modulates the termination of the light response in Drosophila.

Author

Rajaram, Shantadurga, Scott, Robert L., and Nash, Howard A.

Subjects

*RETINA, *BRAIN, *SENSORY neurons, *DROSOPHILA, *GENETIC mutation, *OPTIC lobes

Abstract

A critical factor in visual function is the speed with which photo- receptors (PRs) return to the resting state when light intensity dims. Several elements subserve this process, many of which promote the termination of the phototransduction cascade. Al- though the known elements are intrinsic to PRs, we have found that prompt restoration to the resting state of the Drosophila electroretinogram can require effective communication between the retina and the underlying brain. The requirement is seen more dramatically with long than with short light pulses, distinguishing the phenomenon from gross disruption of the termination machinery. The speed of recovery is affected by mutations (in the Hdc and ort genes) that prevent PRs from transmitting visual information to the brain. It is also affected by manipulation (using either drugs like neostigmine or genetic tools to inactivate neurotransmitter release) of cholinergic signals that arise in the brain. Intracellular recordings support the hypothesis that PRs are the target of this communication. We infer that signaling from the retina to the optic lobe prompts a feedback signal to retinal PRs. Although the mechanism of this retrograde signaling remains to be discerned, the phenomenon establishes a previously unappreciated mode of control of the temporal responsiveness of a primary sensory neuron. [ABSTRACT FROM AUTHOR]

Published

2005

10. An ion channel that influences anesthesia sensitivity: Designing a genetic test for assessing a candidate anesthetic target

Author

Alone, Debasmita P., Scott, Robert L., and Nash, Howard A.

Subjects

*DROSOPHILA, *ANESTHETICS, *GENES, *PHENOTYPES

Abstract

Abstract: Mutations in a gene that encodes an unusual ion channel significantly change the sensitivity of Drosophila to volatile anesthetics (VAs). As for any gene implicated by mutation, we would like to know whether the corresponding gene product is a mediator or modulator of anesthesia. After reviewing what is known about the ion channel gene and the mutant phenotype, we present a theoretical framework for testing the involvement of this (or any) gene product as a direct target of VAs. In essence, we propose that manipulating the copy number of a bona fide target gene should result in alterations of anesthetic sensitivity. A positive feature of this strategy is that it tends to limit compensatory effects. On the other hand, we discuss how false negatives and false positives could obscure the outcome. Nevertheless, the simplicity and clarity of the approach recommends it as a general tool; testing of the ion channel gene is under way. [Copyright &y& Elsevier]

Published

2005

11. The role of TDP1 from budding yeast in the repair of DNA damage

Author

Liu, Chunyan, Pouliot, Jeffrey J., and Nash, Howard A.

Subjects

*DNA repair, *GENES, *PHOSPHODIESTERS, *ORGANOPHOSPHORUS compounds, *CATALYSIS, *ENZYMES, *PROTEIN folding

Abstract

The TDP1 gene encodes a protein that can hydrolyze certain types of 3′-terminal phosphodiesters, but the relevance of these catalytic activities to gene function has not been previously tested. In this work we engineered a point mutation in TDP1 and present evidence that, as per design, it severely diminishes tyrosyl-DNA phosphodiesterase enzyme activity without affecting protein folding. The phenotypes of yeast strains that express this mutant show that the contribution of TDP1 to the repair of two kinds of damaged termini-induced, respectively, by camptothecin (CPT) and by bleomycin—strongly depends on enzyme activity. In routine assays of cell survival and growth the contribution of this activity is often overshadowed by other repair pathways. However, the value of TDP1 in the economy of the cell is highlighted by our discovery of several phenotypes that are evident even without deliberate inactivation of parallel pathways. These non-redundant mutant phenotypes include increased spontaneous mutation rate, transient accumulation of cells in a mid-anaphase checkpoint after exposure to camptothecin and, in cells that overexpress topoisomerase I (Top1), decreased survival of camptothecin-induced damage. The relationship between the role of TDP1 in Saccharomyces and its role in metazoans is discussed. [Copyright &y& Elsevier]

Published

2004

12. Repair of topoisomerase I covalent complexes in the absence of the tyrosyl-DNA phosphodiesterase Tdp1.

Author

Chunyan Liu, Pouliot, Jeffrey J., and Nash, Howard A.

Subjects

*DNA topoisomerase I, *PROTEIN-tyrosine phosphatase

Abstract

Accidental or drug-induced interruption of the breakage and reunion cycle of eukaryotic topoisomerase 1 (Top1) yields complexes in which the active site tyrosine of the enzyme is covalently linked to the 3′ end of broken DNA. The enzyme tyrosyl-DNA phosphodiesterase (Tdp1) hydrolyzes this protein-DNA link and thus functions in the repair of covalent complexes, but genetic studies in yeast show that alternative pathways of repair exist. Here, we have evaluated candidate genes for enzymes that might act in parallel to Tdp1 so as to generate free ends of DNA. Despite finding that the yeast Apn1 protein has a Tdp1-like biochemical activity, genetic inactivation of all known yeast apurinic endonucleases does not increase the sensitivity of a tdp1 mutant to direct induction of Top1 damage. In contrast, assays of growth in the presence of the Top1 poison camptothecin (CPT) indicate that the structure-specific nucleases dependent on RAD1 and MUS81 can contribute independently of TDP1 to repair, presumably by cutting off a segment of DNA along with the topoisomerase. However, cells in which all three enzymes are genetically inactivated are not as sensitive to the lethal effects of CPT as are cells defective in double-strand break repair. We show that the MRE11 gene is even more critical than the RAD52 gene for double-strand break repair of CPT lesions, and comparison of an mre11 mutant with a tdp1 rad1 mus81 triple mutant demonstrates that other enzymes complementary to Tdp1 remain to be discovered. [ABSTRACT FROM AUTHOR]

Published

2002

13. Pathways for repair of topoisomerase I covalent complexes in Saccharomyces cerevisiae.

Author

Pouliot, Jeffrey J., Robertson, Carol A., and Nash, Howard A.

Subjects

*DNA topoisomerase I, *TYROSINE

Abstract

Background The covalent linkage between DNA and the active site tyrosine of topoisomerase I can be stabilized by chemotherapeutic agents, adjacent DNA lesions, or mutational defects in the topoisomerase itself. Following collision with a replication fork, the covalent complex can be converted to a double-strand break. Tdp1, an enzyme that can hydrolyse the bond between topoisomerase I and DNA, is thought to be involved in the repair of these lesions, but little is known about how such repair is accomplished. Results Reaction kinetics with model substrates reveal that the catalytic efficiency of Saccharomyces cerevisiae Tdp1 is relatively poor when the scissile bond is located in the middle of a duplex, but much better when it is located at the end of a structure. Survival of yeast after induction of a toxic topoisomerase is substantially reduced by inactivation of the TDP1 gene. Comparison of survival of single and double mutants places TDP1 and RAD52 in the same epistasis group but TDP1 and RAD9 in different epistasis groups. In the absence of RAD9, inactivation of TDP1 has a significant effect on the survival of cells following exposure to camptothecin but is without consequence for the survival of agents that do not target topoisomerase I. Conclusions Tdp1 acts as a specific repair enzyme for topoisomerase I lesions. Rather than working at their earliest occurrence, the enzyme acts after covalent complexes have been converted to DSBs. A second repair pathway also exists that functions independently of Tdp1 but requires RAD9 function to efficiently repair topoisomerase I-linked DSBs. The efficiency of these pathways differs for complexes induced with the chemotherapeutic agent camptothecin vs. those accumulated by mutant forms of topoisomerase I. [ABSTRACT FROM AUTHOR]

Published

2001

14. Neuroprotection and repair of 3'-blocking DNA ends by glaikit (gkt) encoding Drosophila tyrosyl-DNA phosphodiesterase 1 (TDP1).

Author

Guo, DongYu, Dexheimer, Thomas S., Pommier, Yves, and Nash, Howard A.

Subjects

*PROTEIN-tyrosine kinases, *PHOSPHODIESTERASES, *PHYLOGENY, *DROSOPHILA, *PROTEIN kinases

Abstract

Tyrosyl-DNA phosphodiesterase (TDP1) is a phylogenetically conserved enzyme critical for the removal of blocking lesions at the 3' ends of DNA or RNA. This study analyzes the Drosophila TDP1 gene ortholog glaikit (gkt) and its possible role(s) in the repair of endogenous DNA lesions and neuroprotection. To do so, we studied a homozygous PiggyBac insertion (c03958) that disrupts the 5' UTR of gkt. Protein extracts of c03958 flies were defective in hydrolyzing 3-DNA-tyrosyl residues, demonstrating that gkt is the Drosophila TDP1. Although the mutant is generally healthy and fertile, females exhibit reduced lifespan and diminished climbing ability. This phe-notype was rescued by neuronal expression of TDP1. In addition, when c03958 larvae were exposed to bleomycin, an agent that produces oxidative DNA damage, or topoisomerase l-targeted drugs (camptothecin and a noncamptothecin indenoisoquinoline derivative, LMP-776), survivors displayed rough eye patches, which were rescued by neuronal expression of TDP1. Our study establishes that gkt is the Drosophila TDP1 gene, and that it is critical for neuroprotection, normal longevity, and repair of damaged DNA. [ABSTRACT FROM AUTHOR]

Published

2014

15. UNC79 and UNC80, Putative Auxiliary Subunits of the NARROW ABDOMEN Ion Channel, Are Indispensable for Robust Circadian Locomotor Rhythms in Drosophila.

Author

Lear, Bridget C., Darrah, Eric J., Aldrich, Benjamin T., Gebre, Senetibeb, Scott, Robert L., Nash, Howard A., and Allada, Ravi

Subjects

*DROSOPHILA melanogaster, *FRUIT flies, *ION channels, *CIRCADIAN rhythms, *NEURAL circuitry, *CARDIAC pacemakers, *GENETIC regulation, *RNA interference

Abstract

In the fruit fly Drosophila melanogaster, a network of circadian pacemaker neurons drives daily rhythms in rest and activity. The ion channel NARROW ABDOMEN (NA), orthologous to the mammalian sodium leak channel NALCN, functions downstream of the molecular circadian clock in pacemaker neurons to promote behavioral rhythmicity. To better understand the function and regulation of the NA channel, we have characterized two putative auxiliary channel subunits in Drosophila, unc79 (aka dunc79) and unc80 (aka CG18437). We have generated novel unc79 and unc80 mutations that represent strong or complete loss-of-function alleles. These mutants display severe defects in circadian locomotor rhythmicity that are indistinguishable from na mutant phenotypes. Tissue-specific RNA interference and rescue analyses indicate that UNC79 and UNC80 likely function within pacemaker neurons, with similar anatomical requirements to NA. We observe an interdependent, post-transcriptional regulatory relationship among the three gene products, as loss of na, unc79, or unc80 gene function leads to decreased expression of all three proteins, with minimal effect on transcript levels. Yet despite this relationship, we find that the requirement for unc79 and unc80 in circadian rhythmicity cannot be bypassed by increasing NA protein expression, nor can these putative auxiliary subunits substitute for each other. These data indicate functional requirements for UNC79 and UNC80 beyond promoting channel subunit expression. Immunoprecipitation experiments also confirm that UNC79 and UNC80 form a complex with NA in the Drosophila brain. Taken together, these data suggest that Drosophila NA, UNC79, and UNC80 function together in circadian clock neurons to promote rhythmic behavior. [ABSTRACT FROM AUTHOR]

Published

2013

16. Drosophila ryanodine receptors mediate general anesthesia by halothane.

Author

Gao, Shuying, Sandstrom, David J, Smith, Harold E, High, Brigit, Marsh, Jon W, and Nash, Howard A

Abstract

Background: Although in vitro studies have identified numerous possible targets, the molecules that mediate the in vivo effects of volatile anesthetics remain largely unknown. The mammalian ryanodine receptor (Ryr) is a known halothane target, and the authors hypothesized that it has a central role in anesthesia.Methods: Gene function of the Drosophila Ryr (dRyr) was manipulated in the whole body or in specific tissues using a collection of mutants and transgenes, and responses to halothane were measured with a reactive climbing assay. Cellular responses to halothane were studied using Ca imaging and patch clamp electrophysiology.Results: Halothane potency strongly correlates with dRyr gene copy number, and missense mutations in regions known to be functionally important in the mammalian Ryrs gene cause dominant hypersensitivity. Tissue-specific manipulation of dRyr shows that expression in neurons and glia, but not muscle, mediates halothane sensitivity. In cultured cells, halothane-induced Ca efflux is strictly dRyr-dependent, suggesting a close interaction between halothane and dRyr. Ca imaging and electrophysiology of Drosophila central neurons reveal halothane-induced Ca flux that is altered in dRyr mutants and correlates with strong hyperpolarization.Conclusions: In Drosophila, neurally expressed dRyr mediates a substantial proportion of the anesthetic effects of halothane in vivo, is potently activated by halothane in vitro, and activates an inhibitory conductance. The authors' results provide support for Ryr as an important mediator of immobilization by volatile anesthetics. [ABSTRACT FROM AUTHOR]

Published

2013

17. Genetic Effects in Drosophila on the Potency of Diverse General Anesthetics: A Distinctive Pattern of Altered Sensitivity.

Author

Campbell, Joseph L., Gu, Qun, Guo, Dongyu, and Nash, Howard A.

Subjects

*DROSOPHILA, *GENETICS, *ANESTHETICS, *COCAINE, *ETHANOL, *GENETIC mutation

Abstract

Mutations that influence the sensitivity of an organism to a volatile general anesthetic can be divided into two classes. In one, sensitivity to all other volatile agents is affected to a similar degree. Although this class may contain mutations of interest for understanding anesthesia, it is also likely to contain mutations that merely alter general health. In the second class, mutations confer non-uniform effects on potency (NEP), i.e., larger effects for some volatile anesthetics than for others. Members of this class are of special interest for studies of arousal and its pharmacological suppression because they not only avoid the pitfall of effects on global health, but also imply the existence of drug targets that are preferentially affected by particular agents. In this work, we provide the first systematic investigation of the relative frequency and diversity of NEP mutations in Drosophila. As a first step, we isolated and characterized a set of P element insertion mutations that confer altered sensitivity of the fruit fly to the clinical anesthetic halothane. Then we tested the members of this collection for their effect on the sensitivity of flies to five other volatile agents. Not only do we find that most of the mutations show non-uniform effects, they also share a characteristic arrangement of altered potencies (halothane > >desflurane ≥≥ enflurane~isoflurane~methoxyflurane > sevoflurane). From this result, although we do not know how direct or indirect are the effects of the mutations, we infer the existence of a biologically relevant target for anesthetic action that has a distinct preference for halothane over other agents. Intriguingly, P element insertions that co-map with several NEP loci have been shown to alter the fly's response to cocaine and ethanol, suggesting that common genetic elements are involved in the response to all three drugs. [ABSTRACT FROM AUTHOR]

Published

2009

18. Impact of Gene Copy Number Variation on Anesthesia in Drosophila melanogaster.

Author

Alone, Debasmita P., Rodriguez, Jason C., Noland, Cameron L., and Nash, Howard A.

Subjects

*ANESTHETICS, *PHARMACODYNAMICS, *ANESTHESIA research, *HALOTHANE, *DROSOPHILA melanogaster genetics, *BIOLOGICAL variation, *GENETICS, *GENES, *HETEROZYGOSITY, *FRUIT flies

Abstract

The article discusses a study which investigates the impact of gene copy number variation on anesthesia in Drosophila melanogaster. The study measured in over 200 congenic Drosophila strains the potency with which halothane depressed the righting reflex of fruit-flies. It was discovered that eight have changed sensitivity to halothane despite the majority of deletion heterozygotes were undetermined from the control. It was concluded that the variation on gene copy number has an impact on anesthetic sensitivity in Drosophila melanogaster.

Published

2009

19. A Putative Cation Channel and Its Novel Regulator: Cross-Species Conservation of Effects on General Anesthesia

Author

Humphrey, John A., Hamming, Kevin S., Thacker, Colin M., Scott, Robert L., Sedensky, Margaret M., Snutch, Terrance P., Morgan, Phil G., and Nash, Howard A.

Subjects

*ANESTHESIA, *FLIES, *HALOTHANE, *ENFLURANE, *PHYSIOLOGY

Abstract

Summary: Volatile anesthetics like halothane and enflurane are of interest to clinicians and neuroscientists because of their ability to preferentially disrupt higher functions that make up the conscious state. All volatiles were once thought to act identically; if so, they should be affected equally by genetic variants. However, mutations in two distinct genes, one in Caenorhabditis and one in Drosophila, have been reported to produce much larger effects on the response to halothane than enflurane . To see whether this anesthesia signature is adventitious or fundamental, we have identified orthologs of each gene and determined the mutant phenotype within each species. The fly gene, narrow abdomen (na), encodes a putative ion channel whose sequence places it in a unique family; the nematode gene, unc-79, is identified here as encoding a large cytosolic protein that lacks obvious motifs. In Caenorhabditis, mutations that inactivate both of the na orthologs produce an Unc-79 phenotype; in Drosophila, mutations that inactivate the unc-79 ortholog produce an na phenotype. In each organism, studies of double mutants place the genes in the same pathway, and biochemical studies show that proteins of the UNC-79 family control NA protein levels by a posttranscriptional mechanism. Thus, the anesthetic signature reflects an evolutionarily conserved role for the na orthologs, implying its intimate involvement in drug action. [Copyright &y& Elsevier]

Published

2007