Featured Publications
Tissue-specific dynamic codon redefinition in Drosophila
Hudson AM, Szabo NL, Loughran G, Wills NM, Atkins JF, Cooley L. Tissue-specific dynamic codon redefinition in Drosophila. Proceedings Of The National Academy Of Sciences Of The United States Of America 2021, 118: e2012793118. PMID: 33500350, PMCID: PMC7865143, DOI: 10.1073/pnas.2012793118.Peer-Reviewed Original ResearchConceptsStop codonTranslational stop codon readthroughReadthrough efficiencyHuman tissue culture cellsStop codon readthroughTissue-specific regulationAdult central nervous system (CNS) tissueTissue culture cellsReadthrough productKelch proteinUbiquitin ligaseSingle geneAdult brainIndividual proteinsCodon readthroughReadthroughViral mRNAsC-terminalMalpighian tubulesCodonNeuronal proteinsCell typesAmino acidsCulture cellsDrosophilaTargeted substrate degradation by Kelch controls the actin cytoskeleton during ring canal expansion
Hudson AM, Mannix KM, Gerdes JA, Kottemann MC, Cooley L. Targeted substrate degradation by Kelch controls the actin cytoskeleton during ring canal expansion. Development 2018, 146: dev169219. PMID: 30559276, PMCID: PMC6340150, DOI: 10.1242/dev.169219.Peer-Reviewed Original ResearchConceptsTandem affinity purificationUbiquitin ligase complexCullin-3 functionShort sequence motifsSpecialized cytoskeletal structuresUbiquitin-proteasome systemF-actin cytoskeletonSpecialized actinLigase complexActin cytoskeletonRing canalsSequence motifsGenetic evidenceCytoskeletal structuresAffinity purificationCytoskeletonSubstrate degradationBiochemical evidenceUnusual mechanismKelchCRL3CullinMass spectrometryOogenesisMutagenesisActin Cytoskeletal Organization in Drosophila Germline Ring Canals Depends on Kelch Function in a Cullin-RING E3 Ligase
Hudson AM, Mannix KM, Cooley L. Actin Cytoskeletal Organization in Drosophila Germline Ring Canals Depends on Kelch Function in a Cullin-RING E3 Ligase. Genetics 2015, 201: 1117-1131. PMID: 26384358, PMCID: PMC4649639, DOI: 10.1534/genetics.115.181289.Peer-Reviewed Original ResearchConceptsKelch functionE3 ligaseCullin-RING E3 ligaseGermline ring canalsActin cytoskeletal organizationDrosophila kelch proteinUbiquitin ligase activityCross-link F-actinUbiquitin E3 ligaseRing canalsKelch proteinProtein substratesCytoskeletal defectsCytoskeletal organizationCytoskeletal remodelingLigase activityCullin 3KelchF-actinCytoskeletonLigaseProteasomeVivoCul3MutagenesisMethods for studying oogenesis
Hudson AM, Cooley L. Methods for studying oogenesis. Methods 2014, 68: 207-217. PMID: 24440745, PMCID: PMC4048766, DOI: 10.1016/j.ymeth.2014.01.005.Peer-Reviewed Original ResearchConceptsGAL4/UAS systemStem cell maintenanceDevelopmental cell biologyCell cycle controlClonal screensDrosophila oogenesisCell polarityWhole-mount tissuesCytoskeletal regulationEgg chambersTransgenic linesCell maintenanceIntercellular transportSomatic cellsTrap linesGamete developmentCell biologyUAS systemExcellent systemCycle controlGene expressionIntercellular communicationCell deathOogenesisCell migrationMononuclear muscle cells in Drosophila ovaries revealed by GFP protein traps
Hudson AM, Petrella LN, Tanaka AJ, Cooley L. Mononuclear muscle cells in Drosophila ovaries revealed by GFP protein traps. Developmental Biology 2007, 314: 329-340. PMID: 18199432, PMCID: PMC2293129, DOI: 10.1016/j.ydbio.2007.11.029.Peer-Reviewed Original ResearchConceptsMuscle specificationEpithelial sheath cellsMyoblast fusionSheath cellsProtein trapSarcomere organizationFLP/FRT systemMononuclear muscle cellsMuscle cellsDrosophila ovaryGonadal mesodermGenetic mosaicsKey genesTrap linesFRT systemGenetic analysisHuman muscle physiologySomatic musclesVisceral musclesSingle nucleusClonal analysisFemale reproductive systemMuscle physiologyEpithelial sheathModel systemDrosophila Kelch functions with Cullin-3 to organize the ring canal actin cytoskeleton
Hudson AM, Cooley L. Drosophila Kelch functions with Cullin-3 to organize the ring canal actin cytoskeleton. Journal Of Cell Biology 2010, 188: 29-37. PMID: 20065088, PMCID: PMC2812842, DOI: 10.1083/jcb.200909017.Peer-Reviewed Original ResearchConceptsDrosophila KelchCullin 3Cullin-RING ubiquitin E3 ligasesGermline ring canalsSubstrate adaptor proteinCullin-RING ligaseDiverse protein familiesF-actin cytoskeletal structureUbiquitin E3 ligasesProtein ubiquitylationActin cytoskeletonE3 ligasesRing canalsAdaptor proteinProtein familySequence motifsCytoskeletal structuresFilamentous actinKelchProteinUbiquitylationLigasesCytoskeletonLigaseRepeatsPhylogenetic, Structural and Functional Relationships between WD- and Kelch-Repeat Proteins
Hudson AM, Cooley L. Phylogenetic, Structural and Functional Relationships between WD- and Kelch-Repeat Proteins. Subcellular Biochemistry 2008, 48: 6-19. PMID: 18925367, DOI: 10.1007/978-0-387-09595-0_2.Peer-Reviewed Original ResearchConceptsΒ-propeller proteinsKelch repeat proteinWidespread protein familyWD-repeat proteinΒ-propeller structureΒ-propeller foldΒ-propeller domainWD repeatsMolecular functionsCommon ancestorProtein familyEvolutionary advantageDiverse familySimilar functionsProteinΒ-sheetKelchStructural motifsRepeat unitsExhibit similaritiesMotifFunctional relationshipFamilySuperfamilyAncestorUNDERSTANDING THE FUNCTION OF ACTIN-BINDING PROTEINS THROUGH GENETIC ANALYSIS OF DROSOPHILA OOGENESIS
Hudson AM, Cooley L. UNDERSTANDING THE FUNCTION OF ACTIN-BINDING PROTEINS THROUGH GENETIC ANALYSIS OF DROSOPHILA OOGENESIS. Annual Review Of Genetics 2002, 36: 455-488. PMID: 12429700, DOI: 10.1146/annurev.genet.36.052802.114101.Peer-Reviewed Original ResearchConceptsActin-binding proteinsActin cytoskeletonGenetic analysisNew actin-binding proteinCell biological approachesGenetic model systemActin binding proteinsRecent genetic analysesDrosophila ovaryDrosophila oogenesisGenetic screenBiological approachesGenetic resultsProteinCytoskeletonOogenesisModel systemUltrastructural characteristicsActinScreenUnderstandingOvariesArp2/3-Dependent Psuedocleavage Furrow Assembly in Syncytial Drosophila Embryos
Stevenson V, Hudson A, Cooley L, Theurkauf WE. Arp2/3-Dependent Psuedocleavage Furrow Assembly in Syncytial Drosophila Embryos. Current Biology 2002, 12: 705-711. PMID: 12007413, DOI: 10.1016/s0960-9822(02)00807-2.Peer-Reviewed Original ResearchConceptsDrosophila embryosPseudocleavage furrowsCell cycleActin capActin reorganizationSomatic cell divisionLocal actin polymerizationSyncytial Drosophila embryosARPC1 subunitArp2/3 complexNuclear positioningEmbryonic divisionsComplex localizeCell divisionActin polymerizationCleavage furrowFurrow formationCap functionSpindle fusionMolecular mechanismsArp2/3EmbryosVivo analysisMutationsAssemblyA subset of dynamic actin rearrangements in Drosophila requires the Arp2/3 complex
Hudson AM, Cooley L. A subset of dynamic actin rearrangements in Drosophila requires the Arp2/3 complex. Journal Of Cell Biology 2002, 156: 677-687. PMID: 11854308, PMCID: PMC2174088, DOI: 10.1083/jcb.200109065.Peer-Reviewed Original ResearchConceptsArp2/3 complexRing canal growthActin-related proteinsParallel actin bundlesNurse cell cytoplasmActin filament nucleationDynamic actin rearrangementsActin cytoskeletonRing canalsActin structuresSlow spontaneous rateActin rearrangementPupal epitheliumPlasma membraneFilament nucleationShaft cellsActin bundlesActin filamentsComplex contributesFunction mutationsCanal growthCell cytoplasmSubunitsMutationsComplexesSCAR is a primary regulator of Arp2/3-dependent morphological events in Drosophila
Zallen JA, Cohen Y, Hudson AM, Cooley L, Wieschaus E, Schejter ED. SCAR is a primary regulator of Arp2/3-dependent morphological events in Drosophila. Journal Of Cell Biology 2002, 156: 689-701. PMID: 11854309, PMCID: PMC2174092, DOI: 10.1083/jcb.200109057.Peer-Reviewed Original ResearchMeSH KeywordsActin-Related Protein 2Actin-Related Protein 3ActinsAmino Acid SequenceAnimalsAxonsBase SequenceBlastodermBrainCytoplasmCytoskeletal ProteinsDNA, ComplementaryDrosophilaDrosophila ProteinsGenes, InsectHumansInsect ProteinsMicrofilament ProteinsMolecular Sequence DataMorphogenesisMutagenesisOogenesisOvumProteinsSequence Homology, Amino AcidWiskott-Aldrich Syndrome ProteinConceptsWiskott-Aldrich syndrome proteinArp2/3 complexAdult eye morphologyScar/WAVECell fate decisionsActin-rich structuresCell biological eventsCortical filamentous actinCell morphologyDrosophila developmentMultiple cell typesNormal cell morphologySCAR homologueFate decisionsSyndrome proteinActin structuresFilamentous actinActin polymerizationCell shapeMorphological eventsCytoplasmic organizationEye morphologyBiological eventsCell typesDevelopmental requirementsP element homing to the Drosophila bithorax complex
Bender W, Hudson A. P element homing to the Drosophila bithorax complex. Development 2000, 127: 3981-3992. PMID: 10952896, DOI: 10.1242/dev.127.18.3981.Peer-Reviewed Original ResearchAnimalsDNA NucleotidyltransferasesDNA Transposable ElementsDNA-Binding ProteinsDrosophila melanogasterDrosophila ProteinsGene Expression RegulationGenes, InsectGenes, ReporterHomeodomain ProteinsImmunohistochemistryMutationPhenotypePhysical Chromosome MappingRecombination, GeneticRNA, MessengerTranscription Factors
2020
HtsRC-Mediated Accumulation of F-Actin Regulates Ring Canal Size During Drosophila melanogaster Oogenesis
Gerdes JA, Mannix KM, Hudson AM, Cooley L. HtsRC-Mediated Accumulation of F-Actin Regulates Ring Canal Size During Drosophila melanogaster Oogenesis. Genetics 2020, 216: 717-734. PMID: 32883702, PMCID: PMC7648574, DOI: 10.1534/genetics.120.303629.Peer-Reviewed Original ResearchConceptsGermline ring canalsRing canalsActin cytoskeletonF-actinDrosophila melanogaster oogenesisSomatic follicle cellsCombination of CRISPRF-actin accumulationF-actin recruitmentFilamentous actin cytoskeletonFemale germlineActin structuresFruit flyHigh fecundityFollicle cellsCytoskeletonGermlineOverexpressionAccumulationDrosophilaOogenesisMutagenesisCRISPRFilaminGenesDrosophila sperm development and intercellular cytoplasm sharing through ring canals do not require an intact fusome
Kaufman RS, Price KL, Mannix KM, Ayers KM, Hudson AM, Cooley L. Drosophila sperm development and intercellular cytoplasm sharing through ring canals do not require an intact fusome. Development 2020, 147: dev190140. PMID: 33033119, PMCID: PMC7687857, DOI: 10.1242/dev.190140.Peer-Reviewed Original ResearchConceptsRing canalsSperm developmentPost-meiotic haploid spermatidsGerm cellsGermline ring canalsAnimal germ cellsQuality control surveillanceLarge cytoplasmic structuresCytoplasmic informationDiploid spermatogoniaHaploid spermatidsSpecialized organellesIncomplete cytokinesisIntercellular movementCell divisionEndogenous proteinsFusomeCytoplasmic structuresIntercellular bridgesMale fertilityIntercellular trafficSpermatogenesisCellsCytokinesisNormal conditions
2014
Somatic insulin signaling regulates a germline starvation response in Drosophila egg chambers
Burn KM, Shimada Y, Ayers K, Vemuganti S, Lu F, Hudson A, Cooley L. Somatic insulin signaling regulates a germline starvation response in Drosophila egg chambers. Developmental Biology 2014, 398: 206-217. PMID: 25481758, PMCID: PMC4340711, DOI: 10.1016/j.ydbio.2014.11.021.Peer-Reviewed Original ResearchConceptsDrosophila insulin-like peptidesEgg chambersStarvation responseBody organizationDrosophila egg chamberMotor protein dyneinNutrient-rich conditionsPoor nutrient availabilityInsulin-like peptidesProcessing bodiesDrosophila femalesGermline cellsP-bodiesNutrient availabilityDynein activityInsulin signalingProgeny survivalInsulin pathwayKinesin activityFollicle cellsMicrotubulesStarvationBovine insulinPotential mechanismsProtective response
2012
Expression of Ixodes scapularis Antifreeze Glycoprotein Enhances Cold Tolerance in Drosophila melanogaster
Neelakanta G, Hudson AM, Sultana H, Cooley L, Fikrig E. Expression of Ixodes scapularis Antifreeze Glycoprotein Enhances Cold Tolerance in Drosophila melanogaster. PLOS ONE 2012, 7: e33447. PMID: 22428051, PMCID: PMC3302814, DOI: 10.1371/journal.pone.0033447.Peer-Reviewed Original ResearchMeSH KeywordsAcclimatizationAnalysis of VarianceAnimalsAnimals, Genetically ModifiedAntifreeze ProteinsApoptosisCold TemperatureDrosophila melanogasterEmbryo, NonmammalianEnzyme-Linked Immunosorbent AssayFemaleImmunoblottingIn Situ Nick-End LabelingIxodesMaleMusclesOligonucleotidesReal-Time Polymerase Chain ReactionConceptsNon-freezing temperaturesD. melanogasterDrosophila melanogasterCold toleranceLow non-freezing temperaturesFemale adult fliesTransgenic D. melanogasterCold shock injuryAbility of fliesAntifreeze glycoproteinsAdult fliesMolecular basisMelanogasterFlight musclesFliesAntifreeze proteinsHatching rateHigher survival rateApoptotic damageGlycoproteinExpressionToleranceEmbryosProteinApoptosis
2007
Exploring Strategies for Protein Trapping in Drosophila
Quiñones-Coello A, Petrella LN, Ayers K, Melillo A, Mazzalupo S, Hudson AM, Wang S, Castiblanco C, Buszczak M, Hoskins RA, Cooley L. Exploring Strategies for Protein Trapping in Drosophila. Genetics 2007, 175: 1089-1104. PMID: 17179094, PMCID: PMC1840052, DOI: 10.1534/genetics.106.065995.Peer-Reviewed Original ResearchConceptsGreen fluorescent proteinProtein trapEnhancer trapFluorescent proteinExpression dataGFP expressionGFP fusion proteinFluorescent protein tagsCell biological studiesProduction of GFPWeb-accessible databaseChromosomal positionProtein tagsProtein trappingEndogenous proteinsGenomic DNASplice acceptorDonor sequenceNew insertionsMolecular informationGenesProteinDrosophilaTransposonBiological studies
2002
Drosophila Kelch regulates actin organization via Src64-dependent tyrosine phosphorylation
Kelso RJ, Hudson AM, Cooley L. Drosophila Kelch regulates actin organization via Src64-dependent tyrosine phosphorylation. Journal Of Cell Biology 2002, 156: 703-713. PMID: 11854310, PMCID: PMC2174084, DOI: 10.1083/jcb.200110063.Peer-Reviewed Original ResearchMeSH KeywordsActinsAlanineAmino Acid SequenceAnimalsCarrier ProteinsCross-Linking ReagentsDrosophilaDrosophila ProteinsFemaleInsect ProteinsMicrofilament ProteinsMicroscopy, ElectronMolecular Sequence DataMutagenesis, Site-DirectedPhosphorylationProtein-Tyrosine KinasesProto-Oncogene ProteinsRecombinant Fusion ProteinsSequence Homology, Amino AcidSignal TransductionTyrosineConceptsRing canalsActin organizationDrosophila kelch geneOvarian ring canalsRing canal growthActin cross-linking activitySite-directed mutagenesisTwo-dimensional electrophoresisActin binding siteKelch functionDrosophila KelchCross-linking activityProper morphogenesisKelch proteinTyrosine phosphorylationKelch geneNegative regulationRepeat 5KelchActin filamentsResidue 627Biochemical studiesCanal growthProteinMutants
1997
Formation of the Drosophila Ovarian Ring Canal Inner Rim Depends on cheerio
Robinson D, Smith-Leiker T, Sokol N, Hudson A, Cooley L. Formation of the Drosophila Ovarian Ring Canal Inner Rim Depends on cheerio. Genetics 1997, 145: 1063-1072. PMID: 9093858, PMCID: PMC1207876, DOI: 10.1093/genetics/145.4.1063.Peer-Reviewed Original ResearchMeSH KeywordsActinsAllelesAnimalsCalmodulin-Binding ProteinsCarrier ProteinsCell CommunicationCell MembraneChromosome MappingCytoskeletonDrosophila melanogasterDrosophila ProteinsFemaleGene Expression Regulation, DevelopmentalGenes, InsectInfertility, FemaleInsect ProteinsIntercellular JunctionsMicrofilament ProteinsOocytesOvaryConceptsStable intercellular bridgesExamination of mutantsDrosophila oogenesisPlasma membrane stabilizationRing canalsCytoplasm transportMutant cellsFilamentous actinCleavage furrowRIM proteinsNurse cellsActin filamentsIntercellular bridgesMutantsCritical functionsKelchCheeriosProteinStep-wise processAssemblyMembrane stabilizationCellsCytoskeletonOogenesisGenes