Search results for "La Protein"

showing 10 items of 245 documents

Pentamidine rescues contractility and rhythmicity in a Drosophila model of myotonic dystrophy heart dysfunction

2015

Up to 80% of individuals with myotonic dystrophy type 1 (DM1) will develop cardiac abnormalities at some point during the progression of their disease, the most common of which is heart blockage of varying degrees. Such blockage is characterized by conduction defects and supraventricular and ventricular tachycardia, and carries a high risk of sudden cardiac death. Despite its importance, very few animal model studies have focused on the heart dysfunction in DM1. Here, we describe the characterization of the heart phenotype in a Drosophila model expressing pure expanded CUG repeats under the control of the cardiomyocyte-specific driver GMH5-Gal4. Morphologically, expression of 250 CUG repeat…

[SDV]Life Sciences [q-bio]Myotonic dystrophyMedicine (miscellaneous)lcsh:MedicineVentricular tachycardiaImmunology and Microbiology (miscellaneous)DiastoleHeart RateDrosophila ProteinsMyocytes CardiacGeneticsbiologyRNuclear ProteinsHeartPhenotype3. Good healthCell biology[SDV] Life Sciences [q-bio]Drosophila melanogasterPhenotypeDrosophilaDrosophila melanogasterDrosophila ProteinResearch Articlelcsh:RB1-214congenital hereditary and neonatal diseases and abnormalitiesSystoleLongevityNeuroscience (miscellaneous)In situ hybridizationMyotonic dystrophyGeneral Biochemistry Genetics and Molecular BiologyMuscleblindContractilitymedicinelcsh:PathologyAnimalsPentamidineHeart dysfunctionfungilcsh:RArrhythmias Cardiacbiology.organism_classificationmedicine.diseaseMyocardial ContractionSurvival AnalysisDisease Models AnimalTrinucleotide repeat expansionTrinucleotide Repeat Expansion
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Tracing the origin of the compensasome: evolutionary history of DEAH helicase and MYST acetyltransferase gene families.

2001

Dosage compensation in Drosophila is mediated by a complex of proteins and RNAs called the "compensasome." Two of the genes that encode proteins of the complex, maleless (mle) and males-absent-on-the-first (mof), respectively, belong to the DEAH helicase and MYST acetyltransferase gene families. We performed comprehensive phylogenetic and structural analyses to determine the evolutionary histories of these two gene families and thus to better understand the origin of the compensasome. All of the members of the DEAH and MYST families of the completely sequenced Saccharomyces cerevisiae and Caenorhabditis elegans genomes, as well as those so far (June 2000) found in Drosophila melanogaster (f…

animal structuresChromosomal Proteins Non-HistoneMolecular Sequence DataBiologyEvolution MolecularAcetyltransferasesGeneticsGene familyAnimalsDrosophila ProteinsAmino Acid SequenceMolecular BiologyGeneEcology Evolution Behavior and SystematicsCaenorhabditis elegansPhylogenyHistone AcetyltransferasesGeneticsDosage compensationSequence Homology Amino AcidfungiDNA HelicasesHelicaseNuclear Proteinsbiology.organism_classificationRNA Helicase ACaenorhabditisDNA-Binding ProteinsMultigene Familybiology.proteinDrosophila melanogasterRNA HelicasesTranscription FactorsMolecular biology and evolution
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Spatially restricted expression of PlOtp, a Paracentrotus lividus Orthopedia-related homeobox gene, is correlated with oral ectodermal patterning and…

1999

ABSTRACT Several homeobox genes are expressed in the sea urchin embryo but their roles in development have yet to be elucidated. Of particular interest are homologues of homeobox genes that in mouse and Drosophila are involved in patterning the developing central nervous system (CNS). Here, we report the cloning of an orthopedia (Otp)-related gene from Paracentrotus lividus, PlOtp. Otp is a single copy zygotic gene that presents a unique and highly restricted expression pattern. Transcripts were first detected at the mid-gastrula stage in two pairs of oral ectoderm cells located in a ventrolateral position, overlying primary mesenchyme cell (PMC) clusters. Increases in both transcript abund…

animal structuresDNA ComplementaryStomodeumBody PatterningPolarity in embryogenesisCell specificationCleavage Stage OvumMolecular Sequence DataGene DosageGene ExpressionSettore BIO/11 - Biologia MolecolareEctodermNerve Tissue ProteinsParacentrotus lividusGene expressionEctodermmedicineAnimalsDrosophila ProteinsAmino Acid SequenceCloning MolecularMolecular BiologyBody PatterningGeneticsHomeodomain ProteinsbiologyBase SequenceGenes HomeoboxOrthopediaSequence Analysis DNAbiology.organism_classificationCell biologymedicine.anatomical_structureEctopic expressionParacentrotus lividusSea UrchinsSpiculogenesisSettore BIO/03 - Botanica Ambientale E Applicataembryonic structuresHomeoboxEctopic expressionDevelopmental Biology
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Evidence for differential and redundant function of the Sox genes Dichaete and SoxN during CNS development in Drosophila.

2002

Group B Sox-domain proteins encompass a class of conserved DNA-binding proteins expressed from the earliest stages of metazoan CNS development. In all higher organisms studied to date, related Group B Sox proteins are co-expressed in the developing CNS; in vertebrates there are three (Sox1, Sox2 and Sox3) and in Drosophila there are two (SoxNeuro and Dichaete). It has been suggested there may be a degree of functional redundancy in Sox function during CNS development. We describe the CNS phenotype of a null mutation in the Drosophila SoxNeuro gene and provide the first direct evidence for both redundant and differential Sox function during CNS development in Drosophila. In the lateral neuro…

animal structuresEmbryo NonmammalianMutantBiologyNervous SystemSOX Transcription FactorsSOX1NeuroblastSOX2Species SpecificityEctodermAnimalsDrosophila ProteinsMolecular BiologySOX Transcription FactorsGeneticsNeuroectodermHigh Mobility Group ProteinsGene Expression Regulation DevelopmentalPhenotypeNull alleleDNA-Binding ProteinsDrosophila melanogasterMutagenesisembryonic structuresVertebratesDevelopmental BiologyTranscription FactorsDevelopment (Cambridge, England)
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Molecular markers for identified neuroblasts in the developing brain of Drosophila.

2003

The Drosophila brain develops from the procephalic neurogenic region of the ectoderm. About 100 neural precursor cells (neuroblasts) delaminate from this region on either side in a reproducible spatiotemporal pattern. We provide neuroblast maps from different stages of the early embryo (stages 9, 10 and 11, when the entire population of neuroblasts has formed), in which about 40 molecular markers representing the expression patterns of 34 different genes are linked to individual neuroblasts. In particular, we present a detailed description of the spatiotemporal patterns of expression in the procephalic neuroectoderm and in the neuroblast layer of the gap genes empty spiracles, hunchback, hu…

animal structuresFasciclin 2EctodermBiologyNeuroblastmedicineMorphogenesisAnimalsDrosophila ProteinsMolecular BiologyGap geneIn Situ HybridizationGeneticsHomeodomain ProteinsNeuronsNeuroectodermfungiGenes HomeoboxBrainGene Expression Regulation DevelopmentalNuclear ProteinsNeuromereCell biologyDNA-Binding Proteinsmedicine.anatomical_structureDrosophila melanogasternervous systemembryonic structuresTrans-ActivatorsHomeotic geneGanglion mother cellBiomarkersDevelopmental BiologyDevelopment (Cambridge, England)
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Number, identity, and sequence of the Drosophila head segments as revealed by neural elements and their deletion patterns in mutants.

1994

The development of the insect head tagma involves massive rearrangements and secondary fusions of segment anlagen during embryogenesis. Due to the lack of reliable morphological markers, the number, identity, and sequence of the head segments, particularly in the pregnathal region, are still a matter of ongoing debates. We examined the complex array of internal structures of the embryonic Drosophila melanogaster head such as the sensory structures and nerves of the peripheral and stomatogastric nervous systems, and we used embryonic head mutations causing a lack of overlapping segment anlagen to unravel the segmental identity and the sequence of the neural elements. Our results provide evid…

animal structuresHead (linguistics)media_common.quotation_subjectMorphogenesisInsectPeripheral Nervous SystemMorphogenesisAnimalsDrosophila ProteinsDrosophila (subgenus)TagmaSequence (medicine)media_commonHomeodomain ProteinsGeneticsMultidisciplinarybiologyPhylogenetic treeGenes Homeoboxbiology.organism_classificationDrosophila melanogasterInsect HormonesImmunologic TechniquesDrosophila melanogasterHeadResearch ArticleTranscription FactorsProceedings of the National Academy of Sciences
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Cabut, a C2H2 zinc finger transcription factor, is required during Drosophila dorsal closure downstream of JNK signaling.

2005

AbstractDuring dorsal closure, the lateral epithelia on each side of the embryo migrate dorsally over the amnioserosa and fuse at the dorsal midline. Detailed genetic studies have revealed that many molecules are involved in this epithelial sheet movement, either with a signaling function or as structural or motor components of the process. Here, we report the characterization of cabut (cbt), a new Drosophila gene involved in dorsal closure. cbt is expressed in the yolk sac nuclei and in the lateral epidermis. The Cbt protein contains three C2H2-type zinc fingers and a serine-rich domain, suggesting that it functions as a transcription factor. cbt mutants die as embryos with dorsal closure …

animal structuresMorphogenesisBiologyCabutZinc fingerMorphogenesismedicineAnimalsDrosophila ProteinsDorsal closureYolk sacMolecular BiologyTranscription factorYolk nucleiCytoskeletonGeneticsZinc fingerEpidermis (botany)C2H2 Zinc FingerJNK Mitogen-Activated Protein KinasesZinc FingersCell BiologyDorsal closureCell biologymedicine.anatomical_structureDrosophila melanogasterEpidermal Cellsembryonic structuresMutationJNK cascadeDrosophilaJNKDevelopmental BiologySignal TransductionTranscription FactorsDevelopmental biology
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Notch and Numb are required for normal migration of peripheral glia in Drosophila

2006

Abstract A prominent feature of glial cells is their ability to migrate along axons to finally wrap and insulate them. In the embryonic Drosophila PNS, most glial cells are born in the CNS and have to migrate to reach their final destinations. To understand how migration of the peripheral glia is regulated, we have conducted a genetic screen looking for mutants that disrupt the normal glial pattern. Here we present an analysis of two of these mutants: Notch and numb. Complete loss of Notch function leads to an increase in the number of glial cells. Embryos hemizygous for the weak NotchB-8X allele display an irregular migration phenotype and mutant glial cells show an increased formation of …

animal structuresMutantNotch signaling pathwayBiologyCell MovementGlial cell migrationAnimalsDrosophila ProteinsMolecular BiologyGeneticsReceptors NotchCell migrationCell BiologyImmunohistochemistryEmbryonic stem cellPhenotypeCell biologyJuvenile Hormonesnervous systemMutagenesisNUMBDrosophilaNeurogliaSignal TransductionGenetic screenDevelopmental BiologyDevelopmental Biology
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A Protein Nuclear Extract fromD. melanogasterLarval Tissues

2008

Preparation of protein nuclear extracts is often the first step to study in vitro biological processes occurring in the nucleus of the eukaryotic cell. Nuclear extracts have been extensively used in different model organisms to identify and study protein function in nuclei. Drosophila embryos can be collected in large quantities and have been the source of choice for the production of protein nuclear extracts. However, most of Drosophila in vivo studies on protein function are conducted in larval tissues. Here we report a new method to produce highly stable large-scale protein nuclear extracts from whole Drosophila larvae that are suited for a variety of biochemical analyses.

animal structuresved/biology.organism_classification_rank.speciesBiologyCell FractionationIn vivoSettore BIO/10 - BiochimicaBotanymedicineMelanogasterAnimalsDrosophila ProteinsModel organismDrosophilaCell NucleusLarvaved/biologyfungiNuclear ProteinsEmbryobiology.organism_classificationIn vitroDrosophila melanogastermedicine.anatomical_structureMicroscopy FluorescenceBiochemistryLarvaDrosophila nuclear extractInsect ScienceNucleusFly
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Effects of cold acclimation and dsRNA injections on Gs1l gene splicing in Drosophila montana

2017

Abstract Alternative splicing, in which one gene produce multiple transcripts, may influence how adaptive genes respond to specific environments. A newly produced transcriptome of Drosophila montana shows the Gs1-like (Gs1l) gene to express multiple splice variants and to be down regulated in cold acclimated flies with increased cold tolerance. Gs1l’s effect on cold tolerance was further tested by injecting cold acclimated and non-acclimated flies from two distantly located northern and southern fly populations with double stranded RNA (dsRNA) targeting Gs1l. While both populations had similar cold acclimation responses, dsRNA injections only effected the northern population. The nature of …

cold resistancemahlakärpäsetAcclimatizationlcsh:MedicineacclimationArticleInjectionskylmänkestävyysNucleotidasesAnimalsDrosophila ProteinsHumansProtein IsoformsDrosophilidaegeneslcsh:ScienceRNA Double-StrandedgeenitSequence Homology Amino Acidfungilcsh:RProteinsCold ClimateakklimatisaatioAlternative SplicingRNADrosophilalcsh:QScientific Reports
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