Search results for "Ommatidium"

showing 2 items of 2 documents

Quantitative Assessment of Eye Phenotypes for Functional Genetic Studies Using Drosophila melanogaster

2016

AbstractAbout two-thirds of the vital genes in the Drosophila genome are involved in eye development, making the fly eye an excellent genetic system to study cellular function and development, neurodevelopment/degeneration, and complex diseases such as cancer and diabetes. We developed a novel computational method, implemented as Flynotyper software (http://flynotyper.sourceforge.net), to quantitatively assess the morphological defects in the Drosophila eye resulting from genetic alterations affecting basic cellular and developmental processes. Flynotyper utilizes a series of image processing operations to automatically detect the fly eye and the individual ommatidium, and calculates a phen…

0301 basic medicinegenetic structuresNeurogenesisComputational biologyInvestigationsQH426-470EyeAnimals Genetically Modified03 medical and health sciences0302 clinical medicineOmmatidiumGeneticsAnimalsDrosophila Proteinshuman disease modelsEnhancerMolecular BiologyGeneGenetics (clinical)Genetic Association StudiesGeneticsGene knockdownbiologyModels Geneticneurodevelopmental disordersReproducibility of Resultsbiology.organism_classificationommatidiaPhenotypeeye diseases030104 developmental biologyPhenotypeDrosophila melanogastermodifier screensrough eyeGene Knockdown TechniquesEye developmentsense organsDrosophila melanogaster030217 neurology & neurosurgeryDrosophila ProteinFunction (biology)AlgorithmsG3: Genes, Genomes, Genetics
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Crystalline wax coverage of the imaginal cuticle inCalopteryx splendens(Odonata: Calopterygidae)

2009

Abstract In this study we use high resolution SEM to describe the diversity of wax crystals and their distribution on different morphological structures in male individuals of Calopteryx splendens. The entire cuticle surface of this damselfly, with the exception of ommatidia and ocelli, is covered with crystalline wax in dimensions from submicron to micron range. It is shown that shape - rod-like, plate like, filamentous, etc. -, size, and density of crystals vary on different surfaces and in individuals of different ages. Additionally, we demonstrate different types of damage to the crystalline wax layer: scratches, compressions, wear, and contamination. The primary function of the wax cry…

WaxbiologyCuticleSimple eye in invertebratesHigh resolutionOdonatabiology.organism_classificationDamselflyCalopterygidaeOmmatidiumInsect Sciencevisual_artBotanyvisual_art.visual_art_mediumsense organsComposite materialEcology Evolution Behavior and SystematicsInternational Journal of Odonatology
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