Causes and Consequences of Size Evolution in Drosophila melanogaster
果蝇体型进化的原因和后果
基本信息
- 批准号:8764876
- 负责人:
- 金额:$ 24.77万
- 依托单位:
- 依托单位国家:美国
- 项目类别:
- 财政年份:2014
- 资助国家:美国
- 起止时间:2014-08-01 至 2019-04-30
- 项目状态:已结题
- 来源:
- 关键词:AdultAfricanAltitudeAttentionBiologicalBiological ModelsBody SizeBuffersCandidate Disease GeneCell CountCell CycleCell NucleusCell ProliferationCell SizeCellsClustered Regularly Interspaced Short Palindromic RepeatsCodeCollectionComplementDataDetectionDevelopmentDiabetes MellitusDiseaseDrosophila genusDrosophila melanogasterEpithelialEthiopiaEvolutionFoundationsFrequenciesGene MutationGene TargetingGene Transfer TechniquesGenerationsGenesGeneticGenetic VariationGenetic screening methodGenomicsHaplotypesHomologous GeneHumanInbreedingInsulinKnowledgeLaboratoriesLearningLinkMalignant NeoplasmsMapsMediatingMedicalMedical ResearchMethodsMolecularMuscleMuscle CellsMuscle FibersMutagenesisMutationNatural SelectionsNatureOrganismPhenotypePlayPloidiesPopulationPopulation GeneticsPropertyQuantitative GeneticsQuantitative Trait LociRecording of previous eventsResearchResourcesRoleSamplingScanningSignal PathwaySystemTestingTissuesTransgenic OrganismsVariantVeinsWingWorkbaseflygene functiongene replacementgenetic analysisgenome-wideinsulin signalinginterestnovelnovel strategiespublic health relevanceresearch studysimulationstatisticsstemtooltrait
项目摘要
DESCRIPTION (provided by applicant): This research investigates the genetic basis, cellular mechanisms, and developmental consequences of body and wing size evolution in a newly discovered high altitude population of Drosophila melanogaster which represents the largest known flies of this species. This trait offers the unique opportunity to relate a biologically important phenotypic difference to its underlying cellular mechanisms and to specific genes and mutations responsible for this change. The Drosophila system offers a range of advantages to study adaptive evolution at the genetic level, from population genomic data to transgenic tools. Results will increase our knowledge of the polygenicity of adaptation and the properties of causative variants (e.g. coding vs. regulatory; new mutations vs. standing genetic variation). This research integrates biological subdisciplines to reveal cell-level mechanisms (e.g. cell proliferation and somatic ploidy) responsible for phenotypic evolution. It also takes a rare look a the potential influence of adaptive evolution on developmental stability. This work will reveal how evolution has altered the function of genes involved in insulin signaling and the cell cycle without harmful consequences to the organism - findings that may ultimately prove relevant for research on cancer, diabetes, and other medical conditions. 1. Conduct a genome-wide search for genes that play a role in body size evolution. Confirm their effects and test causative mutations using transgenesis. A novel QTL mapping method will localize causative genes to the ~100kb scale. A new population genetic statistic will reveal genes within QTL intervals that show evidence of population-specific selection in the highland sample (initial outliers include insulin signaling genes). Genes identified will be functionally tested for influence on body and wing size using a newly developed transgenic approach; specific mutations will be tested in the same way. 2. Reveal cellular mechanisms underlying body size evolution. Research will test whether changes in both cell size and number may give rise to the strikingly large wings of Ethiopian D. melanogaster. Research will also confirm whether the observed enlargement of larval muscles (polynucleate cells which strongly influence adult body size) is due to increases in the number of nuclei or their ploidy. Transgenic constructs will allow the cellular influence of
specific adaptive mutations to be assessed. 3. Test whether wing size evolution disrupted developmental canalization. Ethiopian inbred lines show large wings but also very high frequencies of wing vein abnormalities. The hypothesis that phenotypic evolution has destabilized a more developmentally buffered ancestral wing state will be directly tested using a mutagenesis test of genetic perturbility. Artificial selection to recapitulate wing size evolution n the lab will further probe the generality of a link between adaptation and decanalization.
描述(由申请人提供):本研究调查了新发现的高海拔黑腹果蝇种群中身体和翅膀大小进化的遗传基础、细胞机制和发育后果,黑腹果蝇是该物种中已知最大的果蝇。这种特性提供了将生物学上重要的表型差异与其潜在的细胞机制以及负责这种变化的特定基因和突变联系起来的独特机会。果蝇系统提供了一系列的优势,在遗传水平上研究适应性进化,从人口基因组数据到转基因工具。结果将增加我们对适应的多基因性和致病变异的特性(例如编码与调节;新突变与常设遗传变异)的了解。这项研究整合了生物学分支学科,以揭示细胞水平的机制(例如细胞增殖和体细胞倍性)负责表型进化。它也很少看到适应性进化对发育稳定性的潜在影响。这项工作将揭示进化如何改变参与胰岛素信号传导和细胞周期的基因的功能,而不会对生物体产生有害影响-这些发现最终可能与癌症,糖尿病和其他医疗条件的研究有关。1.进行全基因组搜索,寻找在体型进化中起作用的基因。确认它们的影响,并使用转基因测试致病突变。一种新的QTL定位方法将致病基因定位到~ 100 kb的范围。一个新的群体遗传统计将揭示QTL区间内的基因,这些基因显示了高地样本中群体特异性选择的证据(初始离群值包括胰岛素信号基因)。确定的基因将使用新开发的转基因方法进行功能测试,以确定对身体和翅膀大小的影响;特定的突变将以相同的方式进行测试。2.揭示身体大小进化的细胞机制。研究将测试细胞大小和数量的变化是否会导致埃塞俄比亚D.黑腹菌研究还将确认所观察到的幼虫肌肉(强烈影响成体体型的多核细胞)的增大是否是由于核数或其倍性的增加。转基因构建体将允许细胞的影响,
特定的适应性突变进行评估。3.测试翅膀大小的进化是否破坏了发育的渠道。埃塞俄比亚近交系显示大翅膀,但也非常高的频率翅静脉异常。假设表型进化已经不稳定的一个更发达的缓冲祖先翼状态将直接测试使用遗传扰动的诱变测试。在实验室中重现翅膀大小进化的人工选择将进一步探索适应和迁徙之间联系的普遍性。
项目成果
期刊论文数量(0)
专著数量(0)
科研奖励数量(0)
会议论文数量(0)
专利数量(0)
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JOHN E POOL其他文献
JOHN E POOL的其他文献
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{{ truncateString('JOHN E POOL', 18)}}的其他基金
Genomic Diversity and the Architectures of Adaptation and Incompatibility
基因组多样性以及适应和不相容的架构
- 批准号:
10368935 - 财政年份:2020
- 资助金额:
$ 24.77万 - 项目类别:
Genomic Diversity and the Architectures of Adaptation and Incompatibility
基因组多样性以及适应和不相容的架构
- 批准号:
10593052 - 财政年份:2020
- 资助金额:
$ 24.77万 - 项目类别:
Unraveling the Molecular and Population Genetic Complexity of Adaptive Trait Evolution
揭示适应性特征进化的分子和群体遗传复杂性
- 批准号:
10343824 - 财政年份:2019
- 资助金额:
$ 24.77万 - 项目类别:
Unraveling the Molecular and Population Genetic Complexity of Adaptive Trait Evolution
揭示适应性特征进化的分子和群体遗传复杂性
- 批准号:
9901541 - 财政年份:2019
- 资助金额:
$ 24.77万 - 项目类别:
Causes and Consequences of Size Evolution in Drosophila melanogaster
果蝇体型进化的原因和后果
- 批准号:
9269111 - 财政年份:2014
- 资助金额:
$ 24.77万 - 项目类别:
Causes and Consequences of Size Evolution in Drosophila melanogaster
果蝇体型进化的原因和后果
- 批准号:
9057098 - 财政年份:2014
- 资助金额:
$ 24.77万 - 项目类别:
The use of recombining genetic markers for demographic inference
使用重组遗传标记进行人口统计推断
- 批准号:
7563644 - 财政年份:2006
- 资助金额:
$ 24.77万 - 项目类别:
The use of recombining genetic markers for demographic inference
使用重组遗传标记进行人口统计推断
- 批准号:
7320276 - 财政年份:2006
- 资助金额:
$ 24.77万 - 项目类别:
The use of recombining genetic markers for demographic inference
使用重组遗传标记进行人口统计推断
- 批准号:
7626005 - 财政年份:2006
- 资助金额:
$ 24.77万 - 项目类别:
The use of recombining genetic markers for demographic inference
使用重组遗传标记进行人口统计推断
- 批准号:
7293413 - 财政年份:2006
- 资助金额:
$ 24.77万 - 项目类别:
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