about
A reversible color polyphenism in American peppered moth (Biston betularia cognataria) caterpillarsComparative genome sequencing of Drosophila pseudoobscura: chromosomal, gene, and cis-element evolutionA microsatellite linkage map of Drosophila mojavensisLittle qualitative RNA misexpression in sterile male F1 hybrids of Drosophila pseudoobscura and D. persimilis.Speciation genetics: evolving approaches.Evolutionary genetics: jumping into a new species.Gene expression disruptions of organism versus organ in Drosophila species hybridsThe genomics of speciation in Drosophila: diversity, divergence, and introgression estimated using low-coverage genome sequencing.Islands of speciation or mirages in the desert? Examining the role of restricted recombination in maintaining species.Genetics and evolution: an iOS application to supplement introductory courses in transmission and evolutionary genetics.Reinforcement and other consequences of sympatry.The role of meiotic drive in hybrid male sterility.Speciation by reinforcement: a model derived from studies of DrosophilaTranslocation of Y-linked genes to the dot chromosome in Drosophila pseudoobscura.Zinc finger binding motifs do not explain recombination rate variation within or between species of Drosophila.Likelihoods from summary statistics: recent divergence between species.Consequences of recombination rate variation on quantitative trait locus mapping studies. Simulations based on the Drosophila melanogaster genome.How big is your Y? A genome sequence-based estimate of the size of the male-specific region in Megaselia scalaris.How hot are drosophila hotspots? examining recombination rate variation and associations with nucleotide diversity, divergence, and maternal age in Drosophila pseudoobscura.Recombination and the divergence of hybridizing species.Genetics of hybrid male sterility among strains and species in the Drosophila pseudoobscura species groupEffects of inversions on within- and between-species recombination and divergenceTemporal Stability of Molecular Diversity Measures in Natural Populations of Drosophila pseudoobscura and Drosophila persimilis.Mistaken Identity: Another Bias in the Use of Relative Genetic Divergence Measures for Detecting Interspecies Introgression.Mapping of within-species segregation distortion in Drosophila persimilis and hybrid sterility between D. persimilis and D. pseudoobscuraReproductive interference by male Drosophila subobscura on female D. persimilis: A laboratory experimentPolytene chromosomal maps of 11 Drosophila species: the order of genomic scaffolds inferred from genetic and physical maps.Fine-scale mapping of recombination rate in Drosophila refines its correlation to diversity and divergenceStudying recombination with high-throughput sequencing: an educational primer for use with "fine-scale heterogeneity in crossover rate in the garnet-scalloped region of the Drosophila melanogaster X chromosome"Sequence signatures of a recent chromosomal rearrangement in Drosophila mojavensis.Molecular evolution of a Drosophila homolog of human BRCA2.The large X-effect on secondary sexual characters and the genetics of variation in sex comb tooth number in Drosophila subobscuraRecombination rate variation in closely related species.What do we need to know about speciation?Interpreting the genomic landscape of speciation: a road map for finding barriers to gene flow.Variation in Recombination Rate: Adaptive or Not?Gene conversion and linkage: effects on genome evolution and speciation.The 2013 Novitski Prize: Jonathan Pritchard.Variation in recombination rate may bias human genetic disease mapping studies.Recombining without Hotspots: A Comprehensive Evolutionary Portrait of Recombination in Two Closely Related Species of Drosophila.
P50
Q21092181-4F53D10D-A904-402E-8F9C-EE682176DBF8Q22065751-D19B734D-15A8-4F2B-8B55-9F920B33D107Q24791028-7ED81761-DA75-446E-9F7E-22900B74BB80Q24803195-CFAB5DEE-359C-4A2A-8DF8-B8136A4291A7Q31065802-B80A445B-FD08-4BED-B396-27173E583785Q31068572-B6717B84-1256-4DE6-9504-A188A08D28E0Q33361634-4F6432AA-0179-4F96-B63A-32FFAA1927D3Q33478384-6AEB92ED-9650-4F9A-B9E0-D84BB7C0871BQ33601218-459F712F-94F2-42C0-B595-4941A9A1F10EQ33629505-FC1BFB5A-E8C4-4B7F-8A67-B3E22DCCA8BBQ33808394-082E6758-E1F8-420F-A068-E73144E2AFAEQ33856616-0D14EBB3-9600-48CC-BC39-D991D6A2AC5AQ33968057-1C4FE79B-53CE-4E1F-BC1E-0BB82240534CQ34029796-CFA2B3AA-F4ED-4083-97A6-17409A02D1A6Q34427957-49054A9E-2357-46AB-A97A-141E236499AAQ34590103-1C39E6EF-1ED7-497B-9867-7EA65D64BC10Q34613428-4B044673-D3F5-462B-B86D-113A6EADF873Q34923863-D1893636-DB95-4766-BF5C-C233B5D62F18Q34964179-ADDB39CC-2C8B-4AD1-B3DD-76F5C4528031Q35055844-2D5B96EB-D4FF-4054-9509-F6974A379EF3Q35093250-2C06EE6D-BB50-4232-91C9-F9169B7B8C41Q35209631-EF19AE29-5C1D-4117-8D6B-3EE2813689E2Q35974914-948318F4-2527-4A67-A7C4-CF361CB1B91EQ36168083-2DEF5233-406F-4E7E-91A2-564D4231D286Q36235681-6484D0F2-03AF-48BD-A0B4-202E33CA62FBQ36345459-DA44CA9E-C5C0-45B4-857E-B7A8DD809EAEQ36778170-343D171A-1039-4787-AF52-DA68CE61631BQ36786945-26D7F93A-A5D8-4946-8DFD-9C1649E2948EQ36878575-6812D7D0-6707-4955-809B-5737D924FA07Q37147834-BB279A80-803A-41D5-B6BC-5F31739ECB81Q37373337-D14DA371-E0E7-4EDF-9562-9AE151D9AFDBQ37592559-C358F392-2399-426C-8F5C-1EB0263D5E4EQ37889637-E28E6049-943F-443A-BEC7-1D0D02FDCF91Q37943032-2C4690C6-AA02-440F-AEA7-2E64D91DB1A8Q38635379-7433E3BC-FA8C-4DD7-877A-D44F848EC1BBQ38866641-DA034B3B-71BB-40F9-8490-5449DAAFADC8Q38874683-0C6F96B9-3BD6-4FE7-9D88-672E56CB59D8Q39994226-77353D26-B4CA-4471-BEB1-06FA904D13FFQ40459905-0DE8EB69-F34B-4597-B241-7835511C5A07Q40474449-D00D6E67-A869-4220-A8E0-5E6291BBE099
P50
description
Forscher
@de
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Mohamed Noor
@ast
Mohamed Noor
@de
Mohamed Noor
@en
Mohamed Noor
@es
Mohamed Noor
@nl
type
label
Mohamed Noor
@ast
Mohamed Noor
@de
Mohamed Noor
@en
Mohamed Noor
@es
Mohamed Noor
@nl
altLabel
Mohamed A. F. Noor
@de
Mohamed A. F. Noor
@en
prefLabel
Mohamed Noor
@ast
Mohamed Noor
@de
Mohamed Noor
@en
Mohamed Noor
@es
Mohamed Noor
@nl
P108
P106
P21
P31
P4012
P496
0000-0002-5400-4408