Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
about
Departure from neutrality at the mitochondrial NADH dehydrogenase subunit 2 gene in humans, but not in chimpanzeesThe evolutionary biology of poxvirusesMore effective purifying selection on RNA viruses than in DNA virusesPhylogeography of Bufo marinus from its natural and introduced rangesMolecular population genetics of the southern elephant seal Mirounga leoninaExtensive amino acid polymorphism at the pgm locus is consistent with adaptive protein evolution in Drosophila melanogaster.Searching for evidence of selection in avian DNA barcodes.Molecular population genetics of the Arabidopsis CAULIFLOWER regulatory gene: nonneutral evolution and naturally occurring variation in floral homeotic functionElevated evolutionary rates in the laboratory strain of Saccharomyces cerevisiae.Prediction of harmful variants on mitochondrial genes: Test of habitat-dependent and demographic effects in a euryhaline fish.Comparative genomics and the evolution of human mitochondrial DNA: assessing the effects of selectionCompetition between mitochondrial haplotypes in distinct nuclear genetic environments: Drosophila pseudoobscura vs. D. persimilis.Conditional hitchhiking of mitochondrial DNA: frequency shifts of Drosophila melanogaster mtDNA variants depend on nuclear genetic background.Nonneutral mitochondrial DNA variation in humans and chimpanzeesDegree of selective constraint as an explanation of the different rates of evolution of gender-specific mitochondrial DNA lineages in the mussel mytilus.Molecular evolution between Drosophila melanogaster and D. simulans: reduced codon bias, faster rates of amino acid substitution, and larger proteins in D. melanogaster.Patterns of DNA variability at X-linked loci in Mus domesticusReduced selective constraint in endosymbionts: elevation in radical amino acid replacements occurs genome-wide.Mechanisms of molecular evolution.MtDNA segregation in heteroplasmic tissues is common in vivo and modulated by haplotype differences and developmental stage.Contrasting evolutionary dynamics and information content of the avian mitochondrial control region and ND2 gene.The molecular basis of quantitative genetic variation in central and secondary metabolism in Arabidopsis.Nonneutral evolution and differential mutation rate of gender-associated mitochondrial DNA lineages in the marine mussel Mytilus.Deleterious mutations at the mitochondrial ND3 gene in South American marsh rats (Holochilus).Understanding the overdispersed molecular clockContrasting patterns of nonneutral evolution in proteins encoded in nuclear and mitochondrial genomes.The abundance of deleterious polymorphisms in humans.Comparative Phylogenomic Assessment of Mitochondrial Introgression among Several Species of Chipmunks (Tamias)Distinguishing between primary and secondary intergradation among morphologically differentiated populations of Anolis marmoratus.More radical amino acid replacements in primates than in rodents: support for the evolutionary role of effective population size.Mitochondrial Haplotype Influences Mycelial Growth of Agaricus bisporus Heterokaryons.The age of nonsynonymous and synonymous mutations in animal mtDNA and implications for the mildly deleterious theoryMitochondrial DNA haplotype frequencies in natural and experimental populations of Drosophila subobscura.Mutational analysis of the human mitochondrial genome branches into the realm of bacterial genetics.Rapidly evolving mitochondrial genome and directional selection in mitochondrial genes in the parasitic wasp nasonia (hymenoptera: pteromalidae).Linkage disequilibria between mtDNA haplotypes and chromosomal arrangements in a natural population of Drosophila subobscura.Divergence of mitochondrial dna is not corroborated by nuclear dna, morphology, or behavior in Drosophila simulans.Gene genealogies, cryptic species, and molecular evolution in the human pathogen Coccidioides immitis and relatives (Ascomycota, Onygenales).Genetic and geographic differentiation in the Rio Negro tuco-tuco (Ctenomys rionegrensis): inferring the roles of migration and drift from multiple genetic markers.Transmitochondrial differences and varying levels of heteroplasmy in nuclear transfer cloned cattle.
P2860
Q24547711-2316688B-C377-4F6F-9887-B97E90FA79EBQ24652228-97101217-6B1D-42FB-A539-1F1448DCA792Q27489846-F817A576-76DB-414E-B64A-8516BC912B55Q28766090-50B534FA-85BE-4D15-98BA-DC6F48115C68Q28767995-DEFE193C-D5CF-49DA-B3E8-EE75A1BA2608Q30974558-B23DF5DB-9050-4B42-8553-ABE5DF58EF5EQ31024279-5F97A149-F876-4F8C-A620-04DC82EFCA81Q33368716-35D5D596-61A1-4138-9F12-6A2BCBE7580CQ33762608-F54CDC26-A0FE-4C31-B633-B790B682E90BQ33789110-E2F9D481-40CC-45F6-845D-BF46999F2749Q33909600-7EDE97A2-71FC-4A46-9E21-1A8511B6AE32Q33965284-9824D525-73F4-423B-BA7E-B15248B77735Q33966070-8ECDD59C-8F97-405D-9CB1-DEB0813325B0Q33966845-51A40AB7-E308-453A-A61C-975D19D25B90Q33968003-931DE71B-5308-435D-8B3C-EC6FAABF9D49Q33968789-476E667D-34B8-4D44-9B63-6FFCFA792B34Q33971247-0305287F-960B-4E7B-B6AB-B17517F0C209Q34110512-62A38807-C5F5-4CC9-B7C6-B469D1A96E4CQ34111865-7CE42BFE-802A-4AE1-A0A4-52E9B07EBF4CQ34423657-A0C32C47-B610-4730-9464-970EB4CD30B4Q34447095-5F93CAE4-7BE8-4764-9360-A8563732680EQ34604653-38BBADD8-05C6-453B-8365-C09A217437A8Q34604836-82E61493-53F9-4BB7-8556-CA402984A75AQ34605158-97909E43-D65E-4CD8-AE53-3AC1EF5459EBQ34609059-2B0DD47A-FF06-49D0-A5F4-986B402360E2Q34610405-D5DB94D8-2DC3-4A5A-95B9-2DE43322B526Q35863150-59DD1B99-0A56-4FC3-937A-320AF2E4FB5AQ36273081-D0E68919-CBAF-4D9E-A75D-FE7B3AC242CDQ36804064-C8CE0288-8185-4225-8205-5A5155F5A168Q37252766-5A3FB546-9C6D-4F54-AADF-B8CCE98F0985Q42124431-BBFEA619-A01A-4CE3-A009-A9AAFD5082E7Q42561109-C61444D0-A895-445E-826C-0B06991EF6E6Q42572032-DCFD3046-230D-48A3-A162-5D6CAE2D438DQ42590264-EA44A47E-6F0D-4E1D-A9E9-73F577BCB640Q43069191-6A97477F-1AC3-4D5F-9635-532325EDBD0CQ45887584-CF5B4C17-8FB8-4B2F-98AC-F8C2DD98278FQ45887653-7594D904-8CAA-4250-AD3B-3BF1518C689EQ45968609-E62F3B4E-E5CF-4A29-88F5-39BA16A9A062Q47871110-7F7D1BD5-3587-44D7-9C0B-64B44BD61D46Q48912241-DF5541A9-9772-4BCA-B509-13F08B1D6F21
P2860
Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
description
1994 nî lūn-bûn
@nan
1994年の論文
@ja
1994年論文
@yue
1994年論文
@zh-hant
1994年論文
@zh-hk
1994年論文
@zh-mo
1994年論文
@zh-tw
1994年论文
@wuu
1994年论文
@zh
1994年论文
@zh-cn
name
Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
@ast
Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
@en
type
label
Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
@ast
Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
@en
prefLabel
Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
@ast
Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
@en
P2093
P2860
P356
P1476
Nonneutral evolution at the mitochondrial NADH dehydrogenase subunit 3 gene in mice.
@en
P2093
C F Aquadro
M W Nachman
P2860
P304
P356
10.1073/PNAS.91.14.6364
P407
P577
1994-07-01T00:00:00Z