Phylogenetic relatedness predicts priority effects in nectar yeast communities.
about
Multilocus sequence analysis of nectar pseudomonads reveals high genetic diversity and contrasting recombination patternsPatterns and processes of microbial community assemblyIntraspecies competition for niches in the distal gut dictate transmission during persistent Salmonella infectionHoney bees avoid nectar colonized by three bacterial species, but not by a yeast species, isolated from the bee gutEvolutionary relatedness does not predict competition and co-occurrence in natural or experimental communities of green algaeDo bacterial and fungal communities assemble differently during primary succession?Range shifting species reduce phylogenetic diversity in high latitude communities via competition.Flowers as islands: spatial distribution of nectar-inhabiting microfungi among plants of Mimulus aurantiacus, a hummingbird-pollinated shrubEvaluating Darwin's naturalization hypothesis in experimental plant assemblages: phylogenetic relationships do not determine colonization success.Integrating teaching and research in undergraduate biology laboratory education.Nectar yeasts in the tall Larkspur Delphinium barbeyi (Ranunculaceae) and effects on components of pollinator foraging behaviorHost species and environmental effects on bacterial communities associated with Drosophila in the laboratory and in the natural environment.Composition, richness and nonrandom assembly of culturable bacterial-microfungal communities in floral nectar of Mediterranean plants.Digging the New York City Skyline: soil fungal communities in green roofs and city parks.Among-population variation in microbial community structure in the floral nectar of the bee-pollinated forest herb Pulmonaria officinalis L.Microbial diversity in the floral nectar of seven Epipactis (Orchidaceae) speciesStructure and phylogenetic diversity of post-fire ectomycorrhizal communities of maritime pine.Experimental evidence that evolutionary relatedness does not affect the ecological mechanisms of coexistence in freshwater green algae.Nectar sugars and bird visitation define a floral niche for basidiomycetous yeast on the Canary Islands.Niche filtering rather than partitioning shapes the structure of temperate forest ant communities.Historical contingency in species interactions: towards niche-based predictionsThe ecology of yeasts in the bark beetle holobiont: a century of research revisited.Order of arrival structures arbuscular mycorrhizal colonization of plants.Initial phylogenetic relatedness of saprotrophic fungal communities affects subsequent litter decomposition rates.Field experimental evidence that stochastic processes predominate in the initial assembly of bacterial communities.Community priming--effects of sequential stressors on microbial assemblages.Experimental evidence for strong stabilizing forces at high functional diversity of aquatic microbial communities.Initial colonization, community assembly and ecosystem function: fungal colonist traits and litter biochemistry mediate decay rate.Microbial diversity in the floral nectar of Linaria vulgaris along an urbanization gradient.Genome composition and phylogeny of microbes predict their co-occurrence in the environment.Micro-organisms behind the pollination scenes: microbial imprint on floral nectar sugar variation in a tropical plant community.Network modules and hubs in plant-root fungal biomesFlorivory and pollinator visitation: a cautionary taleRevisiting Darwin's conundrum reveals a twist on the relationship between phylogenetic distance and invasibility.Microbiology of sugar-rich environments: diversity, ecology and system constraints.Probabilistic Invasion Underlies Natural Gut Microbiome Stability.Non-target effects of fungicides on nectar-inhabiting fungi of almond flowers.Phylogenetic occupancy models integrate imperfect detection and phylogenetic signal to analyze community structure.The genetics of a putative social trait in natural populations of yeast.Nutrient acquisition across a dietary shift: fruit feeding butterflies crave amino acids, nectivores seek salt.
P2860
Q21132505-062C037E-D7EC-43D8-ACF2-147CC7F147BBQ24604557-631AE53B-0004-48B4-AA93-6DFFB90F167AQ27322699-90E6872D-EB06-42B5-933B-8A30F13249C7Q28539029-D84368DF-BF6C-413B-BFBD-898829FC793FQ28652578-52F5AAFA-52BB-4B1A-8F2A-57273E2C9717Q30958497-FF2115C0-03CE-43EE-8F97-603EEB344064Q31163854-B9ADAAA6-D8C0-43DC-B21C-9FC3F351B44BQ33940340-A06109DE-C733-40D1-A358-FA0AEC7A685BQ34070815-B1DDCC4A-FC0B-43D4-B6C3-A96A05B0BCF3Q34081312-C518AE16-E5BF-4675-A15D-8ED9AB047883Q34278122-57F9A6E4-A769-451E-8798-20D0FD47C12EQ34365800-B441CF1C-7EF5-4373-B925-77CA8C5F0FDFQ34443239-67C808E9-4D2A-4D52-9336-5804067492B0Q34613382-70F282C3-8520-4AD7-845F-5EF71B72FECCQ34638948-EB8530F4-F78D-4172-AEDB-0D68429BFBC5Q34803117-5BA6E7C6-BCFB-4A24-AC9E-1589C9D0639AQ34954282-3ACB5160-02F2-4BB4-9D54-9EBC0FA722C5Q35013495-5EA83759-A14C-4607-A103-F4C48BDA3CCFQ35052798-8F94D454-47A3-4791-A733-54B59FA19FC2Q35056608-0C6FBB97-8785-418B-89CF-841751BDB33EQ35132206-793C8843-8F7C-47BD-BE7D-3D16FB207936Q35223724-B930E0E4-E90E-4E95-AB29-B8D88995DA26Q35314599-F4D3C802-C5A5-49CD-B648-A7EF42BDA144Q35352159-FEDCA1C3-2404-4409-B52A-8B7E1E7BB325Q35586927-C1948248-283F-45D0-BA95-68D33E994A3AQ35601260-9F09F2C1-D060-4C71-8C3E-C0318D6C6A6DQ35734537-B6DEB44D-91C4-404B-9205-B2D8CD1A356EQ35762120-4A663659-09FC-42F8-959A-6FBB907702DAQ35974677-3407C693-9913-4F8F-8B65-157108DD0131Q36267608-FBBAC5C6-C3DC-4770-9363-9FDE9631F880Q36338132-0CB2B811-3100-444E-9F75-9471CB09F2BCQ36832044-2A786C97-886F-47D3-BBFC-97584E240D46Q37084193-B9E7C6B9-405D-42F1-BC3D-0F0EF95B0B9BQ37409267-E3106CC5-D93A-4291-85B8-B180E1FAC36FQ38231662-5980F2D9-BB83-41C4-B5BC-B6CCFB18D3CDQ38430467-ED9C6E61-D23A-4923-B541-019DEA6CB3A6Q38790607-8265936E-35E9-4AA6-961F-EB68525457E6Q39040933-E4B3BD1D-D98E-4426-87EF-E178C8686911Q40218581-1277B7D4-D3A8-4AC7-9843-153336534B2CQ41996674-3E7F144E-37E1-43AC-8872-8DFB0E4C5A2D
P2860
Phylogenetic relatedness predicts priority effects in nectar yeast communities.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年学术文章
@wuu
2011年学术文章
@zh
2011年学术文章
@zh-cn
2011年学术文章
@zh-hans
2011年学术文章
@zh-my
2011年学术文章
@zh-sg
2011年學術文章
@yue
2011年學術文章
@zh-hant
name
Phylogenetic relatedness predicts priority effects in nectar yeast communities.
@en
Phylogenetic relatedness predicts priority effects in nectar yeast communities.
@nl
type
label
Phylogenetic relatedness predicts priority effects in nectar yeast communities.
@en
Phylogenetic relatedness predicts priority effects in nectar yeast communities.
@nl
prefLabel
Phylogenetic relatedness predicts priority effects in nectar yeast communities.
@en
Phylogenetic relatedness predicts priority effects in nectar yeast communities.
@nl
P2860
P356
P1476
Phylogenetic relatedness predicts priority effects in nectar yeast communities.
@en
P2093
Melinda Belisle
P2860
P304
P356
10.1098/RSPB.2011.1230
P577
2011-07-20T00:00:00Z