Temporal dynamics of bird community composition: an analysis of baseline conditions from long-term data

Determining how ecological communities will respond to global environmental change remains a challenging research problem. Recent meta-analyses concluded that most communities are undergoing compositional change despite no net change in local species richness. We explored how species richness and composition of co-occurring plant, grasshopper, breeding bird and small mammal communities in arid and mesic grasslands changed in response to increasing aridity and fire frequency. In the arid system, grassland and shrubland plant and breeding bird communities were undergoing directional change, whereas grasshopper and small mammal communities were stable. In the mesic system, all communities were undergoing directional change regardless of fire frequency. Despite directional change in composition in some communities, species richness of all communities did not change because compositional change resulted more from reordering of species abundances than turnover in species composition. Thus, species reordering, not changes in richness, explains long-term dynamics in these grass and shrub dominated communities.

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“…) or slow temporal changes occurring over decades (Kampichler et al . ). Grasshoppers, which include C 3 and C 4 specialists (Engel et al .…”

Section: Discussionmentioning

confidence: 99%

Species reordering, not changes in richness, drives long‐term dynamics in grassland communities

2017

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“…The majority of community composition studies are of short duration (1-2 yr; Marzluff et al 2001, Kampichler et al 2014, but a growing body of longitudinal studies of urban biotic communities is emerging. A recent review found 34 studies of urban birds that encompass five or more years of sampling (Fidino and Magle 2017).…”

Section: Introductionmentioning

confidence: 99%

The more things change: species losses detected in Phoenix despite stability in bird–socioeconomic relationships

et al. 2019

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The science of urban ecology has increasingly grappled with the long‐term ramifications of a globally urbanized planet and the impacts on biodiversity. Some researchers have suggested that places with high species diversity in cities simply reflect an extinction debt of populations that are doomed to extinction but have not yet disappeared. The longitudinal studies conducted to date have found species composition shifting with urbanization but have not always documented continued species extirpations post‐urbanization. We used long‐term monitoring data on birds from the greater metropolitan area of Phoenix, Arizona, to measure changes in residential bird communities, species–habitat relationships, and human perceptions of bird species diversity over a five‐year period. Bird richness, occupancy, and abundance decreased, as did the percentage of respondents satisfied with bird variety in their neighborhoods. As in previous analyses for this region, we found that desert specialist species were associated with neighborhoods with xeric landscaping consisting of gravel groundcover, and drought‐tolerant, desert‐adapted vegetation. These species were also found in neighborhoods with high per capita income rates and lower percentages of renters and Hispanic/Latinx residents. Non‐native species were positively associated with neighborhoods containing mesic yards with grass and other water‐intensive vegetation. The proportions of yards in our surveyed neighborhoods with these distinct landscaping types likewise remained relatively stable over five‐year period. Although habitat–species relationships remained unchanged, we detected significant loss of species across the sampling period. Declines were not confined to desert specialist species but included generalist and invader species as well. The parallel reduction in residents’ satisfaction suggests that people perceive some aspect of this environmental degradation. Further investigation into the mechanisms underlying these species losses may reveal options for retaining some desert specialist species, and the uniqueness they contribute to urban fauna.

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“…Similar to a RDA, the first canonical AEM axis represents the dominant pattern in the data and the second AEM axis the next most important pattern. In essence, AEM modelling facilitates the identification of different temporal scales (i.e., from seasonal, to decadal to millennial scales) in complex time series data (Baho, Futter, Johnson, & Angeler, ) and has been widely applied to different ecosystems and taxa (invertebrates: Angeler, Allen, & Johnson, ; birds: Kampichler et al, ; paleolimnology: Spanbauer et al, ; microscopy‐based phytoplankton: Angeler, Allen, & Johnson, ; insects: Blanchet et al, ), well supporting its explanatory power. The fitted site scores (i.e., linear combination of explanatory variables; lc scores) of the first and second canonical AEM axis were plotted along time to identify the temporal variability of communities at different temporal scales.…”

Section: Methodsmentioning

confidence: 99%

Multifaceted aspects of synchrony between freshwater prokaryotes and protists

2019

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Community composition of freshwater prokaryotes and protists varies through time. Few studies contemporarily investigate temporal variation of these freshwater communities for more than 1 year. We compared the temporal patterns of prokaryotes and protists in three distinct habitats for 4 years (2014–2017) in Lake Tovel, a cold‐water lake. This lake showed a marked temperature increase in 2017 linked to altered precipitation patterns. We investigated whether microbial communities reflected this change across habitats and whether changes occurred at the same time and to the same extent. Furthermore, we tested the concept of hydrological year emphasizing the ecological effect of water renewal on communities for its explanatory power of community changes. Microbe diversity was assessed by Illumina sequencing of the V3–V4 hypervariable region of the 16S rRNA gene and 18S rRNA gene, and we applied co‐inertia analysis and asymmetric eigenvector maps modelling to infer synchrony and temporal patterns of prokaryotes and protists. When considering community composition, microbes were invariable in synchrony across habitats and indicated a temporal gradient linked to decreasing precipitation; however, when looking at temporal patterns, the extent of synchrony was reduced. Small‐scale patterns were similar across habitats and microbes and linked to seasonally varying environmental variables, while large‐scale patterns were different and partially linked to an ecosystem change as indicated by increasing water transparency and temperature and decreasing dissolved oxygen. Our advanced statistical approach outlined the multifaceted aspect of synchrony when linked to community composition and temporal patterns.

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Temporal dynamics of bird community composition: an analysis of baseline conditions from long-term data

Cited by 23 publications

References 47 publications

Species reordering, not changes in richness, drives long‐term dynamics in grassland communities

Species reordering, not changes in richness, drives long‐term dynamics in grassland communities

The more things change: species losses detected in Phoenix despite stability in bird–socioeconomic relationships

Multifaceted aspects of synchrony between freshwater prokaryotes and protists

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