Disturbance and trajectory of change in a stream fish community over four decades.

Communities can change gradually or abruptly, and directionally (to an alternate state) or non-directionally. We briefly review the history of theoretical and empirical perspectives on community change, and propose a new framework for viewing temporal trajectories of communities in multivariate space. We used a stream fish dataset spanning 40 years (1969-2008) in southern Oklahoma, USA, emphasizing our own 1981-2008 collections which included well-documented, extreme drought and flood events, to assess dynamics of and environmental factors affecting the fish community. We evaluated the trajectory of the Brier Creek community in multivariate space relative to trajectories in 27 published studies, and for Brier Creek fish, tested hypotheses about gradual versus event-driven changes and persistence of shifts to alternate states. Most species were persistent, qualitatively, across the four decades, but varied widely in abundance, with some having unusually strong reproduction after extreme droughts. The community had an early period of relatively gradual and directional change, but greater displacement than predicted at random after two consecutive extreme droughts midway through the study (1998 and 2000). But, the community subsequently returned toward its former state in the last decade. This fish community is characterized by species that are tolerant of environmental extremes, and have life history traits that facilitate population recovery. The community appears "loosely stable" about a long-term average condition, but the impacts of the two consecutive droughts were substantial, and may foretell future dynamics of this or other communities in a changed global climate if disturbance events become more frequent or severe.

Woody plant encroachment into grasslands: spatial patterns of functional group distribution and community development.

Woody plant encroachment into grasslands has been globally widespread. The woody species invading grasslands represent a variety of contrasting plant functional groups and growth forms. Are some woody plant functional types (PFTs) better suited to invade grasslands than others? To what extent do local patterns of distribution and abundance of woody PFTs invading grasslands reflect intrinsic topoedaphic properties versus plant-induced changes in soil properties? We addressed these questions in the Southern Great Plains, United States at a subtropical grassland known to have been encroached upon by woody species over the past 50-100 years. A total of 20 woody species (9 tree-statured; 11 shrub-statured) were encountered along a transect extending from an upland into a playa basin. About half of the encroaching woody plants were potential N2-fixers (55% of species), but they contributed only 7% to 16 % of the total basal area. Most species and the PFTs they represent were ubiquitously distributed along the topoedaphic gradient, but with varying abundances. Overstory-understory comparisons suggest that while future species composition of these woody communities is likely to change, PFT composition is not. Canonical correspondence analysis (CCA) ordination and variance partitioning (Partial CCA) indicated that woody species and PFT composition in developing woody communities was primarily influenced by intrinsic landscape location variables (e.g., soil texture) and secondarily by plant-induced changes in soil organic carbon and total nitrogen content. The ubiquitous distribution of species and PFTs suggests that woody plants are generally well-suited to a broad range of grassland topoedaphic settings. However, here we only examined categorical and non-quantitative functional traits. Although intrinsic soil properties exerted more control over the floristics of grassland-to-woodland succession did plant modifications of soil carbon and nitrogen concentrations, the latter are likely to influence productivity and nutrient cycling and may, over longer time-frames, feed back to influence PFT distributions.