Habitat Use of Fish Communities in A Virginia Stream System

Fish habitat use during summer was examined at micro- and meso-levels, to determine species associations in the upper Roanoke River watershed, Virginia. Based on multivariate-mesohabitat analysis and examination of mean microhabitat use, seven habitat-use guilds were apparent. These included four rheophilic (fast-riffle, riffle/run, fast-generalist, and shallow-rheophilic) and three limnophilic guilds (pool/run, open-pool, and pool-cover) that were reasonably robust across two river segments and two years. Although simple-hydraulic, bottom-topographic, and turbulence variables all segregated fish habitat-use guilds, turbulence variables were redundant with simple-hydraulic variables, substratum use by limnophilic fishes was related to availability, and only one guild consistently selected high cover levels. At the family level, suckers, darters, and especially minnows were notable for occupying several habitat-use guilds, because of species differences in habitat preferences. Such formulation of guilds can simplify habitat-impact analyses in biodiverse, warmwater streams, via focus on habitat needs of guilds rather than on individual species.     

Development of an Index of Biotic Integrity Based on Fish Communities to Assess the Effects of Rural and Urban Land Use on a Stream in Southeastern Brazil

A fish‐based Index of Biotic Integrity (IBI) was adapted for use in a stream of the heavily impacted Piracicaba River basin in southeastern Brazil. The influences of land use (mainly sugar‐cane crops) and an urban area on the fish community were investigated at ten sites along a 17 km‐long stream during the dry and rainy season. The IBI varied with the season and location along the stream, reflecting differences between the agricultural and urban sites, which were more pronounced during the dry season. The final index was positively correlated with a Habitat Quality Index (dry season) but not with a Water Quality Index. The results can be viewed as a tool for assessing and monitoring the ecological health of streams in this watershed. (© 2011 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

A Large-scale Comparative Analysis of Riffle and Pool Fish Communities in an Upland Stream System

Fishes were sampled in riffle and pool habitats at 74 upland localities in the Little River system, southeastern Oklahoma and southwestern Arkansas, U.S.A. I asked how these two habitat-defined communities differed with regard to species abundance and incidence patterns, and how these differences varied along othree environmental gradients: elevation, stream gradient, and stream size. Riffle and pool communities showed distinct and significant differences when ordinated in multivariate space defined by species abundance patterns. Sites with similar pool communities did not have similar riffle communities, and riffle and pool communities responded to environmental gradients in different ways. Elevation was the best predictor of pool community structure, whereas stream size was the best predictor of riffle communities. Overall, riffle habitats had fewer species than pool habitats and formed significant subsets of pool communities at 12 of 74 sites. I predicted that at small stream localities where riffles were unstable, riffle species would form subsets of the pool species communities, and both community types should show high similarities. The presence of faunal subsets was not associated with stream size, but faunal similarities were significantly higher at small stream localities. At the species level, 14 species were significantly associated with pool habitats, while only two were associated with riffle habitats. Riffle and pool communities, although linked by a continuous habitat gradient at the local scale, responded differently to large-scale environmental gradients. Local differences between these communities were predictable based on stream size.     

Stream Fish Communities and Environmental Correlates in the Red River of the North, Minnesota and North Dakota

In the Red River of the North (Red River) drainage in Minnesota and North Dakota, there are strong east–west hydrological and chemical environmental gradients. Historical fish surveys indicated the presence of species with both widespread and restricted distributions, leading to unique fish communities in several streams. To determine the important physiochemical correlates of stream fish community structure, we partitioned 25 streams into 46 large reaches by ecoregion classification. The reaches were then characterized from sampling during 1962–1994 by the frequency of occurrence of 76 fish species and 12 landscape-level hydrologic and chemical factors. In canonical correspondence analysis, the first two axes explained 56% of the species–environment relationship, and indicated that coefficient of variation of mean monthly discharge, minimum discharge in May, and residue were the most important factors correlated with fish community composition. Important covariates of residue were specific conductance, dissolved sulfate, and total hardness of waters. Certain catostomids, Hypentelium nigricans and Moxostoma valenciennesi, cyprinids, Notropis anogenus and N. texanus, ictalurids, Ameiurus natalis, and percids, Etheostoma caeruleum and E. microperca, all correlated highly with habitats characterized by low-flow variability, high discharges, and low residue, conductivity, and hardness. Reaches with these characteristics included the Otter Tail River in the Red River Valley, North Central Hardwoods (NCH), and the Northern Minnesota Wetlands (NMW) ecoregions; the Pelican River in the NCH ecoregion; and the Red Lake River in the NMW ecoregion. The results of this analysis support the hypothesis that regional environmental conditions are important in structuring fish communities in northern streams. As conditions are altered in the future by anthropogenic factors at the landscape scale, our exploratory multivariate model can be used to predict fish community response and support conservation efforts aimed at preserving or restoring unique and/or rare small fishes in the Red River and other, similar stream systems.     

Recovery in Diversity of Fish and Invertebrate Communities Following Remediation of a Polluted Stream: Investigating Causal Relationships

Spatial and temporal responses of biota to anthropogenic disturbance were measured over a 15 year period in a contaminated stream undergoing remediation and recovery. Along the spatial gradient of the stream, levels of contaminants decreased downstream along with improved responses of instream biota at several levels of biological organization. Recovery of the biota in this stream over the 15 year study period is demonstrated by the temporal relationships between levels of decreasing contaminants and the concomitant responses of the periphyton, macroinvertebrate, and fish communities and changes in the various bioindicators of individual fish health. Decreases in contaminants over a temporal scale were followed closely by an improvement in physiological and organismal-level indicators, increases in the diversity of macroinvertebrate and fish communities, and rapid increases in the chlorophyll a biomass and photosynthesis rate of the periphyton community. These results emphasize that field studies designed to assess and evaluate the effectiveness of restoration activities on stream recovery should incorporate a variety of response endpoints ranging from sensitive and short-term responses to long-term but ecological relevant indicators of change. The close spatial and temporal relationships observed between changes in physicochemical factors and positive responses in various components of the stream biota over the 15-year study period suggest a strong cause and effect relationship between remediation activities and stream recovery. Understanding causal relationships and the mechanistic processes between environmental stressors, stress responses of biota, and the recovery process is important in the effective management and restoration of aquatic ecosystems. An erratum to this article is available at .     

Use of Tropical Dry Forests and Agricultural Areas by Neotropical Bird Communities

Agricultural activities represent a global threat to biodiversity, yet little is known about the relative importance of different agricultural land uses in relation to their wildlife communities. We explored bird community structure, diversity, and composition in a landscape dominated by primary tropical dry forest, and in three agricultural systems (i.e., tree orchards, herbaceous cropfields, cattle pastures) to evaluate the way in which birds use different habitats within the landscape. Tropical dry forests had the highest species richness and community evenness, although the bird community in tree orchards was also relatively species rich and even. Cattle pastures had more bird species than cropfields but both habitats were comparatively species poor with low evenness. Our results are related to habitat structure and the spatial location of sites within the landscape matrix. Based on our observations, we recommend including native tree species within agricultural systems and surrounding areas to provide additional resources for birds. Finally, we suggest promoting natural recruitment of native trees and shrubs within cattle pastures to provide suitable habitat for species that use tropical dry forest plants. Abstract in Spanish is available at http://www.blackwell‐synergy.com/loi/btp .     

Use of Biochemical Endpoints to Determine Relationships between Contaminants and Impaired Fish Health in a Freshwater Stream

Bayou Bartholomew is a low gradient stream predominantly influenced by agricultural inputs and stormwater discharge from the urban areas of Pine Bluff, Arkansas. Preliminary studies indicated induction of hepatic cytochrome P450 1A protein (CYP1A) and CYP1A-catalyzed enzyme activity (ethoxyresorufin O-deethylase-EROD) in several fish species collected in the waterway, which meanders through residential areas of Pine Bluff, and forested regions in the outskirts of the city. Largemouth bass (Micropterus salmoides) showed CYP1A repression and a lack of correlation between CYP1A and EROD activity. In addition, hepatic heme oxygenase activity was elevated in several species and demonstrated an inverse relationship with hepatic CYP1A. Hepatic metallothionein was unchanged in any species collected from these locations. Four years after this evaluation, sediments were collected and analyzed for agents that could be mechanistically consistent with the biochemical responses observed. Utilizing seven criteria for causality, these data indicated that PCBs appear to be at least one group of agents responsible for the biological effects observed in fish species from the upper Bayou Bartholomew. While this supports causality under the criteria, further studies in this waterway would strengthen the relationship between this class of compound and the effects observed in resident fish species.     

Production and Resource Use Efficiencies in N- and P-Limited Tropical Forests: A Comparison of Responses to Long-term Fertilization

At two sites at the extreme ends of a soil development chronosequence in Hawaii, we investigated whether forest responses to fertilization on young soils were similar to those on highly weathered soils and whether the initial responses were maintained after 6–11 years of fertilization. Aboveground net primary production (ANPP) was increased by nitrogen (N) application at the 300-year-old site and phosphorus (P) application at the 4.1-million-year-old site, thus confirming earlier results and their designations as N- and P-limited forests. Along with ANPP, application of the limiting element consistently increased leaf area index (LAI), radiation conversion efficiency (RCE), and foliar and litter nutrient concentrations. Fertilization did not consistently alter N or P retranslocation from senescent leaves at either site, but a comparison with other sites on the chronosequence and with a common-garden study suggests that there is a genetic basis for low foliar and litter nutrients and higher retranslocation at infertile sites vs more fertile sites. N limitation appears to be expressed as limitation to carbon gain, with long leaf lifespans and high leaf mass per area. P limitation results in high P-use efficiency and disproportionally large increases in P uptake after fertilization; a comparison with other studies indicates large investments in acquiring and storing P. Although the general responses of ANPP, LAI, and RCE were similar for the two sites, other aspects of nutrient use differ in relation to the physiological and biogeochemical roles of the two elements. Received 2 June 2000; Accepted 4 April 2001.     

Restoration of the Kissimmee River: A Conceptual Model of Past and Present Fish Communities and Its Consequences for Evaluating Restoration Success

Efforts to restore fish communities of the Kissimmee River will require carefully defined criteria for assessing success. A goal of regaining communities mirroring those in the historical river may not be an appropriate target because the ecological conditions of the river before channelization are poorly known. The Kissimmee River is in a biogeographic region historically low in fish diversity, and no comparable rivers in that region remain substantially unaltered by human activity to permit their use as reference sites indicative of conditions in the Kissimmee before channelization. I propose alternative criteria for assessing restoration success emphasizing expectations for ecosystem function in similar floodplain rivers. Assessing ecosystem function will be less simple than assessing criteria such as fish condition or density of selected species. But criteria based solely on fish-population characteristics cannot be justified quantitatively. Information integrated from several levels of biotic organization (individuals, populations, communities, and systems) should be drawn upon in making conclusions about restoration success. I develop a conceptual model to outline aspects of ecosystem function that could serve as a basis for evaluation of the restoration of fish communities of the Kissimmee River. The model focuses on the dynamics of the flux of floodplain-channel nutrients and the movement of larvae, juvenile, and adult fishes and macroinvertebrates. The present community may be dominated more by species tolerant of low-oxygen conditions, such as gar and bowfin, than the restored community will be. I propose that nest sites may be the limiting recruitment success of substrate spawning species in the channelized river and that these species, including sunfish and large-mouth bass, will increase in abundance after restoration. Also, species relying on floodplain habitats, including sun-fish species, darters, and some minnows, may also increase in frequency with restoration of floodplain-channel hydro-logical conditions and habitats. The observation that no species are known to have disappeared from the Kissimmee River, and its relatively simple community structure compared to rivers of comparable size elsewhere, are encouraging for prospects of successful restoration.     

Comparative Environmental Assessment in the Studies of Benthic Diatom,Macroinvertebrate, and Fish Communities

Community response to environmental gradients operating at hierarchical scales was assessed in studies of benthic diatoms, macroinvertebrates and fish from 44 stream sites in the New York City watershed. Hierarchical cluster analysis (TWINSPAN) of diatoms and fish partitioned the study sites into four groups, i.e., acid streams, reservoir outlets and wetland streams, large eutrophic streams, and small eutrophic streams; macroinvertebrate TWINSPAN distinguished an additional group of silty eutrophic streams. The correspondence among the three assemblage TWINSPAN groupings was moderate, ranging from 51 to 57%. The similarity across the four major group types was the highest among large eutrophic stream and acid stream assemblages, and the lowest among small eutrophic stream assemblages. Stepwise discriminant function analysis revealed that environmental factors discriminated most effectively the diatom grouping and least effectively the fish grouping. The best environmental predictors for diatom and macroinvertebrate grouping were conductance and percent surface water, while population density was most powerful in separating the fish groups. Carbaryl was the only pesticide that correlated with macroinvertebrate grouping. Partial redundancy analyses suggested a differential dependence of freshwater communities on the scale of the environmental factors to which they respond. The role of small‐scale habitat and habitatland cover/land use interaction steadily increased across the diatom, macroinvertebrate, and fish assemblages, whereas the effect of large‐scale land cover/land use declined.     

The Use of Gait Transition Speed in Comparative Studies of Fish Locomotion

Physiological and biomechanical inquiries into the principlesof vertebrate locomotion require comparison among animals ofdifferent size, habitat and phyletic association. In designingcomparative studies of locomotion, a major challenge is to isolatethe effects of experimentally imposed variation from the confoundingeffects of variation in animal activity level associated withdifferences in scale and life history. For swimming vertebrates,traditional measures of speed used for comparison, includingsprint speed and critical swimming speed should in theory eachelicit similar efforts from different animals but have practicalshortcomings that can limit their usefulness. This paper presentsan alternative approach, adapted from the work of mammalianphysiologists, which controls for differences in relative activitylevel among swimming animals of different size and habitat throughcomparison at gait transition speeds. The method is illustratedwith examples from study of the teleost fish family Embiotocidae,whose members exhibit a distinct transition from exclusivelypectoral fin oscillation to combined pectoral and caudal finpropulsion with increasing swimming speed. The pectoral-caudalgait transition speed, or any percentage thereof, is shown tobe 'biomechanically equivalent for swimmers of different size.When this performance limit is expressed in terms of body lengthstraveled per unit time, a common normalization of swimming speed,it varies markedly across size and habitat within the family.This finding has the important implication that length specificspeeds may not induce comparable degrees of exercise from differentfishes, and thus kinematic and physiological comparisons atsuch speeds can yield misleading results. The comparative approachdescribed for pectoral fin swimmers, and the limitations oflength-specific speed, should be generally applicable to studiesof other swimming vertebrates.     

The Brain Collections of the Museum of Anthropology and Ethnography, University of Turin: Re-Evaluation and Scientific Investigation

The study of brain collections has played an important role in research on the Natural History of Man. Current knowledge on cerebral morphological evolution and development of the psyche, from non-human primates to Man, is the result of analyses of endocranial casts and brains collected in the nineteenth century from the various primate species dissected. This paper presents the brain collections of non-human and human primates housed in the Museum of Anthropology and Ethnography of the University of Turin put together in the early 1900s by A. Marro, father of Prof. Giovanni Marro, the founder of the Museum. These collections, which have required constant interventions aimed at their preservation and scientific re-evaluation, have undoubted historical interest and are essential to define Man, both biologically and culturally.     

Simulating the Long-term Response of Tropical Wet Forests to Fragmentation

In the coming decades, a large fraction of the world's tropical forests will be fragmented into remnants surrounded by secondary vegetation, land-use areas, or roads. It is important to develop integrative tools to monitor the evolution of these fragmented ecosystems. We used the individual-oriented and process-based forest growth simulator FORMIND2.0 to investigate the spatial and temporal effects on standing biomass and functional diversity of various intensities and patterns of fragmentation within a forest landscape. The simulator was calibrated for an old-growth wet forest in French Guiana, South America. We found that the standing biomass of forest remnants was reduced significantly compared to a similar area of nonfragmented forest. When fewer but larger remnants were created rather than many small ones, the total loss in biomass and the increase in the abundance of early-successional species were significantly reduced, confirming that edge effects dominate the functioning of forest remnants. We also performed simulations of secondary succession after the landscape had been abandoned. The simulated recovery time in those secondary forests depends on both the size of cleared area and the spatial pattern of the remnant forests. Received 30 January 2002; accepted 16 July 2002.     

The New History in an Old Museum: Creating the Past at Colonial Williamsburg

The New History in an Old Museum: Creating the Past at Colonial Williamsburg. Richard Handler and Eric Gable. Durham, NC: Duke University Press, 1997.260 pp.     

Subtle Land‐Use Change and Tropical Biodiversity: Dung Beetle Communities in Cerrado Grasslands and Exotic Pastures

Although many tropical savannas are highly influenced by humans, the patterns of biodiversity loss in these systems remain poorly understood. In particular, the biodiversity consequences of replacing native grasslands with exotic pastures have not been studied. Here we examine how the conversion of the native savanna grasslands affects dung beetle communities. Our study was conducted in 14 native (grassland: campo limpo), and 21 exotic (Urochloa spp. monoculture) pastures in Carrancas, Minas Gerais, Brazil. We collected 4996 dung beetle individuals from 66 species: 3139 individuals from 50 species in native pastures and 1857 individuals from 55 species in the exotic pastures. Exotic pastures had lower dung beetle richness, abundance and biomass than native pastures. Species composition between the two pasture types was significantly different and exotic pastures were dominated by few abundant species. Indicator species analysis detected 16 species indicators of native pastures and three of exotic pastures, according to relative abundance and frequency in each pasture system. Our results show that the conversion of native pastures to exotic pastures leads to a predictable loss of local species richness, increasing dominance and changes in species composition. These results highlight the importance of maintaining native pastures in the Cerrado agro‐pastoral landscape. Abstract in Portuguese is available at http://www.blackwell‐synergy.com/loi/btp .