Longitudinal patterns of metabolism in a southern Appalachian river

McTammany, Matthew E.; Webster, Jackson R.; Benfield, E. F.; Neatrour, Matthew A.

doi:10.2307/1468267

Cited by 71 publications

(55 citation statements)

References 46 publications

(79 reference statements)

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“…For example, a key prediction of the river continuum concept is that GPP/ER should change in a predictable manner from the headwaters to the lower reaches of natural river systems (Vannote et al 1980). This prediction has been tested in many locations and generally has been supported by data (Table 2; Naiman 1983, Bott et al 1985, Chessman 1985, Naiman et al 1987, Minshall et al 1992, McTammany et al 2003, although some fundamental differences have been seen in grassland/prairie systems (Wiley et al 1990, Young andHuryn 1996) and in rivers with strong floodplain connections (Junk et al 1989, Meyer andEdwards 1990). Thus, metabolic rates at potentially impacted sites should be compared with rates measured at (more) pristine sites that are characterized by similar stream order and size.…”

Section: Review Of Factors Controlling River Metabolismmentioning

confidence: 90%

“…The 2 nd approach compares values at test sites with Comments References GPP light limited, but not in grassland (P/R high) Junk et al 1989, Meyer and Edwards 1990, Wiley et al 1990, Young and Huryn 1996 P/R decreases downstream in grassland Young and Huryn 1996 Where strong floodplain connection, high organic input and ER (P/R,,1) Naiman 1983, Bott et al 1985, Chessman 1985, Naiman et al 1987, Junk et al 1989, Meyer and Edwards 1990, Minshall et al 1992, McTammany et al 2003 Algal biomass higher, GPP sometimes higher Flecker and Townsend 1994, Huryn 1998, Biggs et al 2000 Mainly based on the amount of light reaching the riverbed; affected by season, cloud cover, canopy cover, and turbidity Naiman 1983, Bott et al 1985, 2006, Webster et al 1995, Hill et al 2001, Acuñ a et al 2004, Ortiz-Zayas et al 2005, McTammany et al 2007 Only weak evidence Phinney and McIntire 1965, Bott et al 1985, Hill and Gardner 1987, Hedin 1990, Howarth et al 1992, Webster et al 1995, DeNicola 1996, Sinsabaugh 1997, Hill et al 1998, 2002 More organic matter Hedin 1990, Hill et al 1998 Algal production higher on large stable particles Rosenfeld and Roff 1991, Rier and King 1996, Biggs et al 2001…”

Section: Relationships Of Functional Measures To Ecosystem Healthmentioning

confidence: 99%

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Organic matter breakdown and ecosystem metabolism: functional indicators for assessing river ecosystem health

Young

Matthaei

Townsend

2008

Journal of the North American Benthological Society

378

364

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Abstract. River health monitoring traditionally has made use of structural measurements (water quality or taxonomic composition of aquatic organisms). We argue that a more complete assessment of river health should include functional metrics, such as rates of organic matter decomposition and ecosystem metabolism. Leaf breakdown links the characteristics of riparian vegetation with the activity of both aquatic invertebrates and microbial organisms and is affected by natural and human-induced variation in a wide range of environmental factors. Measurement of leaf breakdown is relatively simple and has modest equipment requirements. River metabolism (gross primary productivity and ecosystem respiration) measures the rates of production and use of organic C in river ecosystems as a whole, providing a direct estimate of the food base that determines life-supporting capacity. Metabolism measurements require more sophisticated equipment than do measurements of leaf breakdown, but improvements in technology have made metabolism measurements relatively easy. We review the factors that influence leaf breakdown and river metabolism and pay particular attention to the effects of human-induced environmental stressors. We also describe how measurements can be standardized and suggest criteria for interpreting functional measures in terms of river ecosystem health. Last, we consider the strengths and weaknesses of both methods as functional measures and provide recommendations for their use as biomonitoring tools.

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Section: Review Of Factors Controlling River Metabolismmentioning

confidence: 90%

Section: Relationships Of Functional Measures To Ecosystem Healthmentioning

confidence: 99%

Organic matter breakdown and ecosystem metabolism: functional indicators for assessing river ecosystem health

Young

Matthaei

Townsend

2008

Journal of the North American Benthological Society

378

364

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“…The importance of downstream heterotrophy has been confirmed for whole-river metabolism measured over shorter periods of time (Minshall et Our results also provide some support for the idea that autochthonous production could be an important food source in these large rivers, at least at some times of the year, given that we did regularly detect positive rates of GPP. Food webs of some large rivers are more reliant upon autochthonous C sources than would be expected (Thorp and Delong 2002), and GPP can increase with river size (McTammany et al 2003). We did not analyze relationships between metabolism and secondary consumer production, but during winter and early spring significant GPP occurred in both rivers.…”

Section: Metabolism and Seasonalitymentioning

confidence: 99%

Abiotic controls and temporal variability of river metabolism: multiyear analyses of Mississippi and Chattahoochee River data

et al. 2013

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Abstract. Whole-ecosystem metabolism is an important indicator of the role of organic matter, C cycling, and trophic structure in rivers. Ecosystem metabolism is well studied in small streams, but less is known about metabolism in large rivers. We estimated daily whole-ecosystem metabolism over 2 y for 1 site each at the Mississippi and Chattahoochee Rivers in the USA to understand factors influencing temporal patterns of ecosystem metabolism. We estimated rates of gross primary production (GPP), community respiration (CR), and net ecosystem production (NEP) with a curve-fitting approach with publicly available discharge (Q), dissolved O 2 , temperature, and photosynthetically active radiation (PAR) data. Models were run for week-long blocks, and power analyses suggested that rates should be established at least once for each 10-wk period throughout the year to characterize annual rates of metabolism accurately in these 2 rivers. We analyzed weekly rates averaged over

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“…Numerous studies utilizing changes in DO and/or CO 2 to estimate primary production and stream metabolism have been conducted in a variety of environmental settings (Odum 1956;Hall 1972;Bott et al 1978Bott et al , 1985Bott et al , 2006Wiley et al 1990;Marzolf et al 1994;Young and Huryn 1996;Mulholland et al 1997;Biggs et al 1999;Young and Huryn 1999;Hall and Tank 2003;McTammany et al 2003;Houser and Mulholland 2005). Similarly, a small number of studies have analyzed the effect of increasing nitrate concentrations on the efficiency of biotic uptake and denitrification of nitrate, as related to ecosystem photosynthesis and respiration (Peterson et al 2001;Duff et al 2008;Mulholland et al 2008).…”

Section: Introductionmentioning

confidence: 99%

The relative influence of nutrients and habitat on stream metabolism in agricultural streams

Frankforter

Weyers

Bales

et al. 2009

Environ Monit Assess

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Stream metabolism was measured in 33 streams across a gradient of nutrient concentrations in four agricultural areas of the USA to determine the relative influence of nutrient concentrations and habitat on primary production (GPP) and respiration reach. When data for all study areas were combined, there were no statistically significant relations between gross primary production or community respiration and any of the independent variables. However, significant regression models were developed for three study areas for GPP (r 2 = 0.79-0.91) and CR-24 (r 2 = 0.76-0.77). Various forms of nutrients (total phosphorus and area-weighted total nitrogen loading) were significant for predicting GPP in two study areas, with habitat variables important in seven significant models. Important physical variables included light availability, precipitation, basin area, and in-stream habitat cover. Both benthic and seston chlorophyll were not found to be important explanatory variables in any of the models; however, benthic ash-free dry weight was important in two models for GPP.

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Longitudinal patterns of metabolism in a southern Appalachian river

Cited by 71 publications

References 46 publications

Organic matter breakdown and ecosystem metabolism: functional indicators for assessing river ecosystem health

Organic matter breakdown and ecosystem metabolism: functional indicators for assessing river ecosystem health

Abiotic controls and temporal variability of river metabolism: multiyear analyses of Mississippi and Chattahoochee River data

The relative influence of nutrients and habitat on stream metabolism in agricultural streams

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