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Bibliographic Details
Main Authors: Gjoni, Vojsava, Glazier, Douglas Stewart, Pomeranz, Justin P F, Junker, James R, Smith, Aria, Woelber, Jacob, Reynolds, Staci, Welch, Trevor, Wesner, Jeff S
Format: Artículo científico
Language:en
Published: Philosophical transactions of the Royal Society of London. Series B, Biological sciences 2026
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/41852218/
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author Gjoni, Vojsava
Glazier, Douglas Stewart
Pomeranz, Justin P F
Junker, James R
Smith, Aria
Woelber, Jacob
Reynolds, Staci
Welch, Trevor
Wesner, Jeff S
author_facet Gjoni, Vojsava
Glazier, Douglas Stewart
Pomeranz, Justin P F
Junker, James R
Smith, Aria
Woelber, Jacob
Reynolds, Staci
Welch, Trevor
Wesner, Jeff S
Gjoni, Vojsava
Glazier, Douglas Stewart
Pomeranz, Justin P F
Junker, James R
Smith, Aria
Woelber, Jacob
Reynolds, Staci
Welch, Trevor
Wesner, Jeff S
collection PubMed - marine biology
contents Temperature and predation alter metabolic scaling without changing the size-based community structure of freshwater macroinvertebrates. Gjoni, Vojsava Glazier, Douglas Stewart Pomeranz, Justin P F Junker, James R Smith, Aria Woelber, Jacob Reynolds, Staci Welch, Trevor Wesner, Jeff S Animals Predatory Behavior Body Size Temperature Invertebrates Food Chain Fishes Fresh Water Body size is a key trait that influences ecological processes such as metabolism, abundance and species interactions. While the metabolic theory of ecology (MTE) proposes a universal scaling of metabolic rate with body mass, recent evidence shows that this relationship is not fixed. Environmental factors like temperature and predation can alter the metabolic scaling exponent, potentially reshaping size distributions. However, most research has examined these patterns within individual species, leaving open questions about how environmental drivers affect scaling at the community level. To address this, we performed a mesocosm experiment manipulating both temperature and fish predator presence in freshwater macroinvertebrate communities. We found that warming altered metabolic rates in a predation-dependent way: without fish, metabolic rates increased in large individuals but decreased in small individuals, whereas the opposite occurred with fish present. This suggests that larger individuals reduce their baseline metabolic rates under predation risk, especially at higher temperatures. Interestingly, the slope of the community size distribution remained stable across treatments, indicating that shifts in metabolic scaling occurred independently of changes in size structure. Together, these findings highlight the environmental sensitivity of metabolic scaling and suggest that links between metabolism scaling and size distributions may be more complex than MTE predicts. This article is part of the theme issue 'Embracing variability in comparative physiology: why it matters and what to do with it'.
format Artículo científico
id pubmed_41852218
institution PubMed
language en
publishDate 2026
publisher Philosophical transactions of the Royal Society of London. Series B, Biological sciences
record_format pubmed
spellingShingle Temperature and predation alter metabolic scaling without changing the size-based community structure of freshwater macroinvertebrates.
Gjoni, Vojsava
Glazier, Douglas Stewart
Pomeranz, Justin P F
Junker, James R
Smith, Aria
Woelber, Jacob
Reynolds, Staci
Welch, Trevor
Wesner, Jeff S
Animals
Predatory Behavior
Body Size
Temperature
Invertebrates
Food Chain
Fishes
Fresh Water
Temperature and predation alter metabolic scaling without changing the size-based community structure of freshwater macroinvertebrates. Gjoni, Vojsava Glazier, Douglas Stewart Pomeranz, Justin P F Junker, James R Smith, Aria Woelber, Jacob Reynolds, Staci Welch, Trevor Wesner, Jeff S Animals Predatory Behavior Body Size Temperature Invertebrates Food Chain Fishes Fresh Water Body size is a key trait that influences ecological processes such as metabolism, abundance and species interactions. While the metabolic theory of ecology (MTE) proposes a universal scaling of metabolic rate with body mass, recent evidence shows that this relationship is not fixed. Environmental factors like temperature and predation can alter the metabolic scaling exponent, potentially reshaping size distributions. However, most research has examined these patterns within individual species, leaving open questions about how environmental drivers affect scaling at the community level. To address this, we performed a mesocosm experiment manipulating both temperature and fish predator presence in freshwater macroinvertebrate communities. We found that warming altered metabolic rates in a predation-dependent way: without fish, metabolic rates increased in large individuals but decreased in small individuals, whereas the opposite occurred with fish present. This suggests that larger individuals reduce their baseline metabolic rates under predation risk, especially at higher temperatures. Interestingly, the slope of the community size distribution remained stable across treatments, indicating that shifts in metabolic scaling occurred independently of changes in size structure. Together, these findings highlight the environmental sensitivity of metabolic scaling and suggest that links between metabolism scaling and size distributions may be more complex than MTE predicts. This article is part of the theme issue 'Embracing variability in comparative physiology: why it matters and what to do with it'.
title Temperature and predation alter metabolic scaling without changing the size-based community structure of freshwater macroinvertebrates.
topic Animals
Predatory Behavior
Body Size
Temperature
Invertebrates
Food Chain
Fishes
Fresh Water
url https://pubmed.ncbi.nlm.nih.gov/41852218/