Abstract
Few studies try to explain the effects in tropical lotic ecosystems of an increase in water temperature on the shredding activity of invertebrate shredders, particularly in association with the quality of the leaf litter and the degree of litter conditioning. Therefore, the aims of this study were as follows: i) to better understand how this key invertebrate shredder group affects the decomposition of different species of leaf litter under gradual increases in temperature and microbial conditioning; and ii) to verify the possible consequences on leaf mass loss (LML). Three species of leaf litter were used in two experiments. In experiment I, the litters of three species (Protium spruceanum, Richeria grandis and Inga laurina) at three conditioning levels (1, 7, 14 days) were tested under five different temperatures (20, 22, 24, 26 and 28°C). In experiment II, the leaf litters of three species were used, without conditioning, under four temperatures (20, 22, 26 and 27°C). The shredding performed by Phylloicus sp. was largely dependent on the lignin and cellulose concentrations in each leaf species, independent of conditioning. The presence or absence of conditioning may cause the shredders to use different energy compensation strategies in response to the temperature increases.
Highlights
In lotic ecosystems, the source region displays heterotrophic metabolism due to both the presence of well-developed marginal vegetation and the low light penetration (Vannote, Minshall, Cummins, Sedell, & Cushing, 1980)
In the experiment I (SPANOVA, F118,2 = 18.244, p < 0.001) and II, we found that the leaf mass loss was significantly influenced by the different leaf litter species studies
In the experiment I, the leaf mass loss of I. laurina was significantly lower than those of R. grandis or P. spruceanum, whereas R. grandis was significantly higher than P. spruceanum (Table 1)
Summary
The source region displays heterotrophic metabolism due to both the presence of well-developed marginal vegetation and the low light penetration (Vannote, Minshall, Cummins, Sedell, & Cushing, 1980). The input of organic matter from allochthonous origins constitutes the primary source of energy (Cummins, Wilzbach, Gates, Perry, & Taliaferro, 1989; Graça, 1993). In this context, the decomposition of leaf matter becomes fundamental for the functioning of these ecosystems. The invertebrate shredders present in these lotic environments possess jaws capable of transforming coarse particulate organic matter (CPOM) in fine particulate organic matter (FPOM) (Merrit & Cummins, 1996). This shredding ability allows for leaf matter to be used as food and case-building to be constructed dorsoventrally, contributing to the leaf shredding process within the aquatic trophic chain (Wantzen & Wagner, 2006; Wiggins, 1996)
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