Abstracts

Are sugarcane leaf-detritus well colonized by aquatic macroinvertebrates?

Detritos foliares de cana-de-açúcar são bem colonizados por macroinvertebrados aquáticos?

Luciene Aparecida Leite-Rossi; Susana Trivinho-Strixino

Departamento de Hidrobiologia, Universidade Federal de São Carlos – UFSCar, Rod. Washington Luiz, Km 235, CEP 13565-905, São Carlos, SP, Brazil. e-mail: luciene.rossi@yahoo.com.br, strixino@power.ufscar.br

ABSTRACT

AIM: The aim was to compare the kinetics of decomposition and the colonization of leaf litter of two plant species, the native Talauma ovata (pinha-do-brejo) and the exotic Saccharum officinarum (sugarcane), by aquatic macroinvertebrates;

METHODS: From each substrate, three recipients of colonization were taken from a stream, and the specimens identified to the lowest taxonomic level on days 7, 15, 34, 44, 61 and 75. The debris was weighed at the beginning and end of the experiment and determined their cell wall fractions;

RESULTS: The coefficients of mineralization indicated higher velocity decay of organic matter refractory in T. ovata. There was no difference in taxonomic structure of macroinvertebrates, between the two substrates, but the community exhibited distinct functional feeding groups in the peak of colonization, with a greater number of shredders in T. ovata. The successive states of decomposition of the two plant detritus showed distinct macroinvertebrate densities;

CONCLUSIONS: The amount and state of the plant biomass were important factors influencing the density and diversity of the macroinvertebrate fauna throughout the process of organic decomposition.

Keywords: Chironomidae, shredders, Saccharum officinarum, Talauma ovata, riparian forest.

RESUMO

OBJETIVO: O principal objetivo foi comparar a cinética de decomposição e a colonização de detritos de duas espécies de plantas: a nativa Talauma ovata (pinha-do-brejo) e a exótica Saccharum officinarum (cana-de-açúcar) por macroinvertebrados;

MÉTODOS: Para cada substrato, três recipientes de colonização foram retirados de um riacho e os espécimes identificados até o menor nível taxonômico nos dias 7, 15, 34, 44, 61 e 75. Os detritos foram pesados no início e ao final do experimento e determinadas suas frações de parede celular;

RESULTADOS: Os coeficientes de mineralização indicaram maior velocidade de decaimento da matéria orgânica refratária nos detritos de T. ovata. Os dois substratos não apresentaram diferenças na estrutura taxonômica da comunidade, mas apresentaram agrupamentos funcionais distintos no pico de colonização, com maior número de fragmentadores em T. ovata. Os diferentes estados de decomposição dos dois tipos de detritos vegetais apresentaram densidades faunísticas distintas;

CONCLUSÕES: A quantidade e estado da biomassa vegetal são fatores importantes que influenciam a densidade e diversidade da fauna de macroinvertebrados durante o processo de decomposição orgânica.

Palavras-chave: Chironomidae, fragmentadores, Saccharum officinarum, Talauma ovata, vegetação ripária.

1. Introduction

Riparian vegetation is a transition zone between aquatic and terrestrial ecosystems (Richardson et al., 2007) and has an important role in the functioning of ecosystem processes and maintenance of the characteristics of water bodies (i.e, hydraulic channel morphology, water quality, speed and residence time of water, stream bed and limnological variables) (Naiman and Décamps, 1997, Tabacchi et al., 2000; Francis, 2006; Richardson et al., 2007). One of the most important functions is the supply of organic matter in the form of plant detritus to the water body. In low-order streams, the plant remains are the main source of energy in the aquatic system (Trevisan and Hepp, 2007) since the primary production is limited by the shading vegetation itself (Abelho, 2001, Gonçalves Junior et al. 2006; Graça and Canhoto, 2006). In many cases, the leaf-detritus are the most abundant fraction of allochthonous particulate organic matter (Gonçalves Junior et al., 2006) in these systems and its decomposition is an important process to input organic carbon on the stream.

The decomposition of this leaf litter in streams is a process that depends on the attributes of the plant material and the intrinsic characteristics of the stream, each of which affects the formation of biofilm on detritus, microbial decomposition and macroinvertebrate colonization (Wright and Covich, 2005; Leroy and Marks, 2006; Trevisan and Hepp, 2007).

The stages of the decomposition of leaf-detritus, the analysis of conditioning factors and participation of aquatic biota in this process have been analysed and discussed by several authors (Mason, 1980; Gessner et al., 1999; Cunha-Santino and Bianchini Junior, 2000, 2006; Abelho, 2001; Graça, 2001).

The role of aquatic macroinvertebrates is recognized for its possible association with the mechanical process of fragmentation (Wright and Covich, 2005; Gonçalves Junior et al., 2006; Wantzen and Wagner, 2006, Tanaka et al., 2006), which tends to increase the contact surface available for the action of microorganisms. However, the contribution of macroinvertebrates in tropical streams to this process is not yet fully elucidated because according to Moulton et al. (2010) the shredders are in low abundance and proportion in these systems. It is known that plant remains are potential sources of food and can serve as shelter for these fauna or there may be an interaction between these factors (Dudgeon and Wu, 1999; Graça, 2001). Therefore the presence of riparian vegetation is a very important resource for the macroinvertebrate fauna.

Freshwater systems and riparian forest are subject to degradation in different places (Tockner and Stanford, 2002). It is increasingly recognized that the rehabilitation and recovery of these systems are essential for the conservation of biodiversity and maintenance of their proper role in the ecosystem (Kyle and Leishman, 2009). However, inappropriate agricultural practices have led to the loss of native vegetation, including riparian forest, and its replacement by monocultures of economic interest (Corbi and Trivinho-Strixino, 2006) altering markedly the quality and quantity of allochthonous matter and, consequently, the communities and functional processes in lotic systems (Graça, 2001; Corbi and Trivinho-Strixino, 2008; Beltrão et al. 2009; Casatti et al. 2009; Pramual and Kuvangkadilok, 2009, Zhang et al., 2010).

The cultivation of sugarcane has expanded in Brazil in recent years, mainly in the Southeast and Northeast regions, as a result of the use of alcohol as an automotive fuel, with a view to diversifying sources of energy and consequently reducing dependence on fossil fuels (ANEEL, 2008). The consequences of replacing the native vegetation with this type of monoculture are not entirely known, but it is known that the fauna composition tends to change when changes occur in the type of vegetation (Ormerod et al., 1993).

In view of this problem, a study was conducted with the aim to compare the kinetics of decomposition and the colonization of leaf litter of two plant species, the native Talauma ovata (pinha-do-brejo) and the exotic Saccharum officinarum (sugarcane), by aquatic macroinvertebrates. Talauma ovata (Magnoliaceae) is a perennial representative species of the riparian forest in the southeast region of Brazil (Antunes and Ribeiro, 1999) with leaves devoid of pile, veins reticulate, simple blade with margins entire, apex and base acute. The leaf-detritus of this plant have been used previously in colonization and decomposition experiments (Janke and Trivinho-Strixino, 2007; Gimenes et al., 2012). The monocotyledon Saccharum officinarum (Poaceae) has hairy leaves (silica spicules) with parallel veins, simple blade, ciliated margin, invaginate base and acute apex.

Differences in nutritional content, structural features and palatability of plant detritus can result in different rates of leaf breakdown and macroinvertebrate colonization. Being an exotic plant with high silica content in its leaves, it is expected that leaf-detritus from sugarcane presents lower decomposition rate than the native plant. Similarly it should be less attractive to macroinvertebrate shredders. Thus, in this study were tested the following hypothesis: 1) the rate of mass loss during decomposition is lower in S.officinarum leaf-detritus than in native plant leaf-detritus; 2) the leaf-detritus of T. ovata shelters more shredders than S. officinarum leaf-detritus; 3) the numerical macroinvertebrate density is greater when the leaf-detritus structural features is more heterogeneous.

2. Material and Methods

2.1. Experimental procedures

The leaves of T. ovata were collected on the banks of the stream Córrego do Espraiado, São Carlos, upstate São Paulo, Brazil at the beginning of flowering, ie, in the dry season. The leaves undergoing senescence were taken directly from the adult plant. The leaves of S. officinarum were collected within 30 km of the T. ovata site, in a monoculture located between the towns of Araraquara and Ibaté (21 º 52 'S by 48 º 0.5' W), also in the dry season, when the plant was in the ripening period (just before harvest). The leaves of both species were washed in running water to remove any material that could interfere with the gravimetric method (inorganic material, small animals, animal feces) and were subsequently dried at 60 ºC to constant weight and cut in fragments (average size = 8.02 ± 3.62 cm). This procedure is recommended for better assessment of the rates of colonization and to make the samples more uniform (Bärlocher, 1997).

The leaf fragments were placed in polyethylene bottles (volume = 500 mL) with approximately 220 to 250 holes (0.5 cm average diameter) and screw caps. These bottles minimize the drift of leaf particles fragmented during the experiment. Forty-two of these bottles, half containing 12 g of T. ovata leaf-detritus and half with the same weight of S. officinarum leaf-detritus, were deposited on the Córrego do Espraiado stream bed stretch (depth < 1m), spaced by about 0.5 m. This is a first order stream located on coordinates 21º 53 'S and 47º 52' W in a Cerrado area with slightly acid pH (average = 5.49 ± 0.33), oxygen concentration around 6.91 ± 0.56 mg.L^–1 and, in the period of the experiment, showed a minimum temperature of 14ºC and maximum of 20 ºC. It is preserved, heterogeneous riparian vegetation, with sandy bottom substrate and low water velocity (Corbi and Trivinho-Strixino, 2008).

2.2. Data collection

The samples (3 bottles of each detritus) were removed after 7, 15, 34, 44, 61 and 75 days of incubation, isolated in plastic carboys containing water from the site and transported to the laboratory for screening procedures. The fauna was sorted on illuminated trays and naked eye, still alive, after washing through a sieve (mesh 0.25 mm) and fixed in 70% ethanol, except Oligochaeta and Turbellaria previously fixed in 10% formaldehyde solution. The organisms were identified with the aid of identification keys and specialists (Trivinho-Strixino, 2011; Nieser and Melo, 1997; Domínguez et al., 2006, Domínguez and Fernández, 2004; Brinkhurst and Marchese, 1989; Lecci and Froehlich, 2007; Costa et al. 2004; Pes et al., 2005; Passos et al. 2007).

The trophic structure of the settler community was assessed by referring to the classification of feeding guilds Merritt and Cummins (1996) and Cummins et al. (2005), complemented by microscopic examination of digestive tracts of the larvae of Chironomidae. In this study were considered the following feeding groups: Collectors, Shredders, Scrapers and Predators.

The remaining plant detritus was dried at 60 ºC for 48 hours and its mass determined on analytical balance, in order to determine the organic matter mass decay. To determine the inorganic matter aggregated in plant detritus during the experiment, an aliquot of each sample was calcined for 2 hours at 550 ºC (Wetzel and Likens, 1991). The cell wall fractions (CWF) of the remaining detritus were determined by a modified analytical method of Van Soest and Wine (1967) for all sampling periods.

2.3. Data treatment

To analyze the decay of organic matter, a first order kinetic model (Equation 1) was adjusted by the Levenberg-Marquardt algorithm (Press et al., 1993; Bianchini Junior., 2003), where the inorganic fractions obtained from calcination were subtracted from the total remaining mass. To determine the CWF, another kinetic model was fitted (Equation 2):

where, POM = particulate organic matter; POM_L = labile particulate organic matter; POM_R = refractory particulate organic matter; k₁ = POM_L mineralization coefficient (day^–1), k₂ = k_{3 =} POM_R mineralization coefficient (day^–1); e = vase of natural logarithms and t = time (days). The data were subject to the generalized linear model (GLM) to check for possible differences in weight loss and CWF (response variables) in terms of type of leaf-detritus (T. ovata and S. officinarum - categorical variable), sampling periods (time (days) – continuous variable) and an interaction between these two factors.

The half-life (t 1/2) was determined from the coefficient k, according to the following Equation 3:

To evaluate the physical feature of leaf-detritus (heterogeneity) during sampling periods were considered: 1) the change of the leaf appearance, through observation in stereoscopic microscopy and, 2) the change in proportion of CWF in relation to other components (CWF:OC) (intrinsic or non-intrinsic).

The fauna data were analyzed in number of individuals per gram of dry weight (n. indiv. g dry w^–1), relative participation, richness, diversity and functional feeding groups. The sampling periods (time) and the type of leaf-detritus always were considered continuous and categorical variables respectively and the remaining variables as response. To evaluate the influence of the sampling periods, type of leaf-detritus and the interaction between these two factors on macroinvertebrate numerical densities, were used GLM and ANOSIM analysis. To diversity was performed a GLM and evaluated the Brillouin diversity indices, which is indicate when the random of samples is not secure (Magurran, 2004). The density of each functional feeding group was evaluated using 4 GLMs (one for each functional group), considering sampling periods, type of detritus and interaction between these two factors. Furthermore, a GLM was performed in the period of the peak colonization, to each functional feeding group, to compare the two types of leaf-detritus. To evaluate the effects of the plant detritus, sampling periods and interaction between these two factors on the functional structure of the community, was used a MANOVA/Pillai Trace test (Scheiner, 2001; Gonçalves et al., 2012).

3. Results

3.1. Kinetics of leaf-detritus decomposition

According to the kinetic model adopted above, the loss of labile fraction (POM_L) during the decomposition was 12.33 ± 6.15% in S. officinarum and 37.20 ± 9.68% in T. ovata and loss of refractory fraction (POM_R) was 87.7 ± 4.9% in S. officinarum and 62.8 ± 8.0% in T. ovata (Figure 1). The coefficient k₁ (0.5 ± 2.0 day^–1) of the adjusted model for S. officinarum was clearly greater than for T. ovata (0.3 ± 0.3 day^–1). However, the amount of POM_L released by T. ovata was three times higher than that observed in S. officinarum decomposition. Consequently, the half-lives of these remaining materials were 1.4 and 2.2 days respectively in S. officinarum and T. ovata (Table 1). For both species, the refractory portion was released more slowly than the labile fraction. The rate of decomposition of this portion was higher in T. ovata (k₂ = 0.006 day^–1, t 1/2 = 119.0 days) than in S. officinarum (K₂ = 0.005 day^–1, t 1/2 = 133.3 days) (Table 1).

At the end of the experiment, there remained 55.8% ± 4.8 and 34.9 ± 3.2% of the detritus of S. officinarum and T. ovata respectively. The statistical analysis showed significance differences between the two types of leaf-detritus (F_1,8 = 197.24; p < 0.001) and sampling periods (F_1,8 = 410.25; p < 0.001). However, no significance difference was founded when considered the interaction between these two factors on the biomass loss (F_1,8 = 0.32; p = 0.580).

S. officinarum showed sligth differences in their leaf-detritus appearance and the proportion CWF:OC was always high (beginning = 88:11; middle = 98:2; end = 85:14 ) during all decomposition process. In contrast, the leaf-detritus of T. ovata changed continuously its appearance and proportion CWF:OC (beginning = 64:36; middle = 79:21; end = 84:16) until the end of the process (Figure 2). A significance difference between the two types of detritus was showed by the statistical test (F_1,10 = 17.10; p = 0.002).

3.2. Fauna associated with detritus

Overall, 3,395 specimens of macroinvertebrates from 66 taxa were analysed (Table 2). The most prevalent were the chironomids Endotribelos, Caladomyia, Tanytarsus, Ablabesmyia (Figure 3) and the mayfly Miroculis, each contributing more than 5% of the total. All the other taxa were in low abundance. Particularly, notable was the massive contribution of Endotribelos larvae on T. ovata detritus, with 22% of the total fauna, while on S. officinarum these contributed only 4%; thus, the relative abundance of the Endotribelos on T. ovata detritus was almost six times higher than on S. officinarum.

During experiment it was observed that the maximum numerical density of macroinvertebrates occurred on the native plant detritus in the intermediate period (34 and 44 days of colonization - Figure 4a), showing densities 2.3 and 2.7 times higher than in leaf-detritus of S. officinarum. In this period, the detritus of S. officinarum showed average numerical densities of 14.3 indiv. g dry w^–1 (Figure 4b). For the taxonomic structure of community, the statistical analysis indicated significance difference only to the time of colonization (F_1,8 = 178.31; p = 0.005). The similarity this analysis showed no significance difference (R = 0.009; p = 0.360) between the two types of leaf-detritus. The community diversity ranged with the types of detritus (F_1,8 = 6.53; p = 0.003) and with the interaction between the time of colonization and the type of leaf-detritus (F_1,8 = 45.116; p < 0.001), being the macrofauna more diverse in S. officinarum then T. ovata.

Overall, T. ovata was colonized by: 48.6% collectors; 30.8% shredders, 19.1% predators and 0.2% scrapers (Figure 5a). S. officinarum detritus were colonized by 61.1% collectors, 10.3% shredders, 26.8% predators and 1.81% scrapers (Figure 5b). The numerical density of functional feeding groups was not different (F_4,5 = 0.51; p = 0.720) when analyzed the effect of the types of leaf-detritus on all macroinvertebrate community, but there was significance difference when considered the time of decomposition (F_4,5 =33.46; p < 0.001). This was mainly by differential participation of the collector (F_{1,8 =} 7.72; p = 0.02) and predator groups (F_1,8 = 26.89; p < 0.001). In contrast the analysis considering only the functional feeding groups on the peak of colonization (34 - 45 days) showed significance difference between the two types of plants detritus in three groups: collectors (F_1,3 = 51.92; p = 0.001), shredders (F_1,3 = 473.38; p = 0.002) and predators (F_1,3 = 95.68; p = 0.001), with higher densities in T. ovata than S. officinarum.

4. Discussion

In general, the kinetic of decomposition is discussed in terms of the amount of biomass lost, velocity decay (k coefficients) and half-life times of the labile and refractory portion of the leaf-detritus (Bianchini Junior, 1999). The differences in decay rates of plant mass, whether POM_L or POM_R, observed in the experiment with two types of plant detritus can be attributed to factors, like chemical composition of structural parts (e.g. cellulose and lignin) differences between the two species and their nutrient content (see in Mun et al., 2001). The mass loss in the first days of decomposition (POM_L) is, according to Davis III et al. (2003), due to the leaching process and corresponds to organic and inorganic compounds present in the protoplasm and soluble fractions of the detritus. Although the leaf-detritus of T. ovata releases a major portion of this labile material, the velocity of degradation was slower than S. officinarum, probably because of the larger amounts of energy compounds (mono and polysaccharides) on sugarcane, which are essential for microbial metabolism (Gimenes et al., 2012).

The fraction POM_R has a higher proportion of poorly degradable material, such as lignin, cellulose and hemicellulose, explaining its slow decomposition. This trend towards a lower rate of decomposition after the first days was observed in various studies (Bianchini Junior, 1999). The larger proportion of macroinvertebrates shredders in the peak of colonization in the leaf-detritus of T. ovata and its apparent tearability of the detritus must have tended to accelerate the mechanical fragmentation (Clapcott and Bunn, 2003, Gessner et al., 1999). These two factors possibly influenced in the greater velocity of decay of the refractory material in T. ovata leaf-detritus, relative to S. officinarum. According to Petersen (1984), leaf-detritus that decompose faster support higher densities of settlers, as observed in T. ovata. Gimenes et al. (2012) in a decomposition experiment in vitro (ie, without macroinvertebrates or stream action) with the same plant species observed that T. ovata leaf-detritus had a concentration of CWF 20% higher than that found in the present study. In addition, in the same experiment, the portion of the POM_R in T. ovata leaf-detritus decomposed more slowly than in S. officinarum (K2 = K4 = 0.005 day^–1 and K2 = K4 = 0.007 day^-1, respectively), contradicting the present result. These results seem to indicate the influence of the fauna accelerating the fragmentation of the leaf-detritus of T. ovata in the field experiment, fact not observed in S. officinarum.

The dynamics of macrofauna colonization on the plant detritus seems to follow the cyclic model of invasion and exclusion of Armesto et al. (1991), which shows alternating periods of high and low spatial heterogeneity during decomposition, the highest diversity and density occurring in periods of greater heterogeneity of the substrate. As the detritus of S. officinarum showed no obvious changes during the experiment, colonization remained almost constant, in contrast to T. ovata, on which the maximum density of macroinvertebrates occurred when there was greatest heterogeneity of the detritus. The schematic diagram in Figure 2 illustrates the steps in the process of colonization on the two detritus: at the beginning of experiment, both plant detritus had low densities of macroinvertebrates and there was a marked homogeneity of the leaf substrates, due to the still little action of decomposing mechanisms. Next, the density increased and the substrate had already become more heterogeneous (evident in Figure 2a), due to microbial and macroinvertebrate action. In the last days of the experiment, the substrate T. ovata returned to a more homogeneous appearance, reflecting the size and state of the particles at a late stage of decomposition. As seen in Figure 2b, the appearance of the leaf-detritus of S. officinarum did not seem to change much during the experiment, indicating low heterogeneity, and this was accompanied by a similar colonization throughout. Capello et al. (2004) reported similar observations in his study of the decomposition of leaf-detritus of Salix humboldtiana. Similarly, Gonçalves et al. (2012) attributed the changes of the physical state of detritus and faunal composition to the natural degradative succession process: a sequence of changes in colonization by organisms, which modifies the properties of the surface and improves the habitat for subsequent colonists (Gonçalves et al., 2004; Ligeiro et al., 2010).

The results of this study indicate, in general, that the state of decomposition of plant detritus and the amount of biomass present at each moment (time of colonization) were more important to the macroinvertebrate density than the type of plant detritus. Collectors, like Caladomyia, Stempellina, Tanytarsus, Allonais and Triplectides, which high participation on the detritus native plant, may not have been active in the process of decay of the organic matter in the leaf-detritus, but possibly used fine particulate organic matter as food source or the detritus provides place of refuge or settlement (Capello et al. 2004; Mathuriau and Chauvet, 2002). The colonization of the leaf-detritus of T. ovata by great numbers of larvae of Endotribelos, a chironomid larva with several shredder species (Roque et al., 2005) may have played an important part in the decomposition of the native plant. Similar results were observed by Clapcott and Bunn (2003) in Australia, in the colonization of plant detritus of Saccharum, Urochloa and Eucalyptus (native) where the action of shredders (in this case, the trichopteran Anisocentropus kirramus) was greater on native vegetation.

According to Ormerod et al. (1993), changes in the riparian vegetation appear to affect directly the composition of the benthic macroinvertebrate community. In the present study, what could be observed was the different proportion of functional groups in the two types of detritus in the peak of colonization, but not distinct taxonomic communities. Studies to be conducted in streams impacted by the monoculture of sugarcane may yet show whether there are major changes in these communities.

5. Conclusion

Regarding the hypotheses made at the outset, it can be concluded: (1) the rate of mass loss during decomposition was lower in S. officinarum detritus than in T. ovata; (2) T. ovata presented more shredder macroinvertebrates than S. officinarum; (3) When the leaf-detritus were more heterogeneous there were greater macroinvertebrate densities. In addition, the amount and state of the biomass were important factors influencing the density and diversity of the macroinvertebrate fauna throughout the process of organic decomposition.

Acknowledgements

The authors thank the Foundation for Research Aid of São Paulo (FAPESP) for the scholarship and funding of this work (File: 2009/50690-8) and the Laboratório de Bioensaios e Modelagem Matemática, especially Marcela Bianchessi da Cunha Santino and Karen Zauner Gimenes, for essential comments on this manuscript.

Received: 18 June 2012

Accepted: 28 November 2012

Publication Dates

History