Impact of fine litter chemistry on lignocellulolytic enzyme efficiency during decomposition of maize leaf and root in soil

Amin, B.; Chabbert, Brigitte; Moorhead, Daryl L.; Bertrand, Isabelle

doi:10.1007/s10533-013-9856-y

Cited by 70 publications

(43 citation statements)

References 49 publications

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“…The lowest enzyme efficiencies in the root treatment were compensated for by the highest investments in enzyme activities. The relationships between the enzyme efficiencies and the chemical recalcitrance of the substrate remain unclear (Sinsabaugh et al, 2002; Wickings et al, 2012; Amin et al, 2014; Fanin et al, 2016). In the present work, differences in the enzyme efficiencies observed between the stems and roots could not be explained by differences in the lignin content, which was similar for the two litters.…”

Section: Discussionmentioning

confidence: 99%

“…We calculated the enzyme efficiencies between dates and summed the values over the entire incubation period for the C-acquiring hydrolase activity by summing the βG, EX, and EG activities and for the oxidative enzyme activity by using the LAC value. The enzyme activity efficiencies can be assessed against the CO 2 mineralized as an index of microbial metabolism (Sinsabaugh et al, 2002; Moorhead et al, 2013b; Amin et al, 2014). We proposed in this study to calculate the efficiency of the enzyme activity for fungal-C biosynthesis (in μg fungal-C mol -1 ) by dividing the amount of recovered C in fungal biomass by the cumulative enzyme activity (in μmol g -1 DM).…”

Section: Methodsmentioning

confidence: 99%

“…Indeed, once enzymes have been secreted, their activities have shown different efficiencies, meaning that the amount of enzyme activity required for substrate decomposition can vary markedly. High contents of lignin may decrease enzyme efficiency (Sinsabaugh et al, 2002; Wickings et al, 2012), and recalcitrant substrates may alternatively induce the synthesis of an enzyme “cocktail” in which hydrolytic enzymes act in synergy with oxidative enzymes, thereby resulting in a higher efficiency relative to enzymes secreted on labile substrates (Amin et al, 2014). Enzyme activities per unit microbial biomass synthetized over a specific period are used to characterize the microbial “investment” in enzymes.…”

Section: Introductionmentioning

confidence: 99%

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Enzymatic Strategies and Carbon Use Efficiency of a Litter-Decomposing Fungus Grown on Maize Leaves, Stems, and Roots

et al. 2016

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Soil microorganisms can control the soil cycles of carbon (C), and depending on their C-use efficiency (CUE), these microorganisms either contribute to C stabilization in soil or produce CO2 when decomposing organic matter. However, little is known regarding the enzyme investment of microbial decomposers and the effects on their CUE. Our objective was to elucidate the strategies of litter-decomposing fungi as a function of litter quality. Fungal biosynthesis and respiration were accounted for by quantifying the investment in enzyme synthesis and enzyme efficiency. The basidiomycete Phanerochaete chrysosporium was grown on the leaves, stems, and roots of maize over 126 days in controlled conditions. We periodically measured the fungal biomass, enzyme activity, and chemical composition of the remaining litter and continuously measured the evolved C–CO2. The CUE observed for the maize litter was highest in the leaves (0.63), intermediate in the roots (0.40), and lowest in the stems (0.38). However, the enzyme efficiency and investment in enzyme synthesis did not follow the same pattern. The amount of litter C decomposed per mole of C-acquiring hydrolase activity was 354 μg C in the leaves, 246 μg C in the roots, and 1541 μg C in the stems (enzyme efficiency: stems > leaves > roots). The fungus exhibited the highest investment in C-acquiring enzyme when grown on the roots and produced 40–80% less enzyme activity when grown on the stems and leaves (investment in enzymes: roots > leaves > stems). The CUE was dependent on the initial availability and replenishment of the soluble substrate fraction with the degradation products. The production of these compounds was either limited because of the low enzyme efficiency, which occurred in the roots, or because of the low investments in enzyme synthesis, which occurred in the stems. Fungal biosynthesis relied on the ability of the fungus to invest in enzyme synthesis and the efficient interactions between the enzymes and the substrate. The investment decreased when N was limited, whereas the efficiency of the C-acquiring enzymes was primarily explained by the hemicellulose content and its embedment in recalcitrant lignin linkages. Our results are crucial for modeling microbial allocation strategies.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Enzymatic Strategies and Carbon Use Efficiency of a Litter-Decomposing Fungus Grown on Maize Leaves, Stems, and Roots

et al. 2016

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“…This view is supported by Amin et al [69] who have recently reported a decrease in specific activities of measured enzymes during decomposition of maize roots as compared to leaf residues and ascribed it to the presence of higher ligno-cellulosic fractions of the roots besides other chemical features of the wall constituents. Further, lower enzymatic activities does not necessary reflect lower efficiency [70] and we hypothesize that higher efficiency of the enzymes in Jatropha press cake amended soil might have resulted in more resource allocation to increase biomass by some group of microorganisms for ecological or competitive advantage over others.…”

Section: Influence Nutrient Amendments On Soil Organic Carbon Accumulmentioning

confidence: 59%

Long-term application of Jatropha press cake promotes seed yield by enhanced soil organic carbon accumulation, microbial biomass and enzymatic activities in soils of semi-arid tropical wastelands

Anand

Kubavat

Trivedi

et al. 2015

European Journal of Soil Biology

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a b s t r a c tJatropha curcas is a potential biofuel crop and press cake is an important co-product obtained during biodiesel production. In order to assess the long-term effects of application of Jatropha press cake on soil quality parameters and to evaluate its efficacy as an organic manure, a field trial was carried out in degraded wasteland of Gujarat, India with four treatments chosen on the basis of equivalent amounts of N supply through urea, Jatropha press cake, farmyard manure (FYM) and half dose of urea. The activities of various exocellular enzymes involved in nutrient cycling, microbial biomass carbon, respiration, fluorescein diacetate (FDA) hydrolysis and the influence of chemical composition of the organic manures on these parameters were studied following seven continuous years of application of nutrient amendments. Degradation of the phorbols, toxins present in press cake, was also studied. Except for acid phosphomonoesterase, enzyme activities were higher in FYM compared to other treatments. Lignin content was higher in FYM while the ligno-cellulosic fraction was higher by 45% in press cake as compared to FYM. Notably, carbon accumulation in soil was higher per unit of applied carbon in press cake treated soil. Ratio of microbial biomass carbon to soil organic carbon was higher in press cake amended soil. Phorbol esters were degraded to negligible amounts. The increase in yield of Jatropha following improved enzyme activities, microbial carbon and FDA hydrolysis owing to press cake application in erstwhile poor soils unequivocally establishes the scope of Jatropha press cake in reclaiming unfertile wastelands sustainably.

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“…In addition, it was reported that the chemistry of a single litter type diverged when it was decomposed in management systems with distinct decomposer communities (Wickings et al, 2012).Collectively, these investigations may provide an explanation for the results that the k m value for the roots was significantly higher under the aerobic condition compared with the flooded condition. Furthermore, it was reported that the enzyme activity was higher in maize leaf than root amended soils while enzyme efficiency was systematically higher in the presence of roots, which demonstrated that litter quality is regulating decomposer strategy (Amin et al, 2014). Thus, the opposite pattern of differed process of decomposition between leaves and roots under aerobic and flooded condition indicated that the chemistry of different litter types diverged, rather than converged, during decomposition due to the activities of decomposers, as suggested by Wickings et al (2012).…”

Section: Decomposition Dynamics Of Rice Residues Under Aerobic and Flmentioning

confidence: 96%

Effects of water management practices on residue decomposition and degradation of Cry1Ac protein from crop-wild Bt rice hybrids and parental lines during winter fallow season

Xiao

Dong

et al. 2015

Ecotoxicology and Environmental Safety

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Impact of fine litter chemistry on lignocellulolytic enzyme efficiency during decomposition of maize leaf and root in soil

Cited by 70 publications

References 49 publications

Enzymatic Strategies and Carbon Use Efficiency of a Litter-Decomposing Fungus Grown on Maize Leaves, Stems, and Roots

Enzymatic Strategies and Carbon Use Efficiency of a Litter-Decomposing Fungus Grown on Maize Leaves, Stems, and Roots

Long-term application of Jatropha press cake promotes seed yield by enhanced soil organic carbon accumulation, microbial biomass and enzymatic activities in soils of semi-arid tropical wastelands

Effects of water management practices on residue decomposition and degradation of Cry1Ac protein from crop-wild Bt rice hybrids and parental lines during winter fallow season

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