Abstract
This study assessed the potential of termite gut inhabiting bacteria towards bioconversion of cellulosic waste into biofuel. Total seven bacterial isolates from the gut of Heterotermes indicola were isolated. Among all the isolates, HI-1 produced the largest zone upon primary screening. Untreated paper had more cellulose content (73.03%) than acid (0.5%) treated paper that was used as a lignocellulosic substrate for saccharification. Among all the isolates tested, glucose yield (1.08mg/mL) was high for HI-1 isolate. Several factors were considered for optimizing augmented glucose yield (8.57mg/mL) and growth (8.07×108cfu/mL), such as temperature 37°C, pH 4.5, 5% (w/v) substrate concentration, 6 % bacterial inoculum size, agitation 150 rpm with PEG 0.25 % and Ca2+ ions 0.002 g/L. Overall 8-fold increase in glucose yield was achieved. Enzyme activity of HI-1 showed higher endoglucanase 0.29 ± 0.01 (U/mL/min) and exoglucanase 0.15±0.01 (U/mL/min) activity under optimum conditions, mentioned above. temperature 37°C, pH 4.5, substrate concentration 5%, inoculum size 6%, surfactants PEG 0.01%, ions Ca2+(0.002g/L) and agitation (120 rpm). Simultaneous saccharification and fermentation (SSF) of hydrolyzed office paper yielded 5.43mg/mL bioethanol. According to 16S rRNA sequence homology, the bacterial isolate H1 was identified as Alcaligenes faecalis. Bioethanol production from office paper untreated waste proved an effective strategy. Bacteria having natural tendency towards cellulosic waste consumption are promising for bioconversion of cellulosic waste to valuable products.
Highlights
Fossil fuel depletion causes increase in oil prices and petroleum products that led to a sharp interest in finding alternative energy sources
The present study was undertaken to investigate the potential of cellulolytic bacteria isolated from the gut of termites in bioconversion of highly cellulosic urban waste, and office paper into reducible sugars that was later fermented to bioethanol
New habitats must be searched for novel cellulolytic bacteria which can lead to novel enzymes with efficient activity
Summary
Fossil fuel depletion causes increase in oil prices and petroleum products that led to a sharp interest in finding alternative energy sources. Biofuels can substitute fossil fuels and confer several advantages, ie., produced from renewable sources, lessens greenhouse gas emissions, and cost effective (Wyman 1994). Cellulases from cellulolytic bacteria have been applied in biofuel production due to their unique saccharolytic properties (Chang and Yao 2011). Cellulose, being an abundant biopolymer on earth, is the best resource for renewable energy (Rezaei et al 2008). Bioethanol generated from cellulose in the form of agro-industrial waste has an improved eco-balance, as it does not compete with the food production, while on the other hand, it is readily accessible at low cost (Zhou et al 2007).
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