Engineering cellulases for conversion of lignocellulosic biomass

Chaudhari, Yogesh B.; Várnai, Anikó; Sørlie, Morten; Horn, Svein Jarle; Eijsink, Vincent G. H.

doi:10.1093/protein/gzad002

Cited by 6 publications

(4 citation statements)

References 146 publications

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“…The order of hydrolysed cellulose started with amorphous domains, followed by the crystalline domains, as reported by Ling et al (2017), where the yield of monosaccharides dropped as the crystallinity of the substrate increased. Moreover, each cellulase component has its specific capabilities and activity for the adsorption of different types of cellulose through carbohydrate-binding modules (CBMs) during the breakdown of cellulose (Chaudhari et al, 2023).…”

Section: Biochemical Processes Of Lignocellulosic Biomass Utilisationmentioning

confidence: 99%

Lignocellulosic Biomass-Derived Biogas: A Review on Sustainable Energy in Malaysia

AB AZIZ

2024

JOPR

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Lignocellulosic Biomass (LCB) is regarded as a potentially sustainable alternative resource to fossil fuels.To address concerns related to environmental degradation and geopolitical tensions arising from resource scarcity, the global focus shifted towards developing and utilising sustainable and Renewable Energy (RE) technologies. Biogas technology has attracted attention due to its promising potential to generate energy from agro-waste and the preservation of natural resources. Therefore, this review explores the potential of utilising RE, specifically focusing on its practical implementation in Malaysia. It critically evaluates pre-treatment methods suitable for the country's prevalent biomass sources, offering insights into their applicability.Additionally, the article provides updated data on Malaysia's strategy to advance RE production, particularly in biogas. Despite considerable efforts, there is a notable gap in comprehensively assessing the impact of pretreatment methods on LCB in Malaysia's biogas production. Hence, this article critically assesses recent advancements to address this gap, focusing on potential challenges and the comparative effectiveness of treatment techniques in Malaysian biogas production. It is with the aim to shed light on associated drawbacks and suggest means to enhance performance. Finally, this article ends by reviewing economic analyses for pre-treatment in LCB, focusing on efficient biogas production.

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Section: Biochemical Processes Of Lignocellulosic Biomass Utilisationmentioning

confidence: 99%

Lignocellulosic Biomass-Derived Biogas: A Review on Sustainable Energy in Malaysia

AB AZIZ

2024

JOPR

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“…Hence, engineering individual lignocellulose deconstructing enzymes has been a topic of intense research. For instance, cellulases have been optimised for improved activity, thermostability and pH tolerance; the details of these efforts are outside the scope of this piece, but many of these efforts are covered in excellent reviews [86–89] . Engineered enzyme cocktails have also been developed, with multiple synergistic biocatalysts working together to deconstruct several biomass components in parallel [90] .…”

Section: Accessing Renewable Feedstocks and Chemicals From Biological...mentioning

confidence: 99%

“…For instance, cellulases have been optimised for improved activity, thermostability and pH tolerance; the details of these efforts are outside the scope of this piece, but many of these efforts are covered in excellent reviews. [ 86 , 87 , 88 , 89 ] Engineered enzyme cocktails have also been developed, with multiple synergistic biocatalysts working together to deconstruct several biomass components in parallel. [90] These cocktails typically consist of cellulases, cellobiohydrolases, endoglucanases, β‐glucosidases, hemicellulases, and lytic polysaccharide monooxygenases.…”

Section: Accessing Renewable Feedstocks and Chemicals From Biological...mentioning

confidence: 99%

Engineering Enzymes for Environmental Sustainability

Radley,

Davidson,

Foster

et al. 2023

Angew Chem Int Ed

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The development and implementation of more efficient and sustainable technologies is key to delivering our net‐zero targets. Here we review how engineered enzymes, with a focus on those developed using directed evolution, can be deployed to improve the sustainability of numerous processes and help to conserve our environment. Efficient and robust biocatalysts have been engineered to capture carbon dioxide (CO2) and have been embedded into new efficient metabolic CO2 fixation pathways. Enzymes have been refined for bioremediation, enhancing their ability to degrade toxic and harmful pollutants. Biocatalytic recycling is gaining momentum, with engineered cutinases and PETases developed for the depolymerization of the abundant plastic, PET. Finally, biocatalytic approaches for accessing petroleum‐based feedstocks and chemicals are expanding, using optimized enzymes to convert plant biomass into biofuels or other high value products. Through these examples, we hope to illustrate how enzyme engineering and biocatalysis can contribute to the development of more environmentally sustainable approaches, in order to protect our planet.

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“…Mostly, bacterial and fungal enzymes have been used in the process, but plant enzymes present an equally attractive opportunity as these are naturally involved in cell wall turnover in plants. Whatever the source of enzyme, researchers have noted that natural enzymes may not be sufficiently active to enable economically viable bioprocesses, even at optimal conditions or might be subject to product inhibition ( Chaudhari et al, 2023 ). Therefore, enzyme engineering becomes a necessity.…”

Section: Nature-inspired Biocatalysis Enzyme Engineering and Extremoz...mentioning

confidence: 99%

Nature-inspired Enzyme engineering and sustainable catalysis: biochemical clues from the world of plants and extremophiles

Chatterjee

Puri

Sharma

et al. 2023

Front. Bioeng. Biotechnol.

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The use of enzymes to accelerate chemical reactions for the synthesis of industrially important products is rapidly gaining popularity. Biocatalysis is an environment-friendly approach as it not only uses non-toxic, biodegradable, and renewable raw materials but also helps to reduce waste generation. In this context, enzymes from organisms living in extreme conditions (extremozymes) have been studied extensively and used in industries (food and pharmaceutical), agriculture, and molecular biology, as they are adapted to catalyze reactions withstanding harsh environmental conditions. Enzyme engineering plays a key role in integrating the structure-function insights from reference enzymes and their utilization for developing improvised catalysts. It helps to transform the enzymes to enhance their activity, stability, substrates-specificity, and substrate-versatility by suitably modifying enzyme structure, thereby creating new variants of the enzyme with improved physical and chemical properties. Here, we have illustrated the relatively less-tapped potentials of plant enzymes in general and their sub-class of extremozymes for industrial applications. Plants are exposed to a wide range of abiotic and biotic stresses due to their sessile nature, for which they have developed various mechanisms, including the production of stress-response enzymes. While extremozymes from microorganisms have been extensively studied, there are clear indications that plants and algae also produce extremophilic enzymes as their survival strategy, which may find industrial applications. Typical plant enzymes, such as ascorbate peroxidase, papain, carbonic anhydrase, glycoside hydrolases and others have been examined in this review with respect to their stress-tolerant features and further improvement via enzyme engineering. Some rare instances of plant-derived enzymes that point to greater exploration for industrial use have also been presented here. The overall implication is to utilize biochemical clues from the plant-based enzymes for robust, efficient, and substrate/reaction conditions-versatile scaffolds or reference leads for enzyme engineering.

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Engineering cellulases for conversion of lignocellulosic biomass

Cited by 6 publications

References 146 publications

Lignocellulosic Biomass-Derived Biogas: A Review on Sustainable Energy in Malaysia

Lignocellulosic Biomass-Derived Biogas: A Review on Sustainable Energy in Malaysia

Engineering Enzymes for Environmental Sustainability

Nature-inspired Enzyme engineering and sustainable catalysis: biochemical clues from the world of plants and extremophiles

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