Enhanced Thermostability and Enzymatic Activity of cel6A Variants from Thermobifida fusca by Empirical Domain Engineering

Imran, Ali; Rehman, Hafiz Muzzammel; Mirza, Muhammad Usman; Akhtar, Muhammad; Asghar, Rehana; Tariq, Muhammad; Ahmed, Rashid; Tanveer, Fatima; Khalid, Hina; Alghamdi, Huda Ahmed; Froeyen, Matheus

doi:10.3390/biology9080214

Cited by 6 publications

(2 citation statements)

References 73 publications

(90 reference statements)

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“…Their research suggests that cellulose hydrolysis can be improved for larger bioethanol outputs. Ali et al [ 94 ], also found that uncovering Cel6A variations from Thermobifida fusca utilizing protein domain engineering and molecular dynamics investigations improved their enzymatic activity. Computer-based different microbial cellulase enzyme is given in Figure 2 .…”

Section: Molecular Modelingmentioning

confidence: 99%

A Combined Study on Optimization, In Silico Modeling, and Genetic Modification of Large Scale Microbial Cellulase Production

Rabby¹,

Ahmed²,

Paul³

et al. 2022

Biochemistry Research International

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Cellulase is a biocatalyst that hydrolyzes cellulosic biomass and is considered a major group of industrial enzymes for its applications. Extensive work has been done on microbial cellulase but fungi are considered a novel strain for their maximum cellulase production. Production cost and novel microbial strains are major challenges for its improvement where cheap agro wastes can be essential sources of cellulose as substrates. The researcher searches for more cellulolytic microbes from natural sources but the production level of isolated strains is comparatively low. So genetic modification or mutation can be employed for large-scale cellulase production before optimization. After genetic modification than in silico molecular modeling can be evaluated for substrate molecule’s binding affinity. In this review, we focus not only on the conventional methods of cellulase production but also on modern biotechnological approaches applied to cellulase production by a sequential study on common cellulase-producing microbes, modified microbes, culture media, carbon sources, substrate pretreatment process, and the importance of optimum pH and temperature on fermentation. In this review, we also compare different cellulase activity determination methods. As a result, this review provides insights into the interrelationship between the characteristics of optimizing different culture conditions, genetic modification, and in silico enzyme modeling for the production of cellulase enzymes, which may aid in the advancement of large-scale integrated enzyme manufacturing of substrate-specific enzymes.

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Section: Molecular Modelingmentioning

confidence: 99%

A Combined Study on Optimization, In Silico Modeling, and Genetic Modification of Large Scale Microbial Cellulase Production

Rabby¹,

Ahmed²,

Paul³

et al. 2022

Biochemistry Research International

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“…The readily available T. fusca genome sequence reveals that it has the capacity to express many enzymes useful for hydrolyzing biomass, including numerous cellulases, xylanases, and carbohydrate transporters for sugar uptake ( Lykidis et al, 2007 ). Many of these thermally stable enzymes have been heterologously expressed in alternative microbial hosts and analyzed for their applicability to biomass conversion ( Ghangas and Wilson, 1987 ; Ali et al, 2015 ; Klinger et al, 2015 ; Saini et al, 2015 ; Zhao et al, 2015 ; Setter-Lamed et al, 2017 ; Yan and Fong, 2018 ; Ali et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

The Effects of Carbon Source and Growth Temperature on the Fatty Acid Profiles of Thermobifida fusca

Winkelman

Nikolau

2022

Front. Mol. Biosci.

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The aerobic, thermophilic Actinobacterium, Thermobifida fusca has been proposed as an organism to be used for the efficient conversion of plant biomass to fatty acid-derived precursors of biofuels or biorenewable chemicals. Despite the potential of T. fusca to catabolize plant biomass, there is remarkably little data available concerning the natural ability of this organism to produce fatty acids. Therefore, we determined the fatty acids that T. fusca produces when it is grown on different carbon sources (i.e., glucose, cellobiose, cellulose and avicel) and at two different growth temperatures, namely at the optimal growth temperature of 50°C and at a suboptimal temperature of 37°C. These analyses establish that T. fusca produces a combination of linear and branched chain fatty acids (BCFAs), including iso-, anteiso-, and 10-methyl BCFAs that range between 14- and 18-carbons in length. Although different carbon sources and growth temperatures both quantitatively and qualitatively affect the fatty acid profiles produced by T. fusca, growth temperature is the greater modifier of these traits. Additionally, genome scanning enabled the identification of many of the fatty acid biosynthetic genes encoded by T. fusca.

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Microbial cellulases – An update towards its surface chemistry, genetic engineering and recovery for its biotechnological potential

Paul

Mohapatra²,

Mohapatra

et al. 2021

Bioresource Technology

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Enhanced Thermostability and Enzymatic Activity of cel6A Variants from Thermobifida fusca by Empirical Domain Engineering

Cited by 6 publications

References 73 publications

A Combined Study on Optimization, In Silico Modeling, and Genetic Modification of Large Scale Microbial Cellulase Production

A Combined Study on Optimization, In Silico Modeling, and Genetic Modification of Large Scale Microbial Cellulase Production

The Effects of Carbon Source and Growth Temperature on the Fatty Acid Profiles of Thermobifida fusca

Microbial cellulases – An update towards its surface chemistry, genetic engineering and recovery for its biotechnological potential

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