Restructuring the Crystalline Cellulose Hydrogen Bond Network Enhances Its Depolymerization Rate

Chundawat, Shishir P. S.; Bellesia, Giovanni; Uppugundla, Nirmal; Sousa, Leonardo da Costa; Gao, Dahai; Cheh, Albert M.; Agarwal, Umesh P.; Bianchetti, C.M.; Phillips, George N.; Langan, Paul; Balan, Venkatesh; Gnanakaran, S.; Dale, Bruce E.

doi:10.1021/ja2011115

Cited by 328 publications

(321 citation statements)

References 65 publications

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“…There are a number of significant correlations including those between total CBH and both glucan (r = 0.914, p < 0.01) and xylan (r = 0.551, p < 0.01) slopes, between total EG and both glucan (r = 0.888, p < 0.01) and xylan (r = 0.485, p < 0.01) slopes, between total CBH + EG and both glucan (r = 0.926, p < 0.05) and xylan (r = 0.545, p < 0.05) slopes, and between total CBH + EG + BG and both glucan (r = 0.919, p < 0.05) and xylan (r = 0.578, p < 0.05) slopes. These results validate previous findings that glucan/xylan yields are highly correlated and enzymes that facilitate glucan hydrolysis (CBH, EG, and BG) also facilitate increased digestibility of xylans by hemicellulases or multifunctional glycosyl hydrolases like EG I (Gao et al, 2010a;Chundawat et al, 2011b).…”

Section: Resultssupporting

confidence: 90%

Shotgun Approach to Increasing Enzymatic Saccharification Yields of Ammonia Fiber Expansion Pretreated Cellulosic Biomass

et al. 2017

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Section: Resultssupporting

confidence: 90%

Shotgun Approach to Increasing Enzymatic Saccharification Yields of Ammonia Fiber Expansion Pretreated Cellulosic Biomass

et al. 2017

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“…38,39 Allthough we are unable to distinguish decrystallization of the substrate and the sliding movement of CD, because the sliding movement should promote decrystallization of cellulose, while the decrystallization should cause movement vice versa, we speculate that the rate-limiting step of crystalline cellulose degradation is the process rather than the catalysis as discussed from "bulk" experiments. 38,39 Although a direct comparison between the results of singlemolecule observation and biochemical activity measurement is often difficult, the order of hydrolytic activity on PASC was the same as the order of the velocity of processive movement and k off . This result implies that the rate-limiting step of PASC hydrolysis is the catalytic process or the off-rate from the substrate, but not decided by processivity.…”

Section: ■ Discussionmentioning

confidence: 84%

Trade-off between Processivity and Hydrolytic Velocity of Cellobiohydrolases at the Surface of Crystalline Cellulose

et al. 2014

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Analysis of heterogeneous catalysis at an interface is difficult because of the variety of reaction sites and the difficulty of observing the reaction. Enzymatic hydrolysis of cellulose by cellulases is a typical heterogeneous reaction at a solid/liquid interface, and a key parameter of such reactions on polymeric substrates is the processivity, i.e., the number of catalytic cycles that can occur without detachment of the enzyme from the substrate. In this study, we evaluated the reactions of three closely related glycoside hydrolase family 7 cellobiohydrolases from filamentous fungi at the molecular level by means of high-speed atomic force microscopy to investigate the structure−function relationship of the cellobiohydrolases on crystalline cellulose. We found that high moving velocity of enzyme molecules on the surface is associated with a high dissociation rate constant from the substrate, which means weak interaction between enzyme and substrate. Moreover, higher values of processivity were associated with more loop regions covering the subsite cleft, which may imply higher binding affinity. Loop regions covering the subsites result in stronger interaction, which decreases the velocity but increases the processivity. These results indicate that there is a trade-off between processivity and hydrolytic velocity among processive cellulases.

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“…In preparing novel cellulose-chitosan biocomposites, we need usually to disassemble the molecular networks, either directly or after chemical modification (Chundawat et al 2011) and to mix the two polymers. Among the different ways of disassembly, dissolution enables to separate the polymer chains from each other and produce molecular ''bricks'' for construction of novel materials (Trygg 2015).…”

Section: Introductionmentioning

confidence: 99%

Spherical nanocomposite particles prepared from mixed cellulose–chitosan solutions

et al. 2016

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Novel cellulose-chitosan nanocomposite particles with spherical shape were successfully prepared via mixing of aqueous biopolymer solutions in three different ways. Macroparticles with diameters in the millimeter range were produced by dripping cellulose dissolved in cold LiOH/urea into acidic chitosan solutions, inducing instant co-regeneration of the biopolymers. Two types of microspheres, chemically crosslinked and non-crosslinked, were prepared by first mixing cellulose and chitosan solutions obtained from freeze thawing in LiOH/KOH/urea. Thereafter epichlorohydrin was applied as crosslinking agent for one of the samples, followed by water-inoil (W/O) emulsification, heat induced sol-gel transition, solvent exchange, washing and freeze-drying. Characterization by X-ray photoelectron spectroscopy, total elemental analysis, and Fourier transform infrared spectroscopy confirmed the prepared particles as being true cellulose-chitosan nanocomposites with different distribution of chitosan from the surface to the core of the particles depending on the preparation method. Field emission scanning electron microscopy and laser diffraction was performed to study the morphology and size distribution of the prepared particles. The morphology was found to vary due to different preparation routes, revealing a core shell structure for macroparticles prepared by dripping, and homogenous nanoporous structure for the microspheres. The non-crosslinked microparticles exhibited a somewhat denser structure than the crosslinked ones, which indicated that crosslinking restricts packing of the chains before and under regeneration. From the obtained volume-weighted size distributions it was found that the crosslinked microspheres had the highest median diameter. The results demonstrate that not only the mixing ratio and distribution of the two biopolymers, but also the morphology and nanocomposite particle diameters are tunable by choosing between the different routes of preparation.

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Restructuring the Crystalline Cellulose Hydrogen Bond Network Enhances Its Depolymerization Rate

Cited by 328 publications

References 65 publications

Shotgun Approach to Increasing Enzymatic Saccharification Yields of Ammonia Fiber Expansion Pretreated Cellulosic Biomass

Shotgun Approach to Increasing Enzymatic Saccharification Yields of Ammonia Fiber Expansion Pretreated Cellulosic Biomass

Trade-off between Processivity and Hydrolytic Velocity of Cellobiohydrolases at the Surface of Crystalline Cellulose

Spherical nanocomposite particles prepared from mixed cellulose–chitosan solutions

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