Lintao Bu scite author profile

Understanding the enzymatic mechanism that cellulases employ to degrade cellulose is critical to efforts to efficiently utilize plant biomass as a sustainable energy resource. A key component of cellulase action on cellulose is product inhibition from monosaccharide and disaccharides in the product site of cellulase tunnel. The absolute binding free energy of cellobiose and glucose to the product site of the catalytic tunnel of the Family 7 cellobiohydrolase (Cel7A) of Trichoderma reesei (Hypocrea jecorina) was calculated using two different approaches: steered molecular dynamics (SMD) simulations and alchemical free energy perturbation molecular dynamics (FEP/MD) simulations. For the SMD approach, three methods based on Jarzynski's equality were used to construct the potential of mean force from multiple pulling trajectories. The calculated binding free energies, −14.4 kcal/mol using SMD and −11.2 kcal/mol using FEP/MD, are in good qualitative agreement. Analysis of the SMD pulling trajectories suggests that several protein residues (Arg-251, Asp-259, Asp-262, Trp-376, and Tyr-381) play key roles in cellobiose and glucose binding to the catalytic tunnel. Five mutations (R251A, D259A, D262A, W376A, and Y381A) were made computationally to measure the changes in free energy during the product expulsion process. The absolute binding free energies of cellobiose to the catalytic tunnel of these five mutants are −13.1, −6.0, −11.5, −7.5, and −8.8 kcal/mol, respectively. The results demonstrated that all of the mutants tested can lower the binding free energy of cellobiose, which provides potential applications in engineering the enzyme to accelerate the product expulsion process and improve the efficiency of biomass conversion.

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Identification of Amino Acids Responsible for Processivity in a Family 1 Carbohydrate-Binding Module from a Fungal Cellulase

Beckham

et al. 2010

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We probe the molecular-level behavior of the Family 1 carbohydrate-binding module (CBM) from a commonly studied fungal cellulase, the Family 7 cellobiohydrolase (Cel7A) from Trichoderma reesei, on the hydrophobic face of crystalline cellulose. With a fully atomistic model, we predict that the CBM alone exhibits regions of thermodynamic stability along a cellulose chain corresponding to a cellobiose unit, which is the catalytic product of the entire Cel7A enzyme. In addition, we determine which residues and the types of interactions that are responsible for the observed processivity length scale of the CBM: Y5, Q7, N29, and Y32. These results imply that the CBM can anchor the Cel7A enzyme at discrete points along a cellulose chain and thus aid in both recognizing cellulose chain ends for initial attachment to cellulose as well as aid in enzymatic catalysis by diffusing between stable wells on a length scale commensurate with the catalytic, processive cycle of Cel7A during cellulose hydrolysis. Comparison of other Family 1 CBMs show high functional homology to the four amino acids responsible for the processivity length scale on the surface of crystalline cellulose, which suggests that Family 1 CBMs may generally employ this type of approach for translation on the cellulose surface. Overall, this work provides further insight into the molecular-level mechanisms by which a CBM recognizes and interacts with cellulose.

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An essential sensor histidine kinase controlled by transmembrane helix interactions with its auxiliary proteins

Szurmant

Brooks

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

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Two-component signal transduction systems with membrane-embedded sensor histidine kinases are believed to recognize environmental signals and transduce this information over the cellular membrane to influence the activity of a transcription factor to which they are mated. The YycG sensor kinase of Bacillus subtilis, containing two transmembrane helices, is subject to a complicated activity-control circuit involving two other proteins with N-terminal transmembrane helices, YycH and YycI. Truncation studies of YycH and YycI demonstrated that the individual transmembrane helices of these proteins are sufficient to adjust YycG activity, indicating that this control is achieved at the membrane level. A replica exchange molecular dynamics computational approach generated in silico structural models of the transmembrane helix complex that informed mutagenesis studies of the YycI transmembrane helix supporting the accuracy of the in silico model. The results predict that signal recognition by any of the extracellular domains of the sensor histidine kinase YycG or the associated proteins YycH and YycI is transmitted across the cellular membrane by subtle alterations in the positions of the helices within the transmembrane complex of the three proteins.replica exchange molecular dynamics simulation ͉ signal transduction ͉ YycG ͉ YycH ͉ YycI S ignal transduction across the cell membrane in bacteria is commonly achieved by using two-component signaltransduction systems. A signal-recognition protein, the sensor histidine kinase, is typically a transmembrane (TM) protein with the capability to sense environmental or cellular stimuli and alter its cytoplasmic autokinase activity in response to these signals. Transfer of the kinase phosphoryl group to a regulatory transcription factor activates or represses the expression of its target genes (reviewed in refs. 1 and 2).The YycFG two-component system of Bacillus subtilis is one of only a few signal-transduction systems known to be essential for cell viability in bacterial organisms, and orthologous systems are conserved by the low GϩC Gram-positive bacteria (3). The high-GϩC Gram-positive Actinomyces also conserve an essential two-component system, the MtrAB system (reviewed in ref. 4). Both the YycFG and the MtrAB systems appear to play a role in regulating cell-wall turnover and cell division in their respective organisms, suggesting that most, if not all, Gram-positive organisms have embedded a two-component signal-transduction system in the regulation of these important processes.The YycFG two-component system has been extensively studied in B. subtilis, Staphylococcus aureus, and Streptococcus pneumoniae. Recent work established the YycF regulon (i.e., the genes whose expression is controlled by this system) in these bacteria (5-7). The majority of gene products under YycF control in all three organisms are involved in cell-wall metabolism, although the precise genes differ from organism to organism. In B. subtilis, the essential cell division proteins FtsZ and FtsA are als...

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The Energy Landscape for the Interaction of the Family 1 Carbohydrate-Binding Module and the Cellulose Surface is Altered by Hydrolyzed Glycosidic Bonds

Beckham

Crowley

et al. 2009

J. Phys. Chem. B

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A multiscale simulation model is used to construct potential and free energy surfaces for the carbohydrate-binding module [CBM] from an industrially important cellulase, Trichoderma reesei cellobiohydrolase I, on the hydrophobic face of a coarse-grained cellulose Ibeta polymorph. We predict from computation that the CBM alone exhibits regions of stability on the hydrophobic face of cellulose every 5 and 10 A, corresponding to a glucose unit and a cellobiose unit, respectively. In addition, we predict a new role for the CBM: specifically, that in the presence of hydrolyzed cellulose chain ends, the CBM exerts a thermodynamic driving force to translate away from the free cellulose chain ends. This suggests that the CBM is not only required for binding to cellulose, as has been known for two decades, but also that it has evolved to both assist the enzyme in recognizing a cellulose chain end and exert a driving force on the enzyme during processive hydrolysis of cellulose.

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Lintao Bu

Probing Carbohydrate Product Expulsion from a Processive Cellulase with Multiple Absolute Binding Free Energy Methods

Identification of Amino Acids Responsible for Processivity in a Family 1 Carbohydrate-Binding Module from a Fungal Cellulase

An essential sensor histidine kinase controlled by transmembrane helix interactions with its auxiliary proteins

The Energy Landscape for the Interaction of the Family 1 Carbohydrate-Binding Module and the Cellulose Surface is Altered by Hydrolyzed Glycosidic Bonds

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