Printed with a renewable-source ink on paper containing at least 50% wastepaper, including 10% post consumer waste. Cellulase C. bescii CelA, a highly active and stable enzyme, exhibits a new cellulose digestion paradigm promoting inter-cellulase synergy. C. bescii CelA, a hydrolytic enzyme with multiple functional domains, may have several advantages over other fungal and bacterial cellulases for use in biofuels production: very high specific activity, stability at elevated temperatures , and a novel digestion mechanism.
Reductive catalytic fractionation (RCF) has emerged as an effective biomass pretreatment strategy to depolymerize lignin into tractable fragments in high yields. We investigate the RCF of corn stover, a highly abundant herbaceous feedstock, using carbon-supported Ru and Ni catalysts at 200 and 250 °C in methanol and, in the presence or absence of an acid cocatalyst (H 3 PO 4 or an acidified carbon support). Three key performance variables were studied: (1) the effectiveness of lignin extraction as measured by the yield of lignin oil, (2) the yield of monomers in the lignin oil, and (3) the carbohydrate retention in the residual solids after RCF. The monomers included methyl coumarate/ferulate, propyl guaiacol/syringol, and ethyl guaiacol/syringol. The Ru and Ni catalysts performed similarly in terms of product distribution and monomer yields. The monomer yields increased monotonically as a function of time for both temperatures. At 6 h, monomer yields of 27.2 and 28.3% were obtained at 250 and 200 °C, respectively, with Ni/C. The addition of an acid cocatalysts to the Ni/C system increased monomer yields to 32% for acidified carbon and 38% for phosphoric acid at 200 °C. The monomer product distribution was dominated by methyl coumarate regardless of the use of the acid cocatalysts. The use of phosphoric acid at 200 °C or the high temperature condition without acid resulted in complete lignin extraction and partial sugar solubilization (up to 50%) thereby generating lignin oil yields that exceeded the theoretical limit. In contrast, using either Ni/C or Ni on acidified carbon at 200 °C resulted in moderate lignin oil yields of ca. 55%, with sugar retention values >90%. Notably, these sugars were amenable to enzymatic digestion, reaching conversions >90% at 96 h. Characterization studies on the lignin oils using two-dimensional heteronuclear single quantum coherence nuclear magnetic resonance and gel permeation chromatrography revealed that soluble oligomers are formed via solvolysis, followed by further fragmentation on the catalyst surface via hydrogenolysis. Overall, the results show that clear tradeoffs exist between the levels of lignin extraction, monomer yields, and carbohydrate retention in the residual solids for different RCF conditions of corn stover.
The majority of biological turnover of lignocellulosic biomass in nature is conducted by fungi, which commonly use Family 1 carbohydrate-binding modules (CBMs) for targeting enzymes to cellulose. Family 1 CBMs are glycosylated, but the effects of glycosylation on CBM function remain unknown. Here, the effects of O-mannosylation are examined on the Family 1 CBM from the Trichoderma reesei Family 7 cellobiohydrolase at three glycosylation sites. To enable this work, a procedure to synthesize glycosylated Family 1 CBMs was developed. Subsequently, a library of 20 CBMs was synthesized with mono-, di-, or trisaccharides at each site for comparison of binding affinity, proteolytic stability, and thermostability. The results show that, although CBM mannosylation does not induce major conformational changes, it can increase the thermolysin cleavage resistance up to 50-fold depending on the number of mannose units on the CBM and the attachment site. O-Mannosylation also increases the thermostability of CBM glycoforms up to 16°C, and a mannose disaccharide at Ser3 seems to have the largest themostabilizing effect. Interestingly, the glycoforms with small glycans at each site displayed higher binding affinities for crystalline cellulose, and the glycoform with a single mannose at each of three positions conferred the highest affinity enhancement of 7.4-fold. Overall, by combining chemical glycoprotein synthesis and functional studies, we show that specific glycosylation events confer multiple beneficial properties on Family 1 CBMs. chemical synthesis | cellulase | biofuels | protein engineering
Plant cell-wall polysaccharides represent a vast source of food in nature. To depolymerize polysaccharides to soluble sugars, many organisms use multifunctional enzyme mixtures consisting of glycoside hydrolases, lytic polysaccharide mono-oxygenases, polysaccharide lyases, and carbohydrate esterases, as well as accessory, redox-active enzymes for lignin depolymerization. Many of these enzymes that degrade lignocellulose are multimodular with carbohydrate-binding modules (CBMs) and catalytic domains connected by flexible, glycosylated linkers. These linkers have long been thought to simply serve as a tether between structured domains or to act in an inchworm-like fashion during catalytic action. To examine linker function, we performed molecular dynamics (MD) simulations of the Trichoderma reesei Family 6 and Family 7 cellobiohydrolases (TrCel6A and TrCel7A, respectively) bound to cellulose. During these simulations, the glycosylated linkers bind directly to cellulose, suggesting a previously unknown role in enzyme action. The prediction from the MD simulations was examined experimentally by measuring the binding affinity of the Cel7A CBM and the natively glycosylated Cel7A CBM-linker. On crystalline cellulose, the glycosylated linker enhances the binding affinity over the CBM alone by an order of magnitude. The MD simulations before and after binding of the linker also suggest that the bound linker may affect enzyme action due to significant damping in the enzyme fluctuations. Together, these results suggest that glycosylated linkers in carbohydrate-active enzymes, which are intrinsically disordered proteins in solution, aid in dynamic binding during the enzymatic deconstruction of plant cell walls. biofuels | cellulase | post-translational modification | carbohydrate recognition
Fungal cellulases and complexed cellulosomal enzymes exhibit synergistic mechanisms in cellulose deconstruction
Nature has evolved multiple enzymatic strategies for the degradation of plant cell wall polysaccharides, which are central to carbon flux in the biosphere and an integral part of renewable biofuels production.Many biomass-degrading organisms secrete synergistic cocktails of individual enzymes with one or several catalytic domains per enzyme, whereas a few bacteria synthesize large multi-enzyme complexes, termed cellulosomes, which contain multiple catalytic units per complex. Both enzyme systems employ similar catalytic chemistries; however, the physical mechanisms by which these enzyme systems degrade polysaccharides are still unclear. Here we examine a prominent example of each type, namely a freeenzyme cocktail expressed by the fungus Hypocrea jecorina and a cellulosome preparation secreted from the anaerobic bacterium Clostridium thermocellum. We observe striking differences in cellulose saccharification exhibited by these systems at the same protein loading. Free enzymes are more active on pretreated biomass and in contrast cellulosomes are much more active on purified cellulose. When combined, these systems display dramatic synergistic enzyme activity on cellulose. To gain further insights, we imaged free enzyme-and cellulosome-digested cellulose and biomass by transmission electron microscopy, which revealed evidence for different mechanisms of cellulose deconstruction by free enzymes and cellulosomes. Specifically, the free enzymes employ an ablative, fibril-sharpening mechanism, whereas cellulosomes physically separate individual cellulose microfibrils from larger particles resulting in enhanced access to cellulose surfaces. Interestingly, when the two enzyme systems are combined, we observe changes to the substrate that suggests mechanisms of synergistic deconstruction. Insight into the different mechanisms underlying these two polysaccharide deconstruction paradigms will eventually enable new strategies for enzyme engineering to overcome biomass recalcitrance. Broader contextIndustrial conversion of plant biomass into transportation fuels will likely be a vital component of the global renewable energy portfolio to reduce both greenhouse gas emissions and fossil fuel utilization for mankind's energy needs. However, plants have evolved considerable defense mechanisms against deconstruction of their cell wall polysaccharides into sugars, and as such, depolymerization to sugars for subsequent biological or catalytic conversion to fuels remains a signicant technical challenge with major cost implications in biomass conversion. In nature, many microorganisms evolved a strategy wherein plant cell wall-active enzymes are secreted as a cocktail of individual enzymes that work synergistically to depolymerize biomass, referred to as a "free enzyme" paradigm. Some ruminal microorganisms conversely evolved a strategy wherein their plant cell wall-active enzymes are tethered to large scaffolds, which are linked to the cells for sugar production in close proximity for uptake, termed the "cellulosome". Here, we mecha...
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