通过在嗜热纤维梭菌 Cel9A 的家族 9 催化结构域和家族 3c 纤维素结合模块中的氨基酸变化组合来提高结晶纤维素活性。
Increased crystalline cellulose activity via combinations of amino acid changes in the family 9 catalytic domain and family 3c cellulose binding module of Thermobifida fusca Cel9A.
机构信息
Bioenergy Science Center, Oak Ridge National Laboratory, Oak Ridge, Tennessee 37831, USA.
出版信息
Appl Environ Microbiol. 2010 Apr;76(8):2582-8. doi: 10.1128/AEM.02735-09. Epub 2010 Feb 19.
Abstract
Amino acid modifications of the Thermobifida fusca Cel9A-68 catalytic domain or carbohydrate binding module 3c (CBM3c) were combined to create enzymes with changed amino acids in both domains. Bacterial crystalline cellulose (BC) and swollen cellulose (SWC) assays of the expressed and purified enzymes showed that three combinations resulted in 150% and 200% increased activity, respectively, and also increased synergistic activity with other cellulases. Several other combinations resulted in drastically lowered activity, giving insight into the need for a balance between the binding in the catalytic cleft on either side of the cleavage site, as well as coordination between binding affinity for the catalytic domain and CBM3c. The same combinations of amino acid variants in the whole enzyme, Cel9A-90, did not increase BC or SWC activity but did have higher filter paper (FP) activity at 12% digestion.
摘要
木霉属热纤梭菌 Cel9A-68 催化结构域或碳水化合物结合模块 3c(CBM3c)的氨基酸修饰与另一个结构域中的氨基酸变化相结合,从而创造出具有改变的氨基酸的酶。表达和纯化的酶的细菌结晶纤维素(BC)和溶胀纤维素(SWC)测定表明,三种组合分别使活性分别提高了 150%和 200%,并且还增加了与其他纤维素酶的协同活性。其他几种组合导致活性急剧下降,深入了解了在切割位点两侧的催化裂缝中结合的平衡以及对催化结构域和 CBM3c 的结合亲和力之间的协调的必要性。整个酶 Cel9A-90 中的相同氨基酸变体组合并未增加 BC 或 SWC 的活性,但在 12%的消化水平下滤纸(FP)活性更高。
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