TY - JOUR
T1 - Processive enzymes kept on a leash
T2 - How cellulase activity in multienzyme complexes directs nanoscale deconstruction of cellulose
AU - Zajki-Zechmeister, Krisztina
AU - Kaira, Gaurav Singh
AU - Eibinger, Manuel
AU - Seelich, Klara
AU - Nidetzky, Bernd
N1 - Publisher Copyright:
© 2021 The Authors. Published by American Chemical Society
PY - 2021/11/5
Y1 - 2021/11/5
N2 - Biological deconstruction of polymer materials gains efficiency from the spatiotemporally coordinated action of enzymes with synergetic function in polymer chain depolymerization. To perpetuate enzyme synergy on a solid substrate undergoing deconstruction, the overall attack must alternate between focusing the individual enzymes locally and dissipating them again to other surface sites. Natural cellulases working as multienzyme complexes assembled on a scaffold protein (the cellulosome) maximize the effect of local concentration yet restrain the dispersion of individual enzymes. Here, with evidence from real-time atomic force microscopy to track nanoscale deconstruction of single cellulose fibers, we show that the cellulosome forces the fiber degradation into the transversal direction, to produce smaller fragments from multiple local attacks (“cuts”). Noncomplexed enzymes, as in fungal cellulases or obtained by dissociating the cellulosome, release the confining force so that fiber degradation proceeds laterally, observed as directed ablation of surface fibrils and leading to whole fiber “thinning”. Processive cellulases that are enabled to freely disperse evoke the lateral degradation and determine its efficiency. Our results suggest that among natural cellulases, the dispersed enzymes are more generally and globally effective in depolymerization, while the cellulosome represents a specialized, fiber-fragmenting machinery.
AB - Biological deconstruction of polymer materials gains efficiency from the spatiotemporally coordinated action of enzymes with synergetic function in polymer chain depolymerization. To perpetuate enzyme synergy on a solid substrate undergoing deconstruction, the overall attack must alternate between focusing the individual enzymes locally and dissipating them again to other surface sites. Natural cellulases working as multienzyme complexes assembled on a scaffold protein (the cellulosome) maximize the effect of local concentration yet restrain the dispersion of individual enzymes. Here, with evidence from real-time atomic force microscopy to track nanoscale deconstruction of single cellulose fibers, we show that the cellulosome forces the fiber degradation into the transversal direction, to produce smaller fragments from multiple local attacks (“cuts”). Noncomplexed enzymes, as in fungal cellulases or obtained by dissociating the cellulosome, release the confining force so that fiber degradation proceeds laterally, observed as directed ablation of surface fibrils and leading to whole fiber “thinning”. Processive cellulases that are enabled to freely disperse evoke the lateral degradation and determine its efficiency. Our results suggest that among natural cellulases, the dispersed enzymes are more generally and globally effective in depolymerization, while the cellulosome represents a specialized, fiber-fragmenting machinery.
KW - Cellulose
KW - Complexed and noncomplexed cellulases
KW - Enzyme assembly
KW - Enzyme synergy
KW - Polymer deconstruction
KW - Processive depolymerization
UR - http://www.scopus.com/inward/record.url?scp=85118898746&partnerID=8YFLogxK
U2 - 10.1021/acscatal.1c03465
DO - 10.1021/acscatal.1c03465
M3 - Article
AN - SCOPUS:85118898746
SN - 2155-5435
VL - 11
SP - 13530
EP - 13542
JO - ACS Catalysis
JF - ACS Catalysis
IS - 21
ER -