Hydrolysis of cellulose using cellulase physically immobilized on highly stable zirconium based metal-organic frameworks

Bioresour Technol. 2018 Dec:270:377-382. doi: 10.1016/j.biortech.2018.09.077. Epub 2018 Sep 15.

Abstract

Developing a new cellulase-MOF composite system with enhanced stability and reusability for cellulose hydrolysis was aimed. Physical adsorption strategy was employed to fabricate two cellulase composites, and the activity of composite was characterized by hydrolysis of carboxymethyl cellulose. The NH2 functionalized UiO-66-NH2 MOF exhibited higher protein loading than the precursor UiO-66, due to the extra anchor sites of NH2 groups. The immobilized cellulase showed enhanced thermostability, pH tolerance and lifetime. The maximum activity attained at 55 °C could be kept 85% when used at 80 °C, and the residual activities were 72% after ten cycles and 65% after 30 days storage. The abundant NH2 and COOH groups of MOF adsorb cellulase and enhance its stability, and the resulted heterogeneity offered the opportunity of recovering composite via mild centrifuge. The findings suggest the promising future of developing cellulase-MOF composite with ultrahigh activities and stabilities for practical application.

Keywords: Cellulase; Hydrolysis; Immobilization; Metal-organic frameworks.

MeSH terms

  • Adsorption
  • Cellulase / metabolism*
  • Cellulose / chemistry
  • Cellulose / metabolism*
  • Hydrolysis
  • Metal-Organic Frameworks / chemistry*
  • Zirconium / chemistry*

Substances

  • Metal-Organic Frameworks
  • Cellulose
  • Zirconium
  • Cellulase