A new method for total hydrolysis of cellulose using a chemo-enzymatic system to combine chemical depolymerization and enzymatic hydrolysis, is described in this paper. The approach described herein involves the dissolution of cellulose in an ionic liquid, depolymerization by acidic solid-catalyst, and use of an antisolvent to obtain the resulting cello-oligomers. These were subjected to chemical depolymerization, after which virtually all the soluble cello-oligomers were hydrolyzed to glucose by beta-1,4-D-glucan glucohydrolase. This glucohydrolase is newly identified from a species of Paenibacillus (HPL-001), and is different from commercial beta-1,4-D-glucosidase. Continuous recycling (99%) of ionic acid and organic solvent completely broke down the cellulose into cello-oligomers (soluble sugars) shorter than six anhydrous glucose units. The cello-oligomers of soluble sugars were easily connected to a new single enzyme system for complete hydrolysis to glucose. The efficiency of this technology could solve the dissolution and selective deconstruction problem retarding the major production of glucose from cellulose, and could provide a crucial advance in the production of un-degraded glucose as final product. This approach provides an alternative techno-economic process to traditional, expensive, three-enzyme hydrolysis of cellulose. (C) 2016 Elsevier Ltd. All rights reserved.