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Towards cellulose consolidated bioprocessing into biofuel through | 7537
Current Synthetic and Systems Biology

Current Synthetic and Systems Biology
Open Access

ISSN: 2332-0737

+44-20-4587-4809

Towards cellulose consolidated bioprocessing into biofuel through recombinant Clostridium cellulovorans: Detailed analysis of the central metabolism and development of optimized gene manipulation tools


2nd International Conference on Systems & Synthetic Biology

August 18-20, 2016 London, UK

Chiara Gandini, Loredana Tarraran, Cinzia Bertea, Andrea Occhipinti, Alfredo Braustein, Andrea Pagnani, Anna Luganini and Roberto Mazzoli

University of Torino, Italy
Polytechnic of Torino, Italy

Scientific Tracks Abstracts: Curr Synthetic Sys Biol

Abstract :

Consolidated Bioprocessing (CBP) is a key feature of the so-called 3rd generation biorefinery consisting of cost-sustainable single-step (direct) fermentation of cellulosic biomass into industrially relevant products such as biofuels (notably, ethanol and or butanol). No natural microorganism isolated so far can produce biofuels directly from cellulose with the efficiency required by industrial processes. Clostridium cellulovorans is an anaerobic bacterium among the most efficient plant biomass biodegraders. It efficiently hydrolyzes cellulose, xylan and pectin, but its main catabolites are organic acids, while little ethanol is biosynthesized. The final aim of the present study is the development of recombinant ethanol and or butanol hyper producing C. cellulovorans strains by metabolic engineering. Achievement of this purpose is currently hampered by major hurdles. Nowadays, no detailed study on C. cellulovorans central metabolic pathways exists. Furthermore, no specific tools for C. cellulovorans chromosomal gene knock out/in are available. The present contribution was focused on the development of a model of the C. cellulovorans central metabolism by integration of metabolomics, transcriptomics and proteomics data. Attention was mainly given to comparison of C. cellulovorans metabolic network during growth on cellulose with respect to cells growing on soluble sugars. As far as the development of optimized gene tools for C. cellulovorans is concerned, different transformation protocols were compared. Furthermore, the ClosTron methodology was used as a basis for developing reliable protocol for gene integration in the C. cellulovorans chromosome. These results will be a key for future C. cellulovorans metabolic pathway engineering aimed at direct conversion of cellulose to biofuels.

Biography :

Chiara Gandini has completed her MSc in Industrial Biotechnology in 2012. She is Coauthor of an international patent. She has been working in Biochemistry Laboratory of Department of Life Sciences and Systems Biology, University of Torino, on microorganism’s metabolic engineering since 2012.

Email: chiara.gandini@unito.it

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