Structural studies of carbohydrate-binding modules

Simpson, Peter James

January 2000

No description available.

572

Xylanase; Cellulomonas fimi; Enzymes

Design and construction of modular genetic devices and the enzymatic hydrolysis of lignocellulosic biomass

Barnard, Damian Kelly

January 2012

The enzymatic deconstruction of lignocellulosic plant biomass is performed by specialist microbial species. It is a ubiquitous process within nature and central to the global recycling of carbon and energy. Lignocellulose is a complex heteropolymer, highly recalcitrant and resistant to hydrolysis due to the major polysaccharide cellulose existing as a crystalline lattice, intimately associated with a disordered sheath of hemicellulosic polysaccharides and lignin. In this thesis I aim to transfer the highly efficient cellulolytic mechanism of the bacterium Cellulomonas fimi, to that of a suitably amenable and genetically tractable expression host, in the hopes of better understanding the enzymatic hydrolysis of lignocellulose. Using tools and concepts from molecular biology and synthetic biology, I constructed a library of standardised genetic parts derived from C. fimi, each encoding a known enzymatic activity involved in the hydrolysis of cellulose, mannan or xylan; three of the major polysaccharides present in lignocellulose. Characterization assays were performed on individual parts to confirm enzymatic activity and compare efficiencies against a range of substrates. Results then informed the rational design and construction of parts into modular devices. The resultant genetic devices were introduced into the expression hosts Escherichia coli and Citrobacter freundii, and transformed strains were assayed for the ability to utilize various forms of xylan, mannan and cellulose as a sole carbon source. Results identified devices which when expressed by either host showed growth on the respective carbon sources. Notably, devices with improved activity against amorphous cellulose, crystalline cellulose, mannan and xylan were determined. Recombinant cellulase expressing strains of E. coli and C. freundii were shown capable of both deconstruction and utilization of pure cellulose paper as a sole carbon source. Moreover, this capacity was shown to be entirely unhindered when C. freundii strains were cultured in saline media. These findings show promise in developing C. freundii for bioprocessing of biomass in sea water, so as to reduce the use of fresh water resources and improve sustainability as well as process economics. Work presented in this thesis contributes towards understanding the complementarities and synergies of the enzymes responsible for lignocellulose hydrolysis. Moreover, the research emphasizes the merits of standardizing genetic parts used within metabolic engineering projects and how adopting such design principles can expedite the research process.

621.31

The expression of cellulomomas fimi cellulase genes in Brevibacterium lactofermentum and characterization of recombinant C. fimi B-glucosidase A from E coli

Paradis, François William François William

January 1990

In the first part of this thesis, I describe the expression of C. fimi cellulase genes in the closely related Brevibacterium lactofermentum by generating a shuttle vector able to replicate selectively in the latter and carrying full length cellulase-encoding genes. The expression of those genes apparently originated from some unpredicted regulatory sequences, possibly located within the vector itself. The enzymatic activity was mostly found in the culture medium in B. lactofermentum indicating that the organism secreted the enzymes. The putative C. fimi promoter sequences did not function in B. lactofermentum, making difficult the analysis of their roles in expression of C. fimi cellulase genes. In the second part of this thesis, I describe the characterization of a recombinant C. fimi exo-ϐ-1,4-glucosidase (CbgA) expressed in E. coli. The purified enzyme had a Mr of 183 kDa and hydrolysed various ϐ-glucosides with a preference for cello-oligosaccharides in the order C5>C4>C3>C2. The intact CbgA polypeptide was not required for enzymatic activity since removal of about 700 residues from the amino terminus did not reduce activity. The purified enzyme was used to raise polyclonal antibodies which in turn were used to identify the corresponding enzyme in C. fimi. During the fractionation of C. fimi ϐ-glucosidases, several enzymes hydrolyzing various ϐ-glucosides were isolated together with the native CbgA, which was present in the culture medium as part of a protein aggregate. Part of the nucleotide sequence of the 7.2 kb insert was determined. Alignments of the N-terminal amino acid sequences of the purified CbgA and truncated polypeptides with the partial nucleotide sequence of the cloned C. fimi DNA showed that precise excision was responsible for the appearance of a truncated form of CbgA. Alignment of the amino-terminal sequence of a CbgA:CexCBD fusion peptide indicated that the pre-mature CbgA starts with a putative leader sequence of 49 amino acids which is followed by a region rich in Pro and Ala residues. Two GTG translational initiation codons followed by sequences resemblingprokaryotic ribosome binding sites and separated by a large open reading frame were identified from data obtained after in vitro site-directed mutagenesis of the most upstream initiation codon suggesting that internal re-initiation may occur and that upstream regulatory sequences had not been isolated. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Cellulomonas fimi

Gene expression

Gene Expression

Degradation of cellulosic material by Cellulomonas fimi

Kane, Steven Daniel

January 2015

The world stocks of fossil fuels are dwindling and may be all but out before the end of the century. Despite this there is increasing demand for them to be used for transport, and the ever increasing green house gases which their use produces. Renewable and less environmentally damaging forms of fuel are needed. Biofuels, particularly bioethanol, are a possibility to subsidise or replace fossil fuels altogether. Ethanol produced from fermentation of starch sugars from corn are already in wide use. As this bioethanol is currently produced from crops such as corn and sugar cane, that puts fuel crops in direct competition for space and resources with food crops. This has led to increases in food prices and the search for more arable land. Hydrolysis of lignocellulosic biomass, a waste by-product of many industries, to produce the sugars necessary for ethanol production would ease many of the problems with current biofuels. Degradation of lignocellulose is not simple and requires expensive chemical pre-treatments and large quantities of enzymes usually from fungal species making it about 10 times more expensive to produce than corn starch bioethanol. The production of a consolidated bioprocessor, an organism able to degrade, metabolise and ferment cellulosic material to produce ethanol or other useful products would greatly reduce the cost currently associated with lignocellulosic biofuel. Cellulomonas fimi ATCC 484 is an actinomycete soil bacterium able to degrade efficiently cellulosic material. The US Department of Energy (DOE) released the genome sequence at the start of 2012. In this thesis the released genome has been searched, for genes annotated as encoding polysaccharide degrading enzymes as well as for metabolic pathways. Over 100 genes predicted to code for polysaccharide hydrolysing enzymes were identified. Fifteen of these genes have been cloned as BioBricks, the standard synthetic biology functional unit, expressed in E. coli and C. freundii and assayed for endo β-1,4-glucanase activity using RBB-CMC, endo β-1,4-xylanase activity using RBB-xylan, β-D-xylosidase activity using ONPX, β-D-cellobiohydrolase activity using ONPC and α-L-arabinofuranosidase activity using PNPA. Eleven enzymes not previously reported from C. fimi were identified as active on a substrate with the strongest activities being for 2 arabinofuranosidases (AfsA+B), 4 β-xylosidases (BxyC, BxyF, CelE and XynH), an endoglucanase (CelA), and 2 multifunctional enzymes CelD and XynF, active as cellobiohydrolases, xylosidases and endoxylanases. Four enzymes were purified from E. coli cell lysates and characterised. It was found that AfsB has an optimum activity at pH 6.5 and 45ºC, BxyF has optimum activity at pH 6.0 and 45ºC and XynH has optimum activity at pH 9.0 and 80ºC. XynF exhibited different optima for the 3 substrates with pH 6.0 and 60ºC for ONPC, pH 4.5 and 50ºC for ONPX and pH 5.5 and 40ºC for RBB-xylan. Searching the genome and screening genes for activities will help genome annotation in the future by increasing the number of positively annotated genes in the databases. The BioBrick format is well suited for rapid cloning and expression of genes to be classified. Searching and screening the genome has also given insights into the complex and large network of enzymes required to fully hydrolyse and metabolise the sugars released from lignocellulose. These enzymes are spread across many different glycosyl hydrolase families conferring different catalytic activities. The characterisation of these novel enzymes points towards a system adapted to not only a broad specificity of substrate but also environmental factors such as high temperature and pH. Genomic analysis revealed gene clusters and traits which could be used in the design of a synthetic cellulolytic network, or for the conversion of C. fimi into a consolidated bioprocessor itself.

572