Cloning and Expression of Arabidopsis endo-1,4-£]-glucanase in Pichia pastoris

Chao, Shih-hsien

05 February 2010

In recent years. as industrialized society developed. people have made a lot of environment pollution problems owing to overusing fossil fuel, moreover. fossil fuel is going to deplete. As the result. the study of the substitute energy is promoted. Ligonocellulose (lignin, cellulose and hemicelluloses are included) are the most plentiful renewable resources in the nature, and it have high economic values which extensively use on food, paper and energy. Recent years, it is a hot issue that decomposing cellulose into the minimum unit called glucose, and further, fermenting into alcohol to generate biomass energy. This research goal is cloning Arabidopsis endo-1,4-£]-glucanase and transfer to Escherichia coli(DH5£\). Selection pPICZ£\A the success transferr DNA Fragment. Then to sequence and because of cell in pPICZ£\A have expression in Pichia. pastoris. AOX1 promoter have Mass productions Arabidopsis endo-1,4-£]-glucanase gene in Pichia pastoris. Carries on the extracellular expression by the methyl alcohol induction way. Can obtain recombinant DNA protein. However the Western blotting analysis demonstration has this enzyme active protein At4g11050 pellet Molecular weight about 89 KDa. Again by way of congo red and Dye-CMC assay activeness of the examination enzyme protein. The result discovers At4g11050 in the pellet cell activity compares with negative control has the obvious activity.

Pichia pastoris

endo-1, 4-£]-glucanase

Molecular cloning gene and nucleotide sequence of the gene encoding an endo-1,4-β-glucanase from Bacillus sp VLSH08 strain applying to biomass hydrolysis / Tách dòng và xác định trình tự gen endo-1,4-β – glucanase từ chủng vi khuẩn Bacillus sp VLSH08 ứng dụng để thủy phân sinh khối

Phan, Minh Thi Tuyet, Nguyen, Viet Quoc, Le, Hy Gia, Nguyen, Thoa Kim, Tran, Man Dinh

15 July 2013

Bacillus sp VLSH08 screened from sea wetland in Nam Dinh province produces an extracellular endo-1,4-beta-glucanase. According to the results of the classified Kit API 50/CHB as well as sequence of 1500 bp fragment coding for 16S rRNA gene of the Bacillus sp VLSH 08 strain showed that the taxonomical characteristics between the strain VLSH 08 and Bacillus amyloliquefaciene JN999857 are similar of 98%. Culture supernatant of this strain showed optimal cellulase activity at pH 5.8 and 60 Celsius degree and that was enhanced 2.03 times in the presence of 5 mM Co2+. Moreover, the gene encoding endo-1,4-beta-glucanase from this strain was cloned in Escherichia coli using pCR2.1 vector. The entire gene for the enzyme contained a 1500-bp single open reading frame encoding 500 amino acids, including a 29-amino acid signal peptide. The amino acid sequence of this enzyme is very close to that of an EG of Bacillus subtilis (EU022560.1) and an EG of Bacillus amyloliquefaciene (EU022559.1) which all belong to the cellulase family E2. A cocktail of enzyme containing this endo-1,4-beta-glucanase used for biomass hydrolysis indicated that the cellulose conversion attained to 72.76% cellulose after 48 hours. / Chủng vi khuẩn Bacillus sp VLSH08 được tuyển chọn từ tập hợp chủng vi khuẩn phân lập ở vùng ngập mặn tỉnh Nam Định có khả năng sinh tổng hợp enzyme endo-1,4-beta-glucanase ngoại bào. Kết quả phân loại chủng vi khuẩn Bacillus sp VLSH08 bằng Kit hóa sinh API 50/CHB cũng như trình tự gen mã hóa 16S rRNA cho thấy độ tương đồng của chủng Bacillus sp VLSH08 và chủng Bacillus amyloliquefaciene JN999857 đạt 98%. Dịch lên men của chủng được sử dụng làm nguồn enzyme thô để nghiên cứu hoạt độ tối ưu của enzyme ở pH 5,8 và nhiệt đô 60oC. Hoạt tính enzyme tăng 2,03 lần khi có mặt 5 mM ion Co2+. Đồng thời, gen mã hóa cho enzyme endo-1,4-betaglucanase cũng được tách dòng trong tế bào Escherichia coli sử dụng vector pCR 2.1. Gen mã hóa cho enzyme này có chiều dài 1500 bp, mã hóa cho 500 axit amin, bao gồm 29 axit amin của chuỗi peptid tín hiệu. So sánh cho thấy trình tự gen endo-1,4-beta-glucanase của chủng Bacillus sp VLSH08 có độ tương đồng cao với enzyme này của chủng Bacillus subtilis (EU022560.1) và của chủng Bacillus amyloliquefaciene (EU022559.1). Tất cả các enzyme nhóm này đều thuộc họ cellulase E2. Enzyme của chủng này cũng đã được phối trộn với các enzyme khác tạo thành cocktail để thủy phân sinh khối cho kết quả cellulose bị thủy phân 72,76% sau 48 giờ.

cellulase

endo-1

4-beta-glucanase

Bacillus

biomass hydrolysis

molecular cloning

ddc:660

rvk:WF 9725

Functional studies of a membrane-anchored cellulase from poplar

Jonsson Rudsander, Ulla

January 2007

Cellulose in particular and wood in general are valuable biomaterials for humanity, and cellulose is now also in the spotlight as a starting material for the production of biofuel. Understanding the processes of wood formation and cellulose biosynthesis could therefore be rewarding, and genomics and proteomics approaches have been initiated to learn more about wood biology. For example, the genome of the tree Populus trichocarpa has been completed during 2006. A single-gene approach then has to follow, to elucidate specific patterns and enzymatic details. This thesis depicts how a gene encoding a membrane-anchored cellulase was isolated from Populus tremula x tremuloides Mich, how the corresponding protein was expressed in heterologous hosts, purified and characterized by substrate analysis using different techniques. The in vivo function and modularity of the membrane-anchored cellulase was also addressed using overexpression and complementation analysis in Arabidopsis thaliana. Among 9 genes found in the Populus EST database, encoding enzymes from glycosyl hydrolase family 9, two were expressed in the cambial tissue, and the membrane-anchored cellulase, PttCel9A1, was the most abundant transcript. PttCel9A1 was expressed in Pichia pastoris, and purified by affinity chromatography and ion exchange chromatography. The low yield of recombinant protein from shake flask experiments was improved by scaling up in the fermentor. PttCel9A1 was however highly heterogenous, both mannosylated and phosphorylated, which made the protein unsuitable for crystallization experiments and 3D X-ray structure determination. Instead, a homology model using a well-characterized, homologous bacterial enzyme was built. From the homology model, interesting point mutations in the active site cleft that would highlight the functional differences of the two proteins could be identified. The real-time cleavage patterns of cello-oligosaccharides by mutant bacterial enzymes, the wildtype bacterial enzyme and PttCel9A1 were studied by 1H NMR spectroscopy, and compared with results from HPAEC-PAD analysis. The inverting stereochemistry for the hydrolysis reaction of the membrane-anchored poplar cellulase was also determined by 1H NMR spectroscopy, and it was concluded that transglycosylation in vivo is not a possible scenario. The preferred in vitro polymeric substrates for PttCel9A1 were shown to be long, low-substituted cellulose derivatives, and the endo-1,4--glucanase activity was not extended to branched or mixed linkage substrates to detectable levels. This result indicates an in vivo function in the hydrolysis of “amorphous” regions of cellulose, either during polymerization or crystallization of cellulose. In addition, overexpressing PttCel9A1 in A. thaliana, demonstrated a correlation with decreased crystallinity of cellulose. The significance of the different putative modules of PttCel9A1 was investigated by the construction of hybrid proteins, that were introduced into a knock-out mutant of A. thaliana, and the potential complementation of the phenotype was examined. A type B plant cellulase catalytic domain could not substitute for a type A plant cellulase catalytic domain, although localization and interaction motifs were added to the N- and C-terminus. / QC 20100802

Populus

cellulose biosynthesis

endo-1

4-b-glucanase

cellulase

Pichia pastoris

Arabidopsis thaliana

NMR spectroscopy

cleavage pattern

stereochemistry

transglycosylation

complementation

hybrid proteins

overexpression

substrate analysis

overglycosylation

Bioengineering

Bioteknik

Heterologous expression, characterization and applications of carbohydrate active enzymes and binding modules

Kallas, Åsa

January 2006

Wood and wood products are of great economical and environmental importance, both in Sweden and globally. Biotechnology can be used both for achieving raw material of improved quality and for industrial processes such as biobleaching. Despite the enormous amount of carbon that is fixed as wood, the knowledge about the enzymes involved in the biosynthesis, re-organization and degradation of plant cell walls is relatively limited. In order to exploit enzymes more efficiently or to develop new biotechnological processes, it is crucial to gain a better understanding of the function and mechanism of the enzymes. This work has aimed to increase the knowledge about some of the enzymes putatively involved in the wood forming processes in Populus. Xyloglucan endotransglycosylases and a putative xylanase represent transglycosylating and hydrolytic enzymes, respectively. Carbohydrate binding modules represent non-catalytic modules, which bind to the substrate. Among 24 genes encoding for putative xyloglucan endotransglycosylases or xyloglucan endohydrolases that were identified in the Populus EST database, two were chosen for further studies (PttXTH16-34 and PttXTH16-35). The corresponding proteins, PttXET16-34 and PttXET16-35, were expressed in P. pastoris, purified and biochemically characterized. The importance of the N-glycans was investigated by comparing the recombinant wild-type proteins with their deglycosylated counterparts. In order to obtain the large amounts of PttXET16-34 that were needed for crystallization and development of biotechnological applications, the conditions for the large-scale production of PttXET16-34 in a fermenter were optimized. In microorganisms, endo-(1,4)-β-xylanases are important members of the xylan degrading machinery. These enzymes are also present in plants where they might fulfill a similar, but probably more restrictive function. One putative endo-(1,4)-β-xylanase, denoted PttXYN10A, was identified in the hybrid aspen EST library. Sequence analysis shows that this protein contains three putative carbohydrate-binding modules (CBM) from family 22 in addition to the catalytic module from GH10. Heterologous expression and reverse genetics were applied in order to elucidate the function of the catalytic module as well as the binding modules of PttXYN10A. Just as in microorganisms, some of the carbohydrate active enzymes from plants have one or more CBM attached to the catalytic module. So far, a very limited number of plant CBMs has been biochemically characterized. A detailed bio-informatic analysis of the CBM family 43 revealed interesting modularity patterns. In addition, one CBM43 (CBM43PttGH17_84) from a putative Populus b-(1,3)-glucanase was expressed in E. coli and shown to bind to laminarin (β-(1,3)-glucan), mixed-linked β-(1,3)(1,4)-glucans and crystalline cellulose. Due to their high specificity for different carbohydrates, CBMs can be used as probes for the analysis of plant materials. Generally, they are more specific than both staining techniques and carbohydrate-binding antibodies. We have used cellulose- and mannan binding modules from microorganisms as tools for the analysis of intact fibers as well as processed pulps. / QC 20100903

Populus

xyloglucan endotransglycosylase

carbohydrate binding modules

endo-(1

4)-b-xylanase

Escherichia coli

Pichia pastoris

N-glycosylation

fiber analysis

Bioengineering

Bioteknik

Wood fibre and forest products

Träfiber- och virkeslära