3.Visualization method of type Ⅳ pili and its application in the study of pili function.
Chinese Journal of Biotechnology 2023;39(11):4534-4549
As an important protein structure on the surface of bacteria, type Ⅳ pili (TFP) is the sensing and moving organ of bacteria. It plays a variety of roles in bacterial physiology, cell adhesion, host cell invasion, DNA uptake, protein secretion, biofilm formation, cell movement and electron transmission. With the rapid development of research methods, technical equipment and pili visualization tools, increasing number of studies have revealed various functions of pili in cellular activities, which greatly facilitated the microbial single cell research. This review focuses on the pili visualization method and its application in the functional research of TFP, providing ideas for the research and application of TFP in biology, medicine and ecology.
Fimbriae, Bacterial/metabolism*
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Bacterial Proteins/genetics*
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Bacterial Physiological Phenomena
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Bacterial Adhesion/physiology*
4.Surface display of GFP using CotX as a molecular vector on Bacillus subtilis spores.
Qian LI ; Degang NING ; Chundu WU
Chinese Journal of Biotechnology 2010;26(2):264-269
Spore coat proteins, such as CotB, CotC, CotG et al, are able to efficiently display exogenous protein on spore surface for preparing oral vaccines or enzymes. CotX is another structural protein of spore coats of Bacillus subtilis. To investigate whether CotX could carry target protein onto the spore surface, we constructed a recombinant integrative plasmid, designated as pJS749, which carries a recombinant cotX-gfp gene under the control of the cotX promoter. We transformed pJS749 into Bacillus subtilis 168(trp-), an alpha-amylase inactivated mutant DRJS749 was selected and confirmed to be a double crossover integrant, where cotX-gfp fragment was integrated into the chromosome. After induction of spore formation, significant green fluorescence was observed on spore surface of strain DRJS749 under fluorescent microcopy. This suggests that CotX is associated with the outer part of the coat. CotX can therefore be used as a molecular vehicle for spore surface display of exogenous proteins.
Bacillus subtilis
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genetics
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metabolism
;
physiology
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Bacterial Proteins
;
biosynthesis
;
genetics
;
Gene Expression Regulation, Bacterial
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Green Fluorescent Proteins
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biosynthesis
;
genetics
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Recombinant Fusion Proteins
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biosynthesis
;
genetics
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Spores, Bacterial
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genetics
;
metabolism
5.Characterization and identification of Lactobacillus fermentum 4,6-α-glucosyltransferase and its products.
Lufei SHENG ; Weikang YANG ; Jing WU ; Sheng CHEN
Chinese Journal of Biotechnology 2021;37(12):4363-4372
4,6-α-glucosyltransferases (4,6-α-GTs), which converts amylose into α(1-6) bonds-containing α-glucan, possesses great application potential in enzymatic synthesis of dietary fiber. Primers were designed according to the conserved motifs existing in the amino acid sequence of 4,6-α-GTs, and used to amplify a putative GTFB-Like 4,6-α-GTs gene (named as gtf16) from the genomic DNA of Lactobacillus. The gtf16 gene was cloned into the plasmid pET15b, expressed in Escherichia coli BL21(DE3), followed by purification and characterization. The optimum pH and the optimum temperature of the purified enzyme were 5.0 and 40 °C, respectively. The biotransformation product of this enzyme was systematically characterized by thin-layer chromatography, NMR spectroscopy, and hydrolysis reaction. The Gtf16-catalyzed product shows a similar structure to that of the isomalto/malto-polysaccharide (IMMP), which is the amylose-derived product catalyzed by GtfB from Lactobacillus reuteri 121. Moreover, The Gtf16-catalyzed product contains up to 75% of α(1-6) bonds and has an average molecular weight of 23 793 Da. Furthermore, the content of the anti-digestive components was 88.22% upon hydrolysis with digestive enzymes.
Bacterial Proteins/genetics*
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Glucans
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Glucosyltransferases/genetics*
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Lactobacillus fermentum/enzymology*
6.Bt transgenic crops for insect-resistance and modification of Bt protein and utilization of stacking strategy.
Chinese Journal of Biotechnology 2015;31(1):53-64
Insecticidal protein genes from Bacillus thuringiensis are currently the most widely used insect-resistant genes. They have been transferred to many crops for breeding and production. Among them, cotton, maize, potato and other insect-resistant crops are commercialized, creating considerable economic benefit. In this review, we summarized advances in identifying functional genes and transgenic crops for insect resistance, compared different strategies for enhancing vigor of insecticidal protein and utilizing gene stacking as well as listing valuable groups of stacked genes. In addition, the methods for multiple gene transformation was discussed.
Animals
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Bacterial Proteins
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genetics
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Crops, Agricultural
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genetics
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Endotoxins
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genetics
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Hemolysin Proteins
;
genetics
;
Insecta
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Plants, Genetically Modified
7.Molecular chaperones facilitate soluble expression of recombinant non-toxic mutant CRM197 of diphtheria toxin in Escherichia coli.
Mengting YANG ; Xiaoxiao LI ; Chen LIN ; Mingjing LIU ; Yezi CHEN ; Yun ZHAO ; Chaoqi LIU
Chinese Journal of Biotechnology 2021;37(4):1368-1375
Diphtheria toxin is an ADP-ribosyltransferase toxic to human cells. Mutation of the active site in its catalytic domain eliminates the toxicity, but retains its immunogenicity. A non-toxic mutant of diphtheria toxin known as CRM197 protein has become an ideal carrier protein for conjugate vaccines. CRM197 can further improve its immunogenicity by cross-linking with other antigens, so it has good potential to find broad applications. Unfortunately, inclusion bodies are easily formed during the expression of recombinant CRM197 protein in Escherichia coli, which greatly reduces its yield. In order to address this problem, pG-KJE8 vector carrying molecular chaperones and plasmid pET28a-CRM197, were co-expressed in Escherichia coli. The results showed that the recombinant CRM197 protein was successfully expressed and appeared largely in inclusion bodies. The molecular chaperones DnaK, DnaJ, GrpE, GroES and GroEL5 expressed can facilitate correct and rapid folding of CRM197. Furthermore, it can also improve the recovery rate of soluble CRM197 protein. The soluble expression of CRM197 was maximized upon addition of 1.0 mmol/L IPTG, 0.5 mg L-arabinose, 5.0 ng/mL tetracycline and induction at 20oC for 16 h. The soluble CRM197 protein shows good immunoreactivity, demonstrating the molecular chaperones expressed from pG-KJE8 facilitated the soluble expression of CRM197 protein in E. coli.
Bacterial Proteins
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Diphtheria Toxin/genetics*
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Escherichia coli/genetics*
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Humans
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Molecular Chaperones/genetics*
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Recombinant Proteins/genetics*
8.The role of bacterial toxin-antitoxin systems in phage abortive infections.
Yang HAI ; Xiaoyu WANG ; Jianping XIE
Chinese Journal of Biotechnology 2022;38(9):3291-3300
Bacteria are often infected by large numbers of phages, and host bacteria have evolved diverse molecular strategies in the race with phages, with abortive infection (Abi) being one of them. The toxin-antitoxin system (TA) is expressed in response to bacterial stress, mediating hypometabolism and even dormancy, as well as directly reducing the formation of offspring phages. In addition, some of the toxins' sequences and structures are highly homologous to Cas, and phages even encode antitoxin analogs to block the activity of the corresponding toxins. This suggests that the failure of phage infection due to bacterial death in abortive infections is highly compatible with TA function, whereas TA may be one of the main resistance and defense forces for phage infestation of the host. This review summarized the TA systems involved in phage abortive infections based on classification and function. Moreover, TA systems with abortive functions and future use in antibiotic development and disease treatment were predicted. This will facilitate the understanding of bacterial-phage interactions as well as phage therapy and related synthetic biology research.
Anti-Bacterial Agents
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Antitoxins/chemistry*
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Bacteria/genetics*
;
Bacterial Proteins/chemistry*
;
Bacterial Toxins/genetics*
;
Bacteriophages/genetics*
;
Toxin-Antitoxin Systems/genetics*
9.Clustered regularly interspaced short palindromic repeat associated protein genes cas1 and cas2 in Shigella.
Zerun XUE ; Yingfang WANG ; Guangcai DUAN ; Pengfei WANG ; Linlin WANG ; Xiangjiao GUO ; Yuanlin XI
Chinese Journal of Epidemiology 2014;35(5):581-584
OBJECTIVETo detect the distribution of clustered regularly interspaced short palindromic repeat (CRISPR) associated protein genes cas1 and cas2 in Shigella and to understand the characteristics of CRISPR with relationship between CRISPR and related characteristics on drug resistance.
METHODSCRISPR associated protein genes cas1 and cas2 in Shigella were detected by PCR, with its products sequenced and compared.
RESULTSThe CRISPR-associated protein genes cas1 and cas2 were found in all the 196 Shigella isolates which were isolated at different times and locations in China. Consistencies showed through related sequencing appeared as follows: cas2, cas1 (a) and cas1 (b) were 96.44%, 97.61% and 96.97%, respectively. There were two mutations including 3177129 site(C→G)and 3177126 site (G→C) of cas1 (b) gene in 2003135 strain which were not found in the corresponding sites of Z23 and 2008113.
RESULTSshowed that in terms of both susceptibility and antibiotic-resistance, strain 2003135 was stronger than Z23 and 2008113.
CONCLUSIONCRISPR system widely existed in Shigella, with the level of drug resistance in cas1 (b) gene mutant strains higher than in wild strains. Cas1 (b) gene mutation might be one of the reasons causing the different levels of resistance.
Bacterial Proteins ; genetics ; CRISPR-Associated Proteins ; genetics ; Clustered Regularly Interspaced Short Palindromic Repeats ; Drug Resistance, Bacterial ; genetics ; Mutation ; Shigella ; genetics
10.Discovery, structure and function of plasmid mediated shufflon.
Tian YI ; Yang WANG ; Jianzhong SHEN ; Congming WU ; Yingbo SHEN
Chinese Journal of Biotechnology 2023;39(1):34-44
Antimicrobial resistance has become a major public health issue of global concern. Conjugation is an important way for fast spreading drug-resistant plasmids, during which the type Ⅳ pili plays an important role. Type Ⅳ pili can adhere on the surfaces of host cell and other medium, facilitating formation of bacterial biofilms, bacterial aggregations and microcolonies, and is also a critical factor in liquid conjugation. PilV is an adhesin-type protein found on the tip of type Ⅳ pili encoded by plasmid R64, and can recognize the lipopolysaccharid (LPS) molecules that locate on bacterial membrane. The shufflon is a clustered inversion region that diversifies the PilV protein, which consequently affects the recipient recognition and conjugation frequency in liquid mating. The shufflon was firstly discovered on an IncI1 plasmid R64 and has been identified subsequently in plasmids IncI2, IncK and IncZ, as well as the pathogenicity island of Salmonella typhi. The shufflon consists of four segments including A, B, C, and D, and a specific recombination site named sfx. The shufflon is regulated by its downstream-located recombinase-encoding gene rci, and different rearrangements of the shufflon region in different plasmids were observed. Mobile colistin resistance gene mcr-1, which has attracted substantial attentions recently, is mainly located in IncI2 plasmid. The shufflon may be one of the contributors to fast spread of mcr-1. Herein, we reviewed the discovery, structure, function and prevalence of plasmid mediated shufflon, aiming to provide a theoretical basis on transmission mechanism and control strategy of drug-resistant plasmids.
Plasmids/genetics*
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Proteins/genetics*
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Bacteria/genetics*
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Recombinases
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Genes, Bacterial
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Anti-Bacterial Agents