Bacterial surface display of GFP(uv) on bacillus subtilis spores

To analyze a cotG-based Bacillus subtilis spore display system directly, GFP(uv) was expressed on the surface of Bacillus subtilis spores. When GFP(uv) was fused to the C-terminal of the cotG structural gene and expressed, the existence of a CotG-GFP(uv) fusion protein on the B. subtilis spore was confirmed by flow cytometry confocal microscopic analysis. When the cotG anchoring motif was deleted, no fluorescence emission was observed under flow cytometry and confocal microscopic analysis from the purified spore, confirming the essential role of CotG as an anchoring motif. This GFP(uv) displaying spore might be used for another signaling application triggered by intracellular or extracellular stimuli.     

Bacterial surface display of a co-factor containing enzyme, ω-transaminase from Vibrio fluvialis using the Bacillus subtilis spore display system

To improve the conventional bacterial surface display systems and to display a co-factor containing enzyme, ω-transaminase from Vibrio fluvialis, which needs pyridoxal phosphate (PLP) for efficient transamination, Bacillus subtilis spore display system with cotG, as an anchoring motif was used. Flow cytometry of the B. subtilis spore-expressing ω-transaminase proved its surface localization on the spore. The enzymatic activity of the spore expressing ω-transaminase was more than 30 times higher than that of the host spore. Protease treatment of the ω-transaminase displaying spores resulted in decreased transaminase activity, which is in keeping with the surface location of the fusion protein, CotG-ω-transaminase.     

Surface display of recombinant proteins on Bacillus thuringiensis spores

The insecticidal protoxin from Bacillus thuringiensis has been shown to be a major component of the spore coat. We have developed a novel surface display system using B. thuringiensis spores in which the N-terminal portion of the protoxin is replaced with a heterologous protein. The expression vector with a sporulation-specific promoter was successfully used to display green fluorescent protein and a single-chain antibody (scFv) gene that encodes anti-4-ethoxymethylene-2-phenyl-2-oxazolin-5-one (anti-phOx) antibody. The spores that carry the anti-phOx antibody can bind to phOx specifically.     

Plasmid-associated sensitivity of Bacillus thuringiensis to UV light

Spores and vegetative cells of Bacillus thuringiensis were more sensitive to UV light than were spores or cells of plasmid-cured B. thuringiensis strains or of the closely related Bacillus cereus. Introduction of B. thuringiensis plasmids into B. cereus by cell mating increased the UV sensitivity of the cells and spores. Protoxins encoded by one or more B. thuringiensis plasmids were not involved in spore sensitivity, since a B. thuringiensis strain conditional for protoxin accumulation was equally sensitive at the permissive and nonpermissive temperatures. In addition, introduction of either a cloned protoxin gene, the cloning vector, or another plasmid not containing a protoxin gene into a plasmid-cured strain of B. thuringiensis all increased the UV sensitivity of the spores. Although the variety of small, acid-soluble proteins was the same in the spores of all strains examined, the quantity of dipicolinic acid was about twice as high in the plasmid-containing strains, and this may account for the differences in UV sensitivity of the spores. The cells of some strains harboring only B. thuringiensis plasmids were much more sensitive than cells of any of the other strains, and the differences were much greater than observed with spores.     

Plasmid-associated sensitivity of Bacillus thuringiensis to UV light.

Spores and vegetative cells of Bacillus thuringiensis were more sensitive to UV light than were spores or cells of plasmid-cured B. thuringiensis strains or of the closely related Bacillus cereus. Introduction of B. thuringiensis plasmids into B. cereus by cell mating increased the UV sensitivity of the cells and spores. Protoxins encoded by one or more B. thuringiensis plasmids were not involved in spore sensitivity, since a B. thuringiensis strain conditional for protoxin accumulation was equally sensitive at the permissive and nonpermissive temperatures. In addition, introduction of either a cloned protoxin gene, the cloning vector, or another plasmid not containing a protoxin gene into a plasmid-cured strain of B. thuringiensis all increased the UV sensitivity of the spores. Although the variety of small, acid-soluble proteins was the same in the spores of all strains examined, the quantity of dipicolinic acid was about twice as high in the plasmid-containing strains, and this may account for the differences in UV sensitivity of the spores. The cells of some strains harboring only B. thuringiensis plasmids were much more sensitive than cells of any of the other strains, and the differences were much greater than observed with spores.     

Rapid detection of Bacillus anthracis using monoclonal antibody functionalized QCM sensor

Since the anthrax spore bioterrorism attacks in America in 2001, the early detection of Bacillus anthracis spores and vegetative cells has gained significant interest. At present, many polyclonal antibody-based quartz crystal microbalance (QCM) sensors have been developed to detect B. anthracis simulates. To achieve a simultaneous rapid detection of B. anthracis spores and vegetative cells, this paper presents a biosensor that utilizes an anti-B. anthracis monoclonal antibody designated to 8G3 (mAb 8G3, IgG) functionalized QCM sensor. Having compared four kinds of antibody immobilizations on Au surface, an optimized mAb 8G3 was immobilized onto the Au electrode with protein A on a mixed self-assembled monolayer (SAM) of 11-mercaptoundecanoic acid (11-MUA) and 6-mercaptohexan-1-ol (6-MHO) as adhesive layer. The detection of B. anthracis was investigated under three conditions: dip-and-dry, static addition and flow through procedure. The results indicated that the sensor yielded a distinct response to B. anthracis spores or vegetative cells but had no significant response to Bacillus thuringiensis species. The functionalized sensor recognized B. anthracis spores and vegetative cells specifically from its homophylic ones, and the limit of detection (LOD) reached 10(3)CFU or spores/ml of B. anthracis in less than 30 min. Cyclic voltammogram (CV) and scanning electronic microscopy (SEM) were performed to characterize the surface of the sensor in variable steps during the modification and after the detection. The mAb functionalized QCM biosensor will be helpful in the fabrication of a similar biosensor that may be available in anti-bioterrorism in the future.     

Effect of depletion of FtsY on spore morphology and the protein composition of the spore coat layer in Bacillus subtilis

Bacillus subtilis FtsY is a homolog of the alpha-subunit of mammalian signal recognition particle (SRP) receptor, and is essential for protein translocation and vegetative cell growth. An FtsY conditional null mutant (strain ISR39) can express ftsY during the vegetative stage but not during spore formation. Spores of ISR39 have the same resistance to heat and chloroform as the wild-type, while their resistance to lysozyme is reduced. Electron microscopy showed that the outer coat of spores was incompletely assembled. The coat protein profile of the ftsY mutant spores was different from that of wild-type spores. The amounts of CotA, and CotE were reduced in spore coat proteins of ftsY mutant spores and the molecular mass of CotB was reduced. In addition, CotA, CotB, and CotE are present in normal form at T(8) of sporulation in ftsY mutant cells. These results suggest that FtsY has a pivotal role in assembling coat proteins onto the coat layer during spore morphogenesis.     

Targeting of the BclA and BclB proteins to the Bacillus anthracis spore surface

The exosporium is the outermost layer of the Bacillus anthracis spore. The predominant protein on the exosporium surface is BclA, a collagen-like glycoprotein. BclA is incorporated on the spore surface late in the B. anthracis sporulation pathway. A second collagen-like protein, BclB, has been shown to be surface-exposed on B. anthracis spores. We have identified sequences near the N-terminus of the BclA and BclB glycoproteins responsible for the incorporation of these proteins into the exosporium layer of the spore and used these targeting domains to incorporate reporter fluorescent proteins onto the spore surface. The BclA and BclB proteins are expressed in the mother cell cytoplasm and become spore-associated in a two-step process involving first association of the protein with the spore surface followed by attachment of the protein in a process that involves a proteolytic cleavage event. Protein domains associated with each of these events have been identified. This novel targeting system can be exploited to incorporate foreign proteins into the exosporium of inactivated, spores resulting in the surface display of recombinant immunogens for use as a potential vaccine delivery system.     

Bacterial Surface Display of a Co-Factor Containing Enzyme, ω-Transaminase from Vibrio fluvialis Using the Bacillus subtilis Spore Display System

To improve the conventional bacterial surface display systems and to display a co-factor containing enzyme, ω-transaminase from Vibrio fluvialis, which needs pyridoxal phosphate (PLP) for efficient transamination, Bacillus subtilis spore display system with cotG, as an anchoring motif was used. Flow cytometry of the B. subtilis spore-expressing ω-transaminase proved its surface localization on the spore. The enzymatic activity of the spore expressing ω-transaminase was more than 30 times higher than that of the host spore. Protease treatment of the ω-transaminase displaying spores resulted in decreased transaminase activity, which is in keeping with the surface location of the fusion protein, CotG-ω-transaminase.     

枯草芽胞杆菌芽胞表面展示研究进展

枯草芽胞杆菌芽胞表面展示技术是把枯草芽胞杆菌作为芽胞表面展示的宿主来展示目的蛋白的一种技术。该技术不仅具备芽胞表面展示技术可展示分子量较大的目的蛋白、目的蛋白无需跨膜及芽胞的极强抗逆性等特点外,同时由于该技术的宿主菌--枯草芽胞杆菌的分子生物学信息研究得比较清楚、安全性高而被广泛应用。介绍了枯草芽胞杆菌表面展示近10年在生产疫苗和固定化酶方面的进展,并对如何提高表面展示目的蛋白的产量做了简要概述。     

Peptide ligands that bind selectively to spores of Bacillus subtilis and closely related species

As part of an effort to develop detectors for selected species of bacterial spores, we screened phage display peptide libraries for 7- and 12-mer peptides that bind tightly to spores of Bacillus subtilis. All of the peptides isolated contained the sequence Asn-His-Phe-Leu at the amino terminus and exhibited clear preferences for other amino acids, especially Pro, at positions 5 to 7. We demonstrated that the sequence Asn-His-Phe-Leu-Pro (but not Asn-His-Phe-Leu) was sufficient for tight spore binding. We observed equal 7-mer peptide binding to spores of B. subtilis and its most closely related species, Bacillus amyloliquefaciens, and slightly weaker binding to spores of the closely related species Bacillus globigii. These three species comprise one branch on the Bacillus phylogenetic tree. We did not detect peptide binding to spores of several Bacillus species located on adjacent and nearby branches of the phylogenetic tree nor to vegetative cells of B. subtilis. The sequence Asn-His-Phe-Leu-Pro was used to identify B. subtilis proteins that may employ this peptide for docking to the outer surface of the forespore during spore coat assembly and/or maturation. One such protein, SpsC, appears to be involved in the synthesis of polysaccharide on the spore coat. SpsC contains the Asn-His-Phe-Leu-Pro sequence at positions 6 to 10, and the first five residues of SpsC apparently must be removed to allow spore binding. Finally, we discuss the use of peptide ligands for bacterial detection and the use of short peptide sequences for targeting proteins during spore formation.     

Fate of Bacillus thuringiensis strains in different insect larvae

In favorable conditions Bacillus thuringiensis spores germinate and vegetative cells multiply, whereas in unfavorable conditions Bacillus thuringiensis sporulates and produces insecticidal crystal proteins. The development of B. thuringiensis strains was investigated in the larvae of insects belonging to the orders Lepidoptera and Diptera. Bacillus thuringiensis strains able to kill the insects did not always multiply in cadavers. Strains with no specificity to kill the insect sometimes multiplied when the insects were killed mechanically. These results indicate that some insect larvae represent an environment that favors the germination of B. thuringiensis spores and the multiplication of vegetative cells; however, there was no correlation between the toxin specificity and the specificity of the host.     

Biochemical studies of bacterial sporulation and germination. XII. A sulfonic acid as a major sulfur compound of Bacillus subtilis spores

A sulfonic acid found to be a major constituent of spores of Bacillus subtilis was provisionally identified as 3-l-sulfolactic acid. This compound was completely absent from vegetative cells during growth, but large amounts accumulated in sporulating cells just before the development of refractile spores. Essentially all of the accumulated sulfolactic acid was eventually incorporated into the nature spore, where it may represent more than 5% of the dry weight of the spore. Germination resulted in the rapid and complete release into the medium of unaltered sulfolactic acid. This compound was not found in spores of Bacillus megaterium, B. cereus, or B. thuringiensis.     

利用苏云金芽胞杆菌细胞表面展示系统表达禽流感病毒NP蛋白

首次利用苏云金芽胞杆菌(Bacillus thuringiensis,Bt)S-层蛋白CTC表面展示系统研究在Bt细胞表面展示禽流感病毒NP蛋白的可行性和最佳方案,为研制能常温长期保藏和运输的禽用口服疫苗奠定基础。用全长np基因或部分np基因(npp)代替S-层蛋白ctc基因的3′-端或中部,构建了4个重组质粒pSNP(含ctc-np)、pCSA-SNP(csa-ctc-np)、pCTC-NPP(ctc-npp)和pCSNPP(csa-ctc-npp)。将重组质粒分别电转化入Bt受体菌株BMB171中,获得了5个重组菌株BN、BCN、C-S、BCCN和CN。用5个重组菌株的营养细胞做玻片凝集试验,结果显示5个重组菌株均成功地在细胞表面展示了NP蛋白。用5个重组菌株的营养细胞免疫小鼠,ELISA测定血清抗体效价,结果显示5个重组菌株均具有免疫原性,其中重组菌株CN的免疫原性最高,其含融合基因csa-ctc-npp,证明该种融合基因的构建方式最佳。这为利用S-层蛋白CTC表面展示系统构建展示其它禽类病原体抗原的重组菌株以研制禽用热稳定性口服疫苗奠定了基础。     

Peptide Ligands That Bind Selectively to Spores of Bacillus subtilis and Closely Related Species

As part of an effort to develop detectors for selected species of bacterial spores, we screened phage display peptide libraries for 7- and 12-mer peptides that bind tightly to spores of Bacillus subtilis. All of the peptides isolated contained the sequence Asn-His-Phe-Leu at the amino terminus and exhibited clear preferences for other amino acids, especially Pro, at positions 5 to 7. We demonstrated that the sequence Asn-His-Phe-Leu-Pro (but not Asn-His-Phe-Leu) was sufficient for tight spore binding. We observed equal 7-mer peptide binding to spores of B. subtilis and its most closely related species, Bacillus amyloliquefaciens, and slightly weaker binding to spores of the closely related species Bacillus globigii. These three species comprise one branch on the Bacillus phylogenetic tree. We did not detect peptide binding to spores of several Bacillus species located on adjacent and nearby branches of the phylogenetic tree nor to vegetative cells of B. subtilis. The sequence Asn-His-Phe-Leu-Pro was used to identify B. subtilis proteins that may employ this peptide for docking to the outer surface of the forespore during spore coat assembly and/or maturation. One such protein, SpsC, appears to be involved in the synthesis of polysaccharide on the spore coat. SpsC contains the Asn-His-Phe-Leu-Pro sequence at positions 6 to 10, and the first five residues of SpsC apparently must be removed to allow spore binding. Finally, we discuss the use of peptide ligands for bacterial detection and the use of short peptide sequences for targeting proteins during spore formation.     

ssp Genes and spore osmotolerance in Bacillus thuringiensis israelensis and Bacillus sphaericus

It was shown previously that spores and vegetative cells of Bacillus sphaericus (Bf) and Bacillus thuringiensis israelensis (Bti) are very sensitive to osmotic variations. Since spore osmotolerance has been associated with their SASP (small acid soluble spore proteins) content coded by ssp genes, hybridization assays were performed with sspE and sspA genes from B. subtilis as probes and showed that Bti and Bf strains could lack an sspE-like gene. The B. subtilis sspE gene was then introduced into Bti 4Q2 strain; spores were obtained and showed a 65 to 650 times higher level of osmotolerance to NaCl, without affecting other important properties: hypoosmotic resistance in vegetative cells, spore UV resistance, and larvicidal activity against diptera larvae.     

Use of Yeast Spores for Microencapsulation of Enzymes

Here, we report a novel method to produce microencapsulated enzymes using Saccharomyces cerevisiae spores. In sporulating cells, soluble secreted proteins are transported to the spore wall. Previous work has shown that the spore wall is capable of retaining soluble proteins because its outer layers work as a diffusion barrier. Accordingly, a red fluorescent protein (RFP) fusion of the α-galactosidase, Mel1, expressed in spores was observed in the spore wall even after spores were subjected to a high-salt wash in the presence of detergent. In vegetative cells, however, the cell wall cannot retain the RFP fusion. Although the spore wall prevents diffusion of proteins, it is likely that smaller molecules, such as sugars, pass through it. In fact, spores can contain much higher α-galactosidase activity to digest melibiose than vegetative cells. When present in the spore wall, the enzyme acquires resistance to environmental stresses including enzymatic digestion and high temperatures. The outer layers of the spore wall are required to retain enzymes but also decrease accessibility of the substrates. However, mutants with mild spore wall defects can retain and stabilize the enzyme while still permitting access to the substrate. In addition to Mel1, we also show that spores can retain the invertase. Interestingly the encapsulated invertase has significantly lower activity toward raffinose than toward sucrose. This suggests that substrate selectivity could be altered by the encapsulation.     

Non-polar distribution of green fluorescent protein on the surface of Autographa californica nucleopolyhedrovirus using a heterologous membrane anchor

Heterogeneous proteins can be displayed on the surface of the budded form of Autographa californica nucleopolyhedrovirus (AcMNPV) after fusion of the display protein to the AcMNPV major envelope glycoprotein, gp64. However, display is restricted to the poles of the virion and is relatively low level. To investigate the use of alternative membrane anchor sequences that would be compatible with virus surface display, we have constructed a display vector containing the gp64 signal peptide and a membrane anchor from the vesicular stomatitis virus (VSV) G glycoprotein. Introduction of a gene encoding green fluorescent protein (GFP) between these signals led to abundant display of GFP on the surface of insect cells and on recombinant budded virions. In addition, and in contrast to gp64 based fusion proteins, GFP was localized to the lateral virion surfaces.     

Surface display of recombinant proteins on Bacillus subtilis spores

We developed a novel surface display system based on the use of bacterial spores. A protein of the Bacillus subtilis spore coat, CotB, was found to be located on the spore surface and used as fusion partner to express the 459-amino-acid C-terminal fragment of the tetanus toxin (TTFC). Western, dot blot and fluorescent-activated cell sorting analyses were used to monitor TTFC surface expression on purified spores. We estimated that more than 1.5 x 10(3) TTFC molecules were exposed on the surface of each spore and recognized by TTFC-specific antibodies. The efficient surface presentation of the heterologous protein, together with the simple purification procedure and the high stability and safety record of B. subtilis spores, makes this spore-based display system a potentially powerful approach for surface expression of bioactive molecules.