Molecular characterization of the S-layer gene,sbpA, of Bacillus sphaericus CCM 2177 and production of a functional S-layer fusion protein with the ability to recrystallize in a defined orientation while presenting the fused allergen

The nucleotide sequence encoding the crystalline bacterial cell surface (S-layer) protein SbpA of Bacillus sphaericus CCM 2177 was determined by a PCR-based technique using four overlapping fragments. The entire sbpA sequence indicated one open reading frame of 3,804 bp encoding a protein of 1,268 amino acids with a theoretical molecular mass of 132,062 Da and a calculated isoelectric point of 4.69. The N-terminal part of SbpA, which is involved in anchoring the S-layer subunits via a distinct type of secondary cell wall polymer to the rigid cell wall layer, comprises three S-layer-homologous motifs. For screening of amino acid positions located on the outer surface of the square S-layer lattice, the sequence encoding Strep-tag I, showing affinity to streptavidin, was linked to the 5' end of the sequence encoding the recombinant S-layer protein (rSbpA) or a C-terminally truncated form (rSbpA(31-1068)). The deletion of 200 C-terminal amino acids did not interfere with the self-assembly properties of the S-layer protein but significantly increased the accessibility of Strep-tag I. Thus, the sequence encoding the major birch pollen allergen (Bet v1) was fused via a short linker to the sequence encoding the C-terminally truncated form rSpbA(31-1068). Labeling of the square S-layer lattice formed by recrystallization of rSbpA(31-1068)/Bet v1 on peptidoglycan-containing sacculi with a Bet v1-specific monoclonal mouse antibody demonstrated the functionality of the fused protein sequence and its location on the outer surface of the S-layer lattice. The specific interactions between the N-terminal part of SbpA and the secondary cell wall polymer will be exploited for an oriented binding of the S-layer fusion protein on solid supports to generate regularly structured functional protein lattices.     

Construction of a Functional S-Layer Fusion Protein Comprising an Immunoglobulin G-Binding Domain for Development of Specific Adsorbents for Extracorporeal Blood Purification

The chimeric gene encoding a C-terminally-truncated form of the S-layer protein SbpA from Bacillus sphaericus CCM 2177 and two copies of the Fc-binding Z-domain was constructed, cloned, and heterologously expressed in Escherichia coli HMS174(DE3). The Z-domain is a synthetic analogue of the B-domain of protein A, capable of binding the Fc part of immunoglobulin G (IgG). The S-layer fusion protein rSbpA_31-1068/ZZ retained the specific properties of the S-layer protein moiety to self-assemble in suspension and to recrystallize on supports precoated with secondary cell wall polymer (SCWP), which is the natural anchoring molecule for the S-layer protein in the bacterial cell wall. Due to the construction principle of the S-layer fusion protein, the ZZ-domains remained exposed on the outermost surface of the protein lattice. The binding capacity of the native or cross-linked monolayer for human IgG was determined by surface plasmon resonance measurements. For batch adsorption experiments, 3-μm-diameter, biocompatible cellulose-based, SCWP-coated microbeads were used for recrystallization of the S-layer fusion protein. In the case of the native monolayer, the binding capacity for human IgG was 5.1 ng/mm², whereas after cross-linking with dimethyl pimelimidate, 4.4 ng of IgG/mm² was bound. This corresponded to 78 and 65% of the theoretical saturation capacity of a planar surface for IgGs aligned in the upright position, respectively. Compared to commercial particles used as immunoadsorbents to remove autoantibodies from sera of patients suffering from an autoimmune disease, the IgG binding capacity of the S-layer fusion protein-coated microbeads was at least 20 times higher. For that reason, this novel type of microbeads should find application in the microsphere-based detoxification system.     

A recombinant bacterial cell surface (S-layer)-major birch pollen allergen-fusion protein (rSbsC/Bet v1) maintains the ability to self-assemble into regularly structured monomolecular lattices and the functionality of the allergen

The mature crystalline bacterial cell surface (S-layer) protein SbsC of Bacillus stearothermophilus ATCC 12980 comprises amino acids 31-1099 and assembles into an oblique lattice type. As the deletion of up to 179 C-terminal amino acids did not interfere with the self-assembly properties of SbsC, the sequence encoding the major birch pollen allergen (Bet v1) was fused to the sequence encoding the truncated form rSbsC(31-920). The S-layer fusion protein, termed rSbsC/Bet v1, maintained the ability to self-assemble into flat sheets and open-ended cylinders. The presence and the functionality of the fused Bet v1 sequence was proved by blot experiments using BIP1, a monoclonal antibody against Bet v1 and Bet v1-specific IgE-containing serum samples from birch pollen allergic patients. The location and accessibility of the allergen moiety on the outer surface of the S-layer lattice were demonstrated by immunogold labeling of the rSbsC/Bet v1 monolayer, which was obtained by oriented recrystallization of the S-layer fusion protein on native cell wall sacculi. Thereby, the specific interactions between the N-terminal part of SbsC and a distinct type of secondary cell wall polymer were exploited. This is the first S-layer fusion protein described that had retained the specific properties of the S-layer protein moiety in addition to those of the fused functional peptide sequence.     

Generation of a functional monomolecular protein lattice consisting of an s-layer fusion protein comprising the variable domain of a camel heavy chain antibody

Crystalline bacterial cell surface layer (S-layer) proteins are composed of a single protein or glycoprotein species. Isolated S-layer subunits frequently recrystallize into monomolecular protein lattices on various types of solid supports. For generating a functional protein lattice, a chimeric protein was constructed, which comprised the secondary cell wall polymer-binding region and the self-assembly domain of the S-layer protein SbpA from Bacillus sphaericus CCM 2177, and a single variable region of a heavy chain camel antibody (cAb-Lys3) recognizing lysozyme as antigen. For construction of the S-layer fusion protein, the 3'-end of the sequence encoding the C-terminally truncated form rSbpA(31)(-)(1068) was fused via a short linker to the 5'-end of the sequence encoding cAb-Lys3. The functionality of the fused cAb-Lys3 in the S-layer fusion protein was proved by surface plasmon resonance measurements. Dot blot assays revealed that the accessibility of the fused functional sequence for the antigen was independent of the use of soluble or assembled S-layer fusion protein. Recrystallization of the S-layer fusion protein into the square lattice structure was observed on peptidoglycan-containing sacculi of B. sphaericus CCM 2177, on polystyrene or on gold chips precoated with thiolated secondary cell wall polymer, which is the natural anchoring molecule for the S-layer protein in the bacterial cell wall. Thereby, the fused cAb-Lys3 remained located on the outer S-layer surface and accessible for lysozyme binding. Together with solid supports precoated with secondary cell wall polymers, S-layer fusion proteins comprising rSbpA(31)(-)(1068) and cAbs directed against various antigens shall be exploited for building up monomolecular functional protein lattices as required for applications in nanobiotechnology.     

An S-layer heavy chain camel antibody fusion protein for generation of a nanopatterned sensing layer to detect the prostate-specific antigen by surface plasmon resonance technology

The bacterial cell surface layer (S-layer) protein of Bacillus sphaericus CCM 2177 assembles into a square lattice structure and recognizes a distinct type of secondary cell wall polymer (SCWP) as the proper anchoring structure in the rigid cell wall layer. For generating a nanopatterned sensing layer with high density and well defined distance of the ligand on the outermost surface, an S-layer fusion protein incorporating the sequence of a variable domain of a heavy chain camel antibody directed against prostate-specific antigen (PSA) was constructed, produced, and recrystallized on gold chips precoated with thiolated SCWP. The S-layer protein moiety consisted of the N-terminal part which specifically recognized the SCWP as binding site and the self-assembly domain. The PSA-specific variable domain of the camel heavy chain antibody was selected by several rounds of panning from a phage display library of an immunized dromedary, and was produced by heterologous expression in Escherichia coli. For construction of the S-layer fusion protein, the 3'-end of the sequence encoding the C-terminally truncated form rSbpA(31)(-)(1068) was fused via a short linker to the 5'-end of the sequence encoding cAb-PSA-N7. The S-layer fusion protein had retained the ability to self-assemble into the square lattice structure. According to the selected fusion site in the SbpA sequence, the cAb-PSA-N7 moiety remained located on the outer surface of the protein lattice. After recrystallization of the S-layer fusion protein on gold chips precoated with thiolated SCWP, the monomolecular protein lattice was exploited as sensing layer in surface plasmon resonance biochips to detect PSA.     

The three S-layer-like homology motifs of the S-layer protein SbpA of Bacillus sphaericus CCM 2177 are not sufficient for binding to the pyruvylated secondary cell wall polymer

The S-layer protein SbpA of Bacillus sphaericus CCM 2177 recognizes a pyruvylated secondary cell wall polymer (SCWP) as anchoring structure to the peptidoglycan-containing layer. Data analysis from surface plasmon resonance (SPR) spectroscopy revealed the existence of three different binding sites with high, medium and low affinity for rSbpA on SCWP immobilized to the sensor chip. The shortest C-terminal truncation with specific affinity to SCWP was rSbpA(31-318). Surprisingly, rSbpA(31-202) comprising the three S-layer-like homology (SLH) motifs did not bind at all. Analysis of the SbpA sequence revealed a 58-amino-acid-long SLH-like motif starting 11 amino acids after the third SLH motif. The importance of this motif for reconstituting the functional SCWP-binding domain was further demonstrated by construction of a chimaeric protein consisting of the SLH domain of SbsB, the S-layer protein of Geobacillus stearothermophilus PV72/p2 and the C-terminal part of SbpA. In contrast to SbsB or its SLH domain which did not recognize SCWP of B. sphaericus CCM 2177 as binding site, the chimaeric protein showed specific affinity. Deletion of 213 C-terminal amino acids of SbpA had no impact on the square (p4) lattice structure, whereas deletion of 350 amino acids was linked to a change in lattice type from square to oblique (p1).     

Construction of a functional S-layer fusion protein comprising an immunoglobulin G-binding domain for development of specific adsorbents for extracorporeal blood purification

The chimeric gene encoding a C-terminally-truncated form of the S-layer protein SbpA from Bacillus sphaericus CCM 2177 and two copies of the Fc-binding Z-domain was constructed, cloned, and heterologously expressed in Escherichia coli HMS174(DE3). The Z-domain is a synthetic analogue of the B-domain of protein A, capable of binding the Fc part of immunoglobulin G (IgG). The S-layer fusion protein rSbpA(31-1068)/ZZ retained the specific properties of the S-layer protein moiety to self-assemble in suspension and to recrystallize on supports precoated with secondary cell wall polymer (SCWP), which is the natural anchoring molecule for the S-layer protein in the bacterial cell wall. Due to the construction principle of the S-layer fusion protein, the ZZ-domains remained exposed on the outermost surface of the protein lattice. The binding capacity of the native or cross-linked monolayer for human IgG was determined by surface plasmon resonance measurements. For batch adsorption experiments, 3-microm-diameter, biocompatible cellulose-based, SCWP-coated microbeads were used for recrystallization of the S-layer fusion protein. In the case of the native monolayer, the binding capacity for human IgG was 5.1 ng/mm(2), whereas after cross-linking with dimethyl pimelimidate, 4.4 ng of IgG/mm(2) was bound. This corresponded to 78 and 65% of the theoretical saturation capacity of a planar surface for IgGs aligned in the upright position, respectively. Compared to commercial particles used as immunoadsorbents to remove autoantibodies from sera of patients suffering from an autoimmune disease, the IgG binding capacity of the S-layer fusion protein-coated microbeads was at least 20 times higher. For that reason, this novel type of microbeads should find application in the microsphere-based detoxification system.     

The S-Layer Proteins of Two Bacillus stearothermophilus Wild-Type Strains Are Bound via Their N-Terminal Region to a Secondary Cell Wall Polymer of Identical Chemical Composition

Two Bacillus stearothermophilus wild-type strains were investigated regarding a common recognition and binding mechanism between the S-layer protein and the underlying cell envelope layer. The S-layer protein from B. stearothermophilus PV72/p6 has a molecular weight of 130,000 and assembles into a hexagonally ordered lattice. The S-layer from B. stearothermophilus ATCC 12980 shows oblique lattice symmetry and is composed of subunits with a molecular weight of 122,000. Immunoblotting, peptide mapping, N-terminal sequencing of the whole S-layer protein from B. stearothermophilus ATCC 12980 and of proteolytic cleavage fragments, and comparison with the S-layer protein from B. stearothermophilus PV72/p6 revealed that the two S-layer proteins have identical N-terminal regions but no other extended structurally homologous domains. In contrast to the heterogeneity observed for the S-layer proteins, the secondary cell wall polymer isolated from peptidoglycan-containing sacculi of the different strains showed identical chemical compositions and comparable molecular weights. The S-layer proteins could bind and recrystallize into the appropriate lattice type on native peptidoglycan-containing sacculi from both organisms but not on those extracted with hydrofluoric acid, leading to peptidoglycan of the A1γ chemotype. Affinity studies showed that only proteolytic cleavage fragments possessing the complete N terminus of the mature S-layer proteins recognized native peptidoglycan-containing sacculi as binding sites or could associate with the isolated secondary cell wall polymer, while proteolytic cleavage fragments missing the N-terminal region remained unbound. From the results obtained in this study, it can be concluded that S-layer proteins from B. stearothermophilus wild-type strains possess an identical N-terminal region which is responsible for anchoring the S-layer subunits to a secondary cell wall polymer of identical chemical composition.     

Detection of metal binding sites on functional S-layer nanoarrays using single molecule force spectroscopy

Crystalline bacterial cell surface layers (S-layers) show the ability to recrystallize into highly regular pattern on solid supports. In this study, the genetically modified S-layer protein SbpA of Lysinibacillus sphaericus CCM 2177, carrying a hexa-histidine tag (His₆-tag) at the C-terminus, was used to generate functionalized two-dimensional nanoarrays on a silicon surface. Atomic force microscopy (AFM) was applied to explore the topography and the functionality of the fused His₆-tags. The accessibility of the His₆-tags was demonstrated by in-situ anti-His-tag antibody binding to the functional S-layer array. The metal binding properties of the His₆-tag was investigated by single molecule force microscopy. For this purpose, newly developed tris–NTA was tethered to the AFM tips via a flexible polyethylene glycol (PEG) linker. The functionalized tips showed specific interactions with S-layer containing His₆-tags in the presence of nickel ions. Thus the His₆-tag is located at the outer surface of the S-layer and can be used for stable but reversible attachment of functional tris–NTA derivatives.     

Surface Location of Individual Residues of SlpA Provides Insight into the Lactobacillus brevis S-Layer

Bacterial surface layer (S-layer) proteins are excellent candidates for in vivo and in vitro nanobiotechnological applications because of their ability to self-assemble into two-dimensional lattices that form the outermost layer of many Eubacteria and most Archaea species. Despite this potential, knowledge about their molecular architecture is limited. In this study, we investigated SlpA, the S-layer protein of the potentially probiotic bacterium Lactobacillus brevis ATCC 8287 by cysteine-scanning mutagenesis and chemical modification. We generated a series of 46 mutant proteins by replacing single amino acids with cysteine, which is not present in the wild-type protein. Most of the replaced amino acids were located in the self-assembly domain (residues 179 to 435) that likely faces the outer surface of the lattice. As revealed by electron microscopy, all the mutant proteins were able to form self-assembly products identical to that of the wild type, proving that this replacement does not dramatically alter the protein conformation. The surface accessibility of the sulfhydryl groups introduced was studied with two maleimide-containing marker molecules, TMM(PEG)₁₂ (molecular weight [MW], 2,360) and AlexaFluor488-maleimide (MW = 720), using both monomeric proteins in solution and proteins allowed to self-assemble on cell wall fragments. Using the acquired data and available domain information, we assigned the mutated residues into four groups according to their location in the protein monomer and lattice structure: outer surface of the lattice (9 residues), inner surface of the lattice (9), protein interior (12), and protein-protein interface/pore regions (16). This information is essential, e.g., in the development of therapeutic and other health-related applications of Lactobacillus S-layers.Bacterial surface layers (S-layers) are cell envelope structures ubiquitously found in gram-positive and gram-negative bacteria as well as in Archaea. S-layers are composed of identical (glyco)protein subunits with a molecular mass in the range of 40 to 200 kDa. The proteins self-assemble into two-dimensional crystalline structures with oblique (p1, p2), square (p4), or hexagonal (p3, p6) symmetry, covering the entire cell surface. The subunits are held together and attached to the underlying cell wall by noncovalent interactions and they have an intrinsic ability to spontaneously form regular layers in solution and on solid supports (24). S-layers have been shown to have roles in the determination and maintenance of cell shape as virulence factors, as mediators of cell adhesion, and as regulators of immature dendritic and T cells. Moreover, they can also function as a protective coat, molecular sieve, murein hydrolase, and ion trap (4, 8, 13, 17, 19, 25, 29).S-layer proteins have several properties that make them an attractive target for the development of nanobiotechnological applications both in vivo and in vitro. In particular, a high number of protein subunits are displayed at the bacterial cell surface. Moreover, the protein subunits are able to spontaneously self-assemble into a regularly arranged lattice structure both in solution and on solid supports (1, 27, 30, 31). However, despite the high prevalence of S-layers in nature, their molecular structure remains poorly elucidated. In particular, knowledge about the spatial organization of amino acid residues in S-layer proteins or the interactions between these residues and other subunits is limited. The poor solubility of protein assemblies and the absence of stoichiometrically defined oligomers have hindered attempts to apply nuclear magnetic resonance or hydrogen/deuterium exchange mass spectroscopy. In addition, the intrinsic property of S-layer proteins to form two-dimensional lattices has hampered efforts to obtain three-dimensional crystals required for X-ray crystallography (12, 31). To our knowledge, only part of the structure of one S-layer protein, SbsC of Geobacillus stearothermophilus, has been determined by X-ray crystallography (18). Since high-resolution, three-dimensional structural data are mostly lacking, traditional mutation-based techniques are presently the methods of choice. In cysteine-scanning mutagenesis (CSM), a series of mutant proteins is generated by replacing single residues with cysteine, which contains a sulfhydryl group amenable to further chemical modification. The spatial locations of amino acid residues within the S-layer protein SbsB of gram-positive thermophile G. stearothermophilus PV72/p2 have been analyzed by CSM. A total of 75 residues out of 920 were studied, identifying 23 residues located at the surface of protein monomers, five of those located on the outer surface of the protein lattice (10). These mutant proteins were subsequently analyzed by a cross-linking screen to assess residues accessible in monomeric form to the protein/protein interface and the inner surface of the lattice (12).In the genus Lactobacillus, S-layers have been found in several species. S-layer protein genes have been sequenced from L. brevis, L. helveticus, and L. acidophilus group organisms. Sequence similarity between Lactobacillus S-layer protein genes can be found only between closely related Lactobacillus species. Therefore, the primary sequences of Lactobacillus S-layer proteins show extensive variability, with the number of identical amino acids varying from 7 to 100% between different proteins. As a group, Lactobacillus S-layer proteins differ from those of most other bacteria in their smaller sizes (25 to 71 kDa) and higher calculated isoelectric point (pI) values (9.4 to 10.4) (1). The presence of two or more S-layer protein genes in the same strain is common in lactobacilli (5, 6, 11, 28, 35); however, only one S-layer protein gene, slpA, has so far been described to be present in the genome of L. brevis ATCC 8287. SlpA is a 435-amino-acid, 46-kDa S-layer protein that assembles into a lattice of oblique symmetry on the bacterial surface (2, 36). L. brevis ATCC 8287 has GRAS (generally recognized as safe) status and has been shown to possess probiotic properties (21), which make SlpA a very attractive subject, e.g., in the development of live oral vaccines. Moreover, a recent report using differential scanning calorimetry suggests that in comparison with other S-layer proteins, SlpA is resistant to high temperatures (21). This thermal stability could prove potentially useful in a variety of in vitro S-layer applications currently being planned or under development (27, 30, 31). Recently, SlpA was characterized to consist of an N-terminal cell wall binding domain (residues 1 to 178) and a C-terminal self-assembly domain (179 to 435) (3). For the development of applications that take advantage of these characteristics, further investigation of SlpA at the molecular level is essential.Herein, we use CSM and targeted chemical modification to assign 46 amino acid residues of SlpA to spatial locations in the protein monomer and in the lattice according to their surface accessibility. We focused mainly on the self-assembly domain, the region facing the outer surface of the protein lattice and thus most amenable to insertions and chemical modification. Two different marker molecules were used to modify cysteine-containing mutant proteins that were either in solution or attached to the cell wall. The results were subsequently evaluated taking advantage of the recent new information on SlpA domain boundaries (3). We were able to distinguish residues located in the outer and inner surfaces of the lattice, protein interior, and interface/pore regions. The information gathered here can be used in the development of further biotechnological and nanobiological applications, both in vitro and in vivo, that benefit from a thermostable S-layer protein from a GRAS bacterium with health-beneficial properties.     

Identification of Two Binding Domains, One for Peptidoglycan and Another for a Secondary Cell Wall Polymer, on the N-Terminal Part of the S-Layer Protein SbsB from Bacillus stearothermophilus PV72/p2

First studies on the structure-function relationship of the S-layer protein from B. stearothermophilus PV72/p2 revealed the coexistence of two binding domains on its N-terminal part, one for peptidoglycan and another for a secondary cell wall polymer (SCWP). The peptidoglycan binding domain is located between amino acids 1 to 138 of the mature S-layer protein comprising a typical S-layer homologous domain. The SCWP binding domain lies between amino acids 240 to 331 and possesses a high serine plus glycine content.     

The Role of Changing Loop Conformations in Streptavidin Versions Engineered for High-affinity Binding of the Strep-tag II Peptide

The affinity system based on the artificial peptide ligand Strep-tag® II and engineered tetrameric streptavidin, known as Strep-Tactin®, offers attractive applications for the study of recombinant proteins, from detection and purification to functional immobilization. To further improve binding of the Strep-tag II to streptavidin we have subjected two protruding loops that shape its ligand pocket for the peptide – instead of D-biotin recognized by the natural protein – to iterative random mutagenesis. Sequence analyses of hits from functional screening assays revealed several unexpected structural motifs, such as a disulfide bridge at the base of one loop, replacement of the crucial residue Trp120 by Gly and a two-residue deletion in the second loop. The mutant m1-9 (dubbed Strep-Tactin XT) showed strongly enhanced affinity towards the Strep-tag II, which was further boosted in case of the bivalent Twin-Strep-tag®. Four representative streptavidin mutants were crystallized in complex with the Strep-tag II peptide and their X-ray structures were solved at high resolutions. In addition, the crystal structure of the complex between Strep-Tactin XT and the Twin-Strep-tag was elucidated, indicating a bivalent mode of binding and explaining the experimentally observed avidity effect. Our study illustrates the structural plasticity of streptavidin as a scaffold for ligand binding and reveals interaction modes that would have been difficult to predict. As result, Strep-Tactin XT offers a convenient reagent for the kinetically stable immobilization of recombinant proteins fused with the Twin-Strep-tag. The possibility of reversibly dissociating such complexes simply with D-biotin as a competing ligand enables functional studies in protein science as well as cell biology.     

Species-Specific Cell Wall Binding Affinity of the S-Layer Proteins of Mosquitocidal Bacterium Bacillus sphaericus C3-41

The binding affinities and specificities of six truncated S-layer homology domain (SLH) polypeptides of mosquitocidal Bacillus sphaericus strain C3-41 with the purified cell wall sacculi have been assayed. The results indicated that the SLH polypeptide comprised of amino acids 31 to 210 was responsible for anchoring the S-layer subunits to the rigid cell wall layer via a distinct type of secondary cell wall polymer and that a motif of the recombinant SLH polypeptide comprising amino acids 152 to 210 (rSLH_152-210) was essential for the stable binding of the S-layer with the bacterial cell walls. The quantitative assays revealed that the K_D (equilibrium dissociation constant) values of rSLH_152-210 and rSLH_31-210 with purified cell wall sacculi were 1.11 × 10⁻⁶ M and 1.40 × 10⁻⁶ M, respectively. The qualitative assays demonstrated that the SLH domain of strain C3-41 could bind only to the cell walls or the cells treated with 5 M guanidinium hydrochloride of both toxic and nontoxic B. sphaericus strains but not to those from other bacteria, indicating the species-specific binding of the SLH polypeptide of B. sphaericus with bacterial cell walls.Crystalline bacterial cell surface layers (S-layers) cover the cell surfaces of many bacteria and archaea during all stages of growth and division. S-layers are composed of identical protein or glycoprotein subunits, which can assemble into two-dimensional crystalline arrays and exhibit oblique, square, or hexagonal symmetry (27, 28, 30). S-layers play key roles in the interaction between bacterial cells and environment as protective coats, molecular sieves, ion traps, cell adhesion mediators, and attachment structures (4, 21, 26, 29). Many S-layer proteins possess an N-terminal region with highly conserved amino acid sequences, which is called an S-layer homology (SLH) domain. An SLH domain contains one, two, or three repeating SLH motifs (6, 16). Each SLH motif is composed of about 55 amino acids containing 10 to 15 conserved residues (6, 17). It is suggested that the SLH domain of S-layer proteins is responsible for the binding of the S-layer subunits to the rigid cell wall layer (6, 15, 17, 19, 25), while the middle and C-terminal parts include the domains which are involved in the self-assembly process (27). In the case of Bacillaceae, secondary cell wall polymers (SCWP) are responsible for binding with SLH domains (13, 18, 19), but the SLH domains of some other bacteria have an affinity for peptidoglycan (33).Bacillus sphaericus is a gram-positive soil bacterium that represents a strictly aerobic group of mesophilic endospore-forming bacteria. Due to its specific toxicity to target mosquito larvae and the limited environment impact, some strains of this bacterium have been successfully used worldwide in integrated mosquito control programs. Previous studies revealed that some nontoxic strains of B. sphaericus contained S-layer proteins, and the S-layer proteins of B. sphaericus NCTC 9602, JG-A12, P1, and CCM 2177 have been studied in detail elsewhere (3, 7-9, 12, 22).B. sphaericus C3-41, a highly active strain isolated from a mosquito-breeding site in China in 1987, has different levels of toxicity against Culex spp., Anopheles spp., and Aedes spp. This strain belongs to the flagella serotype H5a5b, like strains 2362 and 1593 (32), and it has been developed as a commercial larvicide (JianBao) for mosquito larva control in China during the last decade (31). The genomic analysis of strain C3-41 revealed that an S-layer protein gene (slpC) (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"EF535606","term_id":"145975949","term_text":"EF535606"}}EF535606) exists on the chromosomal genome and its sequence is identical to the S-layer protein of B. sphaericus 2362 (1, 10), composed of 3,531 bp encoding a protein of 1,176 amino acids with a molecular size of 125 kDa. Although the binding function of S-layers has been identified in some nontoxic B. sphaericus strains (6, 11), it is not well documented in mosquitocidal B. sphaericus strains, and there are few reports on the binding function of each SLH motif and the binding specificity.In this study, the binding affinities and specificities of each SLH motif of S-layer protein from mosquitocidal B. sphaericus C3-41 alone and in combination with the different cell wall preparations have been investigated, and the species-specific binding of SLH polypeptide with bacterial cell walls has been demonstrated.     

Characterization,Identification, and Cloning of the S-Layer Protein from <Emphasis Type="Italic">Cytophaga</Emphasis> sp.

We characterized, identified, and cloned a major protein which comprised 16% of the total proteins from Cytophaga sp. cell lysate. After French pressing, the fraction of cell envelope was treated with 0.2% Triton X-100 to remove cell membranes. Subsequent SDS-PAGE analysis of the Triton X-100-insoluble cell wall revealed a protein of 120 kDa with a pI of 5.4, which was identified by gold immunostaining as the surface (S)-layer protein of this soil bacterium. The nucleotide sequence of the cloned S-layer protein gene (slp) encoding this protein consisted of 3144 nucleotides with an ORF for 1047 amino acids, which included a typical 32-amino acid leader peptide sequence. Amino acid sequence alignment revealed 29–48% similarity between this protein and the S-layer proteins from other prokaryotic organisms. The 120-kDa protein from the Cytophaga sp. cell lysate has been characterized as a member of the S-layer proteins, and the slp gene was cloned and expressed in Escherichia coli. E. coli harboring the plasmid containing the 600- or 800-bp DNA fragment upstream of the initiation codon of the slp gene, in the presence of the reporter gene rsda (raw starch digesting amylase), showed amylase activity in starch containing plate. The putative promoter region of slp located 600 bp upstream of the initiation codon might be used for foreign gene expression.     

Characterization of a S-layer protein from Lactobacillus crispatus K313 and the domains responsible for binding to cell wall and adherence to collagen

It was previously shown that the surface (S)-layer proteins covering the cell surface of Lactobacillus crispatus K313 were involved in the adherence of this strain to human intestinal cell line HT-29. To further elucidate the structures and functions of S-layers, three putative S-layer protein genes (slpA, slpB, and slpC) of L. crispatus K313 were amplified by PCR, sequenced, and characterized in detail. Quantitative real-time PCR analysis reveals that slpA was silent under the tested conditions; whereas slpB and slpC, the putative amino acid sequences which exhibited minor similarities to the previously reported S-layer proteins in L. crispatus, were actively expressed. slpB, which was predominantly expressed in L. crispatus K313, was further investigated for its functional domains. Genetic truncation of the untranslated leader sequence (UTLS) of slpB results in a reduction in protein production, indicating that the UTLS contributed to the efficient S-layer protein expression. By producing a set of N- and C-terminally truncated recombinant SlpB proteins in Escherichia coli, the cell wall-binding region was mapped to the C terminus, where rSlpB_380–501 was sufficient for binding to isolated cell wall fragments. Moreover, the binding ability of the C terminus was variable among the Lactobacillus species (S-layer- and non-S-layer-producing strains), and teichoic acid may be acting as the receptor of SlpB. To determine the adhesion region of SlpB to extracellular matrix proteins, ELISA was performed. Binding to immobilized types I and IV collagen was observed with the His-SlpB_1–379 peptides, suggesting that the extracellular matrix protein-binding domain was located in the N terminus.     

Highly robust lipid membranes on crystalline S-layer supports investigated by electrochemical impedance spectroscopy

In the present work, S-layer supported lipid membranes formed by a modified Langmuir-Blodgett technique were investigated by electrochemical impedance spectroscopy (EIS). Basically two intermediate hydrophilic supports for phospholipid- (DPhyPC) and bipolar tetraetherlipid- (MPL from Thermoplasma acidophilum) membranes have been applied: First, the S-layer protein SbpA isolated from Bacillus sphaericus CCM 2177 recrystallized onto a gold electrode; and second, as a reference support, an S-layer ultrafiltration membrane (SUM), which consists of a microfiltration membrane (MFM) with deposited S-layer carrying cell wall fragments. The electrochemical properties and the stability of DPhyPC and MPL membranes were found to depend on the used support. The specific capacitances were 0.53 and 0.69 μF/cm² for DPhyPC bilayers and 0.75 and 0.77 μF/cm² for MPL monolayers resting on SbpA and SUM, respectively. Membrane resistances of up to 80 MΩ cm² were observed for DPhyPC bilayers on SbpA. In addition, membranes supported by SbpA exhibited a remarkable long-term robustness of up to 2 days. The membrane functionality could be demonstrated by reconstitution of membrane-active peptides such as valinomycin and alamethicin. The present results recommend S-layer-supported lipid membranes as promising structures for membrane protein-based biosensor technology.     

A novel approach to specific allergy treatment: the recombinant fusion protein of a bacterial cell surface (S-layer) protein and the major birch pollen allergen Bet v 1 (rSbsC-Bet v 1) combines reduced allergenicity with immunomodulating capacity

Counterregulating the disease-eliciting Th2-like immune response of allergen-specific Th lymphocytes by fostering an allergen-specific Th1-like response is a promising concept for future immunotherapy of type I allergy. The use of recombinant allergens combined with more functional adjuvants has been proposed. In this respect, we present a novel approach. The gene sequence encoding the major birch pollen allergen, Bet v 1, was fused with the gene encoding the bacterial cell surface (S-layer) protein of Geobacillus stearothermophilus, resulting in the recombinant protein, rSbsC-Bet v 1. rSbsC-Bet v 1 contained all relevant Bet v 1-specific B and T cell epitopes, but was significantly less efficient to release histamine than rBet v 1. In cells of birch pollen-allergic individuals, rSbsC-Bet v 1 induced IFN-gamma along with IL-10, but no Th2-like response, as observed after stimulation with Bet v 1. Intracellular cytokine staining revealed that rSbsC-Bet v 1 promoted IFN-gamma-producing Th cells. Moreover, rSbsC-Bet v 1 induced IFN-gamma synthesis in Bet v 1-specific Th2 cell clones, and importantly, increased IL-10 production in these cells. In conclusion, genetic fusion of an allergen to S-layer proteins combined reduced allergenicity with immunomodulatory capacity. The strategy described in this work may be generally applied to design vaccines for specific immunotherapy of type I allergy with improved efficacy and safety.     

Influence of the Secondary Cell Wall Polymer on the Reassembly,Recrystallization, and Stability Properties of the S-Layer Protein from Bacillus stearothermophilus PV72/p2

The high-molecular-weight secondary cell wall polymer (SCWP) from Bacillus stearothermophilus PV72/p2 is mainly composed of N-acetylglucosamine (GlcNAc) and N-acetylmannosamine (ManNAc) and is involved in anchoring the S-layer protein via its N-terminal region to the rigid cell wall layer. In addition to this binding function, the SCWP was found to inhibit the formation of self-assembly products during dialysis of the guanidine hydrochloride (GHCl)-extracted S-layer protein. The degree of assembly (DA; percent assembled from total S-layer protein) that could be achieved strongly depended on the amount of SCWP added to the GHCl-extracted S-layer protein and decreased from 90 to 10% when the concentration of the SCWP was increased from 10 to 120 μg/mg of S-layer protein. The SCWP kept the S-layer protein in the water-soluble state and favored its recrystallization on solid supports such as poly-l-lysine-coated electron microscopy grids. Derived from the orientation of the base vectors of the oblique S-layer lattice, the subunits had bound with their charge-neutral outer face, leaving the N-terminal region with the polymer binding domain exposed to the ambient environment. From cell wall fragments about half of the S-layer protein could be extracted with 1 M GlcNAc, indicating that the linkage type between the S-layer protein and the SCWP could be related to that of the lectin-polysaccharide type. Interestingly, GlcNAc had an effect on the in vitro self-assembly and recrystallization properties of the S-layer protein that was similar to that of the isolated SCWP. The SCWP generally enhanced the stability of the S-layer protein against endoproteinase Glu-C attack and specifically protected a potential cleavage site in position 138 of the mature S-layer protein.Many bacteria and archaea possess crystalline bacterial cell surface layers (S-layers) as their outermost cell envelope component (3, 36, 38). S-layers are composed of identical protein or glycoprotein subunits which assemble into two-dimensional crystalline arrays showing oblique, square, or hexagonal lattice symmetry. S-layer subunits from bacteria are linked to each other and to the underlying cell envelope layer by noncovalent interactions and may therefore be isolated from whole cells or cell wall fragments by different procedures involving chaotropic agents, detergents, chelating agents, or high salt concentrations or by alkaline or acidic pH conditions. During removal of the disrupting agents, e.g., by dialysis, the S-layer subunits frequently reassemble into flat sheets or open-ended cylinders (in vitro self-assembly in suspension; for reviews, see references 37 and 38).Studies regarding the binding mechanism between the S-layer protein and the underlying cell envelope layer have shown that in gram-negative bacteria, the N-terminal region of the S-layer subunits recognizes specific lipopolysaccharides in the outer membrane (9, 29, 41). For Aeromonas hydrophila it was found, however, that the C-terminal part of the S-layer protein is essential for interaction with the outer membrane (40). A similar observation was reported for the S-layer protein from the gram-positive Corynebacterium glutamicum. A hydrophobic stretch of 21 amino acids located at the C-terminal end of the S-layer protein was found to interact with a hydrophobic layer in the cell wall proper that most probably consisted of mycolic acid (8). In earlier studies it was suggested that secondary cell wall polymers could represent the binding sites for the S-layer proteins from Bacillus sphaericus (15, 16) and Lactobacillus buchneri (24).Recently, a high-molecular-weight secondary cell wall polymer (SCWP) containing glucose and N-acetylglucosamine (GlcNAc) was extracted from peptidoglycan-containing sacculi of two Bacillus stearothermophilus wild-type strains (PV72/p6 and ATCC 12980 [10]). An SCWP of different chemical composition could be isolated from peptidoglycan-containing sacculi of an oxygen-induced variant strain from B. stearothermophilus PV72/p6 (35). The SCWP produced by this variant strain (B. stearothermophilus PV72/p2) is mainly composed of GlcNAc and N-acetylmannosamine (ManNAc) and shows a molecular weight of about 24,000 (33). Binding studies with proteolytic cleavage fragments and native peptidoglycan-containing sacculi revealed that the N-terminal region is involved in anchoring the S-layer subunits to the rigid cell wall layer (10, 11, 33). Several observations have supported the notion that a specific recognition and binding mechanism exists between the SCWP and the N-terminal region of the S-layer proteins from B. stearothermophilus strains. (i) Despite the overall heterogeneity, S-layer proteins from B. stearothermophilus wild-type strains possess an identical N-terminal region and are capable of binding to an SCWP of identical chemical composition. (ii) B. stearothermophilus PV72/p6 and the oxygen-induced p2 variant produce an SCWP of different chemical composition and structure. (iii) The S-layer protein from B. stearothermophilus PV72/p2 did not recognize native peptidoglycan-containing sacculi from B. stearothermophilus wild-type strains as binding sites (35). (iv) The S-layer protein from B. stearothermophilus PV72/p6 (SbsA) and the oxygen-induced p2 variant (SbsB) are encoded by different genes which show little overall identity (19, 20), and only SbsB possesses a typical S-layer homologous (SLH) domain (23) at the N-terminal part.By sequence comparison, SLH domains (23) were identified on the N-terminal part of several S-layer proteins (6, 13, 23, 27, 30) or at the very C-terminal end of cell-associated exoenzymes and exoproteins (21, 22, 25, 26). SLH domains were suggested to anchor these proteins permanently or transiently to the cell surface. So far, evidence for a binding function of an SLH domain was provided for the S-layer protein of Thermus thermophilus (30) and for the outer-layer proteins of the cellulosome complex from Clostridium thermocellum (21, 22).In the present study, the influence of the SCWP on the formation of self-assembly products in suspension and on the recrystallization properties of the S-layer protein from B. stearothermophilus PV72/p2 on solid supports such as poly-l-lysine-coated electron microscopy (EM) grids was investigated. Moreover, studies on the stability of the S-layer protein against endoproteinase Glu-C attack in the presence and the absence of the SCWP were carried out.     

Characterization of an S-layer glycoprotein produced in the course of S-layer variation of<Emphasis Type="Italic"> Bacillus stearothermophilu</Emphasis>s ATCC 12980 and sequencing and cloning of the<Emphasis Type="Italic"> sbsD</Emphasis> gene encoding the protein moiety

The cell surface of Bacillus stearothermophilus ATCC 12980 is completely covered by an oblique lattice which consists of the S-layer protein SbsC. On SDS-polyacrylamide gels, the mature S-layer protein migrates as a single band with an apparent molecular mass of 122 kDa. During cultivation of B. stearothermophilus ATCC 12980 at 67 degrees C instead of 55 degrees C, a variant developed that had a secondary cell wall polymer identical to that of the wild-type strain, but it carried an S-layer glycoprotein that could be separated on SDS-polyacrylamide gels into four bands with apparent molecular masses of 92, 118, 150 and 175 kDa. After deglycosylation, only a single protein band with a molecular mass of 92 kDa remained. The complete nucleotide sequence encoding the protein moiety of this S-layer glycoprotein, termed SbsD, was established by PCR and inverse PCR. The sbsD gene of 2,709 bp is predicted to encode a protein of 96.2 kDa with a 30-amino-acid signal peptide. Within the 807 bp encoding the signal peptide and the N-terminal sequence (amino acids 31-269), different nucleotides for sbsD and sbsC were observed in 46 positions, but 70% of these mutations were silent, thus leading to a level of identity of 95% for the N-terminal parts. The level of identity of the remaining parts of SbsD and SbsC was below 10%, indicating that the lysine-, tyrosine- and arginine-rich N-terminal region in combination with a distinct type of secondary cell wall polymer remained conserved upon S-layer variation. The sbsD sequence encoding the mature S-layer protein cloned into the pET28a vector led to stable expression in Escherichia coli HMS174(DE3). This is the first example demonstrating that S-layer variation leads to the synthesis of an S-layer glycoprotein.