Diverse supramolecular structures formed by self‐assembling proteins of the Bacillus subtilis spore coat

Bacterial spores (endospores), such as those of the pathogens Clostridium difficile and Bacillus anthracis, are uniquely stable cell forms, highly resistant to harsh environmental insults. Bacillus subtilis is the best studied spore‐former and we have used it to address the question of how the spore coat is assembled from multiple components to form a robust, protective superstructure. B. subtilis coat proteins (CotY, CotE, CotV and CotW) expressed in Escherichia coli can arrange intracellularly into highly stable macro‐structures through processes of self‐assembly. Using electron microscopy, we demonstrate the capacity of these proteins to generate ordered one‐dimensional fibres, two‐dimensional sheets and three‐dimensional stacks. In one case (CotY), the high degree of order favours strong, cooperative intracellular disulfide cross‐linking. Assemblies of this kind could form exquisitely adapted building blocks for higher‐order assembly across all spore‐formers. These physically robust arrayed units could also have novel applications in nano‐biotechnology processes.     

Proteins involved in formation of the outermost layer of Bacillus subtilis spores

To investigate the outermost structure of the Bacillus subtilis spore, we analyzed the accessibility of antibodies to proteins on spores of B. subtilis. Anti-green fluorescent protein (GFP) antibodies efficiently accessed GFP fused to CgeA or CotZ, which were previously assigned to the outermost layer termed the spore crust. However, anti-GFP antibodies did not bind to spores of strains expressing GFP fused to 14 outer coat, inner coat, or cortex proteins. Anti-CgeA antibodies bound to spores of wild-type and CgeA-GFP strains but not cgeA mutant spores. These results suggest that the spore crust covers the spore coat and is the externally exposed, outermost layer of the B. subtilis spore. We found that CotZ was essential for the spore crust to surround the spore but not for spore coat formation, indicating that CotZ plays a critical role in spore crust formation. In addition, we found that CotY-GFP was exposed on the surface of the spore, suggesting that CotY is an additional component of the spore crust. Moreover, the localization of CotY-GFP around the spore depended on CotZ, and CotY and CotZ depended on each other for spore assembly. Furthermore, a disruption of cotW affected the assembly of CotV-GFP, and a disruption of cotX affected the assembly of both CotV-GFP and CgeA-GFP. These results suggest that cgeA and genes in the cotVWXYZ cluster are involved in spore crust formation.     

Contributions of crust proteins to spore surface properties in Bacillus subtilis

Surface properties, such as adhesion and hydrophobicity, constrain dispersal of bacterial spores in the environment. In Bacillus subtilis, these properties are influenced by the outermost layer of the spore, the crust. Previous work has shown that two clusters, cotVWXYZ and cgeAB, encode the protein components of the crust. Here, we characterize the respective roles of these genes in surface properties using Bacterial Adherence to Hydrocarbons assays, negative staining of polysaccharides by India ink and Transmission Electron Microscopy. We showed that inactivation of crust genes caused increases in spore relative hydrophobicity, disrupted the spore polysaccharide layer, and impaired crust structure and attachment to the rest of the coat. We also found that cotO, previously identified for its role in outer coat formation, is necessary for proper encasement of the spore by the crust. In parallel, we conducted fluorescence microscopy experiments to determine the full network of genetic dependencies for subcellular localization of crust proteins. We determined that CotZ is required for the localization of most crust proteins, while CgeA is at the bottom of the genetic interaction hierarchy.     

Assembly of the BclB glycoprotein into the exosporium and evidence for its role in the formation of the exosporium ‘cap’ structure in Bacillus anthracis

The outermost layer of the Bacillus anthracis spore consists of an exosporium comprised of an outer hair‐like nap layer and an internal basal layer. A major component of the hair‐like nap is the glycosylated collagen‐like protein BclA. A second collagen‐like protein, BclB, is also present in the exosporium. BclB possesses an N‐terminal sequence that targets it to the exosporium and is similar in sequence to a cognate targeting region in BclA. BclB lacks, however, sequence similarity to the region of BclA thought to mediate attachment to the basal layer via covalent interactions with the basal layer protein BxpB. Here we demonstrate that BxpB is critical for correct localization of BclB during spore formation and that the N‐terminal domains of the BclA and BclB proteins compete for BxpB‐controlled assembly sites. We found that BclB is located principally in a region of the exosporium that excludes a short arc on one side of the exosporium (the so‐called bottle‐cap region). We also found that in bclB mutant spores, the distribution of exosporium proteins CotY and BxpB is altered, suggesting that BclB has roles in exosporium assembly. In bclB mutant spores, the distance between the exosporium and the coat, the interspace, is reduced.     

Cloning and characterization of a cluster of genes encoding polypeptides present in the insoluble fraction of the spore coat of Bacillus subtilis.

The Bacillus subtilis spore coat is composed of at least 15 polypeptides plus an insoluble protein fraction arranged in three morphological layers. The insoluble fraction accounts for about 30% of the coat protein and is resistant to solubilization by a variety of reagents, implying extensive cross-linking. A dodecapeptide was purified from this fraction by formic acid hydrolysis and reverse-phase high-performance liquid chromatography. This peptide was sequenced, and a gene designated cotX was cloned by reverse genetics. The cotX gene encoding the dodecapeptide at its amino end was clustered with four other genes designated cotV, cotW, cotY, and cotZ. These genes were mapped to 107 degrees between thiB and metA on the B. subtilis chromosome. The deduced amino acid sequences of the cotY and cotZ genes are very similar. Both proteins are cysteine rich, and CotY antigen was present in spore coat extracts as disulfide cross-linked multimers. There was little CotX antigen in the spore coat soluble fraction, and deletion of this gene resulted in a 30% reduction in the spore coat insoluble fraction. Spores produced by strains with deletions of the cotX, cotYZ, or cotXYZ genes were heat and lysozyme resistant but readily clumped and responded more rapidly to germinants than did spores from the wild type. In electron micrographs, there was a less densely staining outer coat in spores produced by the cotX null mutant, and those produced by a strain with a deletion of the cotXYZ genes had an incomplete outer coat. These proteins, as part of the coat insoluble fraction, appear to be localized to the outer coat and influence spore hydrophobicity as well as the accessibility of germinants.     

以CotX为分子载体在枯草芽胞杆菌芽胞表面展示绿色荧光蛋白

芽胞衣壳蛋白CotB、CotC、CotG等可作为芽胞表面展示外源蛋白的分子载体,制备口服重组疫苗或具有催化活性的重组酶。CotX为枯草芽胞杆菌Bacillussubtilis芽胞衣壳中的另一种结构蛋白。为证明CotX能否作为分子载体将外源蛋白展示在芽胞表面,本研究将cotX基因与绿色荧光蛋白基因gfp的编码序列进行基因重组,构建融合表达CotX-GFP的整合型重组质粒,将该质粒转化枯草芽胞杆菌,筛选重组菌株并诱导产生芽胞,观察到重组芽胞表面具有GFP绿色荧光。结果表明枯草芽胞杆菌的芽胞衣壳蛋白CotX位于芽胞衣壳外层,可作为芽胞表面展示外源蛋白的载体分子。     

ExsY and CotY are required for the correct assembly of the exosporium and spore coat of Bacillus cereus

The exosporium-defective phenotype of a transposon insertion mutant of Bacillus cereus implicated ExsY, a homologue of B. subtilis cysteine-rich spore coat proteins CotY and CotZ, in assembly of an intact exosporium. Single and double mutants of B. cereus lacking ExsY and its paralogue, CotY, were constructed. The exsY mutant spores are not surrounded by an intact exosporium, though they often carry attached exosporium fragments. In contrast, the cotY mutant spores have an intact exosporium, although its overall shape is altered. The single mutants show altered, but different, spore coat properties. The exsY mutant spore coat is permeable to lysozyme, whereas the cotY mutant spores are less resistant to several organic solvents than is the case for the wild type. The exsY cotY double-mutant spores lack exosporium and have very thin coats that are permeable to lysozyme and are sensitive to chloroform, toluene, and phenol. These spore coat as well as exosporium defects suggest that ExsY and CotY are important to correct formation of both the exosporium and the spore coat in B. cereus. Both ExsY and CotY proteins were detected in Western blots of purified wild-type exosporium, in complexes of high molecular weight, and as monomers. Both exsY and cotY genes are expressed at late stages of sporulation.     

An oligosaccharyltransferase from Leishmania major increases the N‐glycan occupancy on recombinant glycoproteins produced in Nicotiana benthamiana

N‐glycosylation is critical for recombinant glycoprotein production as it influences the heterogeneity of products and affects their biological function. In most eukaryotes, the oligosaccharyltransferase is the central‐protein complex facilitating the N‐glycosylation of proteins in the lumen of the endoplasmic reticulum (ER). Not all potential N‐glycosylation sites are recognized in vivo and the site occupancy can vary in different expression systems, resulting in underglycosylation of recombinant glycoproteins. To overcome this limitation in plants, we expressed LmSTT3D, a single‐subunit oligosaccharyltransferase from the protozoan Leishmania major transiently in Nicotiana benthamiana, a well‐established production platform for recombinant proteins. A fluorescent protein‐tagged LmSTT3D variant was predominately found in the ER and co‐located with plant oligosaccharyltransferase subunits. Co‐expression of LmSTT3D with immunoglobulins and other recombinant human glycoproteins resulted in a substantially increased N‐glycosylation site occupancy on all N‐glycosylation sites except those that were already more than 90% occupied. Our results show that the heterologous expression of LmSTT3D is a versatile tool to increase N‐glycosylation efficiency in plants.     

Glycosylation defects activate filamentous growth Kss1 MAPK and inhibit osmoregulatory Hog1 MAPK

The yeast filamentous growth (FG) MAP kinase (MAPK) pathway is activated under poor nutritional conditions. We found that the FG‐specific Kss1 MAPK is activated by a combination of an O‐glycosylation defect caused by disruption of the gene encoding the protein O‐mannosyltransferase Pmt4, and an N‐glycosylation defect induced by tunicamycin. The O‐glycosylated membrane proteins Msb2 and Opy2 are both essential for activating the FG MAPK pathway, but only defective glycosylation of Msb2 activates the FG MAPK pathway. Although the osmoregulatory HOG (high osmolarity glycerol) MAPK pathway and the FG MAPK pathway share almost the entire upstream signalling machinery, osmostress activates only the HOG‐specific Hog1 MAPK. Conversely, we now show that glycosylation defects activate only Kss1, while activated Kss1 and the Ptp2 tyrosine phosphatase inhibit Hog1. In the absence of Kss1 or Ptp2, however, glycosylation defects activate Hog1. When Hog1 is activated by glycosylation defects in ptp2 mutant, Kss1 activation is suppressed by Hog1. Thus, the reciprocal inhibitory loop between Kss1 and Hog1 allows only one or the other of these MAPKs to be stably activated under various stress conditions.     

A protein phosphorylation module patterns the Bacillus subtilis spore outer coat

Assembly of the Bacillus subtilis spore coat involves over 80 proteins which self-organize into a basal layer, a lamellar inner coat, a striated electrodense outer coat and a more external crust. CotB is an abundant component of the outer coat. The C-terminal moiety of CotB, SKR^B, formed by serine-rich repeats, is polyphosphorylated by the Ser/Thr kinase CotH. We show that another coat protein, CotG, with a central serine-repeat region, SKR^G, interacts with the C-terminal moiety of CotB and promotes its phosphorylation by CotH in vivo and in a heterologous system. CotG itself is phosphorylated by CotH but phosphorylation is enhanced in the absence of CotB. Spores of a strain producing an inactive form of CotH, like those formed by a cotG deletion mutant, lack the pattern of electrondense outer coat striations, but retain the crust. In contrast, deletion of the SKR^B region, has no major impact on outer coat structure. Thus, phosphorylation of CotG by CotH is a key factor establishing the structure of the outer coat. The presence of the cotB/cotH/cotG cluster in several species closely related to B. subtilis hints at the importance of this protein phosphorylation module in the morphogenesis of the spore surface layers.     

N-linked glycosylation in Archaea: two paths to the same glycan

N‐linked protein glycosylation occurs in all three branches of life, eukaryotes, bacteria and archaea. The simplest system is that of the bacterium, Campylobacter jejuni, in which a heptasaccharide glycan is added to multiple proteins from a single lipid carrier molecule. In the eukaryotic system a conserved tetradecasaccharide modification is first added to target proteins, but is then modified by trimming and addition of other glycans from additional carrier molecules resulting in a diverse array of glycans of distinct functionality. In the halophilic Archaea from the Dead Sea, Haloferax volcanii, the surface array or S‐layer protein is glycosylated with a pentasaccharide. This glycan is synthesized from two separate carrier molecules, one that carries a tetrasaccharide and another that carries the terminal mannose, in a process that is analogous to that of eukaryotes. In this issue of Molecular Microbiology the glycosylation of the S‐layer of another halophilic Archaea from the Dead Sea, Haloarcula marismortui is characterized ( Calo et al., 2011 ). This S‐layer is glycosylated with the same pentasaccharide as that of Hfx. volcanii, but the intact pentasaccharide is synthesized on a single carrier molecule in Har. marismortui in a process that more closely resembles that of the bacterial N‐linked system.     

Differential localization of LTA synthesis proteins and their interaction with the cell division machinery in Staphylococcus aureus

Lipoteichoic acid (LTA) is an important cell wall component of Gram‐positive bacteria. In Staphylococcus aureus it consists of a polyglycerolphosphate‐chain that is retained within the membrane via a glycolipid. Using an immunofluorescence approach, we show here that the LTA polymer is not surface exposed in S. aureus, as it can only be detected after digestion of the peptidoglycan layer. S. aureus mutants lacking LTA are enlarged and show aberrant positioning of septa, suggesting a link between LTA synthesis and the cell division process. Using a bacterial two‐hybrid approach, we show that the three key LTA synthesis proteins, YpfP and LtaA, involved in glycolipid production, and LtaS, required for LTA backbone synthesis, interact with one another. All three proteins also interacted with numerous cell division and peptidoglycan synthesis proteins, suggesting the formation of a multi‐enzyme complex and providing further evidence for the co‐ordination of these processes. When assessed by fluorescence microscopy, YpfP and LtaA fluorescent protein fusions localized to the membrane while the LtaS enzyme accumulated at the cell division site. These data support a model whereby LTA backbone synthesis proceeds in S. aureus at the division site in co‐ordination with cell division, while glycolipid synthesis takes place throughout the membrane.     

Dynamics of the assembly of a complex macromolecular structure--the coat of spores of the bacterium Bacillus subtilis

The coat is the outermost layer of spores of many Bacillus species, and plays a key role in these spores' resistance. The Bacillus subtilis spore coat contains > 70 proteins in four distinct layers: the basement layer, inner coat, outer coat and crust. In this issue of Molecular Microbiology, McKenney and Eichenberger study the dynamics of spore coat assembly using GFP-fusions to 41 B. subtilis coat proteins. A key finding in the work is that formation of the spore coat is initiated by the apparently simultaneous assembly of foci of proteins from all four coat layers on the developing spore just as forespore engulfment by the mother cell begins. The expansion of these foci before completion of forespore engulfment then sets up the scaffold to which coat proteins added later in sporulation are added. This study provides new understanding of the mechanism of the assembly of a multi-protein, multi-lamellar structure.     

AglP is a S‐adenosyl‐L‐methionine‐dependent methyltransferase that participates in the N‐glycosylation pathway of Haloferax volcanii

While pathways for N‐glycosylation in Eukarya and Bacteria have been solved, considerably less is known of this post‐translational modification in Archaea. In the halophilic archaeon Haloferax volcanii, proteins encoded by the agl genes are involved in the assembly and attachment of a pentasaccharide to select asparagine residues of the S‐layer glycoprotein. AglP, originally identified based on the proximity of its encoding gene to other agl genes whose products were shown to participate in N‐glycosylation, was proposed, based on sequence homology, to serve as a methyltransferase. In the present report, gene deletion and mass spectrometry were employed to reveal that AglP is responsible for adding a 14 Da moiety to a hexuronic acid found at position four of the pentasaccharide decorating the Hfx. volcanii S‐layer glycoprotein. Subsequent purification of a tagged version of AglP and development of an in vitro assay to test the function of the protein confirmed that AglP is a S‐adenosyl‐L‐methionine‐dependent methyltransferase.     

Toolbox: Creating a systematic database of secretory pathway proteins uncovers new cargo for COPI

A third of yeast genes encode for proteins that function in the endomembrane system. However, the precise localization for many of these proteins is still uncertain. Here, we visualized a collection of ~500 N‐terminally, green fluorescent protein (GFP), tagged proteins of the yeast Saccharomyces cerevisiae. By co‐localizing them with 7 known markers of endomembrane compartments we determined the localization for over 200 of them. Using this approach, we create a systematic database of the various secretory compartments and identify several new residents. Focusing in, we now suggest that Lam5 resides in contact sites between the endoplasmic reticulum and the late Golgi. Additionally, analysis of interactions between the COPI coat and co‐localizing proteins from our screen identifies a subset of proteins that are COPI‐cargo. In summary, our approach defines the protein roster within each compartment enabling characterization of the physical and functional organization of the endomembrane system and its components.      

Automated measurement of site‐specific N‐glycosylation occupancy with SWATH‐MS

Asparagine‐linked glycosylation is a common post‐translational modification of proteins catalyzed by oligosaccharyltransferase that is important in regulating many aspects of protein function. Analysis of protein glycosylation, including glycoproteomic measurement of the site‐specific extent of glycosylation, remains challenging. Here, we developed methods combining enzymatic deglycosylation and protease digestion with SWATH‐MS to enable automated measurement of site‐specific occupancy at many glycosylation sites. Deglycosylation with peptide‐endoglycosidase H, leaving a remnant N‐acetylglucosamine on asparagines previously carrying high‐mannose glycans, followed by trypsin digestion allowed robust automated measurement of occupancy at many sites. Combining deglycosylation with the more general peptide‐N‐glycosidase F enzyme with AspN protease digest allowed robust automated differentiation of nonglycosylated and deglycosylated forms of a given glycosylation site. Ratiometric analysis of deglycosylated peptides and the total intensities of all peptides from the corresponding proteins allowed relative quantification of site‐specific glycosylation occupancy between yeast strains with various isoforms of oligosaccharyltransferase. This approach also allowed robust measurement of glycosylation sites in human salivary glycoproteins. This method for automated relative quantification of site‐specific glycosylation occupancy will be a useful tool for research with model systems and clinical samples.     

Insight into glucosidase II from the red marine microalga Porphyridium sp. (Rhodophyta)

N‐glycosylation of proteins is one of the most important post‐translational modifications that occur in various organisms, and is of utmost importance for protein function, stability, secretion, and loca‐lization. Although the N‐linked glycosylation pathway of proteins has been extensively characterized in mammals and plants, not much information is available regarding the N‐glycosylation pathway in algae. We studied the α 1,3‐glucosidase glucosidase II (GANAB) glycoenzyme in a red marine microalga Porphyridium sp. (Rhodophyta) using bioinformatic and biochemical approaches. The GANAB‐gene was found to be highly conserved evolutionarily (compo‐sed of all the common features of α and β subunits) and to exhibit similar motifs consistent with that of homolog eukaryotes GANAB genes. Phylogenetic analysis revealed its wide distribution across an evolutionarily vast range of organisms; while the α subunit is highly conserved and its phylogenic tree is similar to the taxon evolutionary tree, the β subunit is less conserved and its pattern somewhat differs from the taxon tree. In addition, the activity of the red microalgal GANAB enzyme was studied, including functional and biochemical characterization using a bioassay, indicating that the enzyme is similar to other eukaryotes ortholog GANAB enzymes. A correlation between polysaccharide production and GANAB activity, indicating its involvement in polysaccharide biosynthesis, is also demonstrated. This study represents a valuable contribution toward understanding the N‐glycosylation and polysaccharide biosynthesis pathways in red microalgae.