Proteins In Gram-positive Bacteria Research Articles

Housekeeping sortase facilitates the cell wall anchoring of pilus polymers in Corynebacterium diphtheriae

Many surface proteins in Gram-positive bacteria are covalently linked to the cell wall through a transpeptidation reaction catalysed by the enzyme sortase. Corynebacterium diphtheriae encodes six sortases, five of which are devoted to the assembly of three distinct types of pilus fibres--SrtA for the SpaA-type pilus, SrtB/SrtC for the SpaD-type pilus, and SrtD/SrtE for the SpaH-type pilus. We demonstrate here the function of SrtF, the so-called housekeeping sortase, in the cell wall anchoring of pili. We show that a multiple deletion mutant strain expressing only SrtA secretes a large portion of SpaA polymers into the culture medium, with concomitant decrease in the cell wall-linked pili. The same phenotype is observed with the mutant that is missing SrtF alone. By contrast, a strain that expresses only SrtF displays surface-linked pilins but no polymers. Therefore, SrtF can catalyse the cell wall anchoring of pilin monomers as well as pili, but it does not polymerize pilins. We show that SrtA and SrtF together generate wild-type levels of the SpaA-type pilus on the bacterial surface. Furthermore, by regulating the expression of SpaA in the cell, we demonstrate that the SrtF function becomes critical when the SpaA level is sufficiently high. Together, these findings provide key evidence for a two-stage model of pilus assembly: pilins are first polymerized by a pilus-specific sortase, and the resulting fibre is then attached to the cell wall by either the cognate sortase or the housekeeping sortase.

Haem recognition by a Staphylococcus aureus NEAT domain

Successful pathogenic organisms have developed mechanisms to thrive under extreme levels of iron restriction. Haem-iron represents the largest iron reservoir in the human body and is a significant source of iron for some bacterial pathogens. NEAT (NEAr Transporter) domains are found exclusively in a family of cell surface proteins in Gram-positive bacteria. Many NEAT domain-containing proteins, including IsdA in Staphylococcus aureus, are implicated in haem binding. Here, we show that overexpression of IsdA in S. aureus enhances growth and an inactivation mutant of IsdA has a growth defect, compared with wild type, when grown in media containing haem as the sole iron source. Furthermore, the haem-binding property of IsdA is contained within the NEAT domain. Crystal structures of the apo-IsdA NEAT domain and in complex with haem were solved and reveal a clathrin adapter-like beta-sandwich fold with a large hydrophobic haem-binding pocket. Haem is bound with the propionate groups directed at the molecular surface and the iron is co-ordinated solely by Tyr(166). The phenol groups of Tyr(166) and Tyr(170) form an H-bond that may function in regulating haem binding and release. An analysis of IsdA structure-sequence alignments indicate that conservation of Tyr(166) is a predictor of haem binding by NEAT domains.

Oxidative thiol modifications in proteins of Gram-positive bacteria

Oxidative thiol modifications in proteins of Gram-positive bacteria

SclC is a member of a novel family of collagen-like proteins in Streptococcus equi subspecies equi that are recognised by antibodies against SclC

Previously we have reported on a cell surface collagen-like protein, called SclC, from Streptococcus equi subspecies equi. In the present study we show that this protein is a member of a family of seven collagen-like proteins, called SclC-SclI in this subspecies. All proteins contain an N-terminal signal sequence, followed by a unique non-repetitive region called A, a highly repetitive collagen-like region (CL) consisting of Glycine-Xaa-Yaa-triplet repeats. Following the CL-region a C-terminal proline-rich putative wall spanning region (W) preceding an LPXTG-motif and a hydrophobic transmembrane region (M) are found, typical features of cell surface exposed proteins in Gram-positive bacteria. The nucleotide and amino acid sequences, were analysed to investigate the similarities between them, and recombinant proteins encoding different domains (A- and CL-regions) were expressed and purified. Although the novel collagen-like proteins display differences in amino acid sequences, affinity purified antibodies against SclC were found to cross react with the other members of the novel collagen-like proteins. Furthermore, in sera from horses previously diagnosed having strangles, antibodies against these proteins were detected suggesting that these proteins are expressed during the infection.

SWIFT (sequence-wide investigation with Fourier transform): a software tool for identifying proteins of a given class from the unannotated genome sequence

The ever increasing number of sequenced genomes calls for new analysis techniques, which can benefit from the methodologies developed in the field of signal processing. The present paper addresses the question of searching a pattern of amino acids (not necessarily completely specified) by means of the cross-correlation of complex sequences, obtained after suitable coding of the original amino acid sequence. Subsequently, the proposed algorithm provides a flexible strategy in setting the border between the accepted and rejected ORFs, by means of the k-means clustering of the candidate ORFs. The search for the class of proteins specified by the pattern is carried out from the most basic level, i.e. the DNA sequence, without sifting through an ensemble of previously determined ORFs. Thus, an exhaustive examination of all the occurrences of the pattern in the genome is performed. The application of the method to the search of surface proteins in Gram-positive bacteria witnesses its efficacy, in terms of both sensitivity and specificity. The comparison with the usual (and somewhat arbitrary) choice of setting a fixed value for the threshold length of the putative ORF confirms the validity of the proposed approach.

Identification of a novel collagen-like protein, SclC, in Streptococcus equi using signal sequence phage display

Strangles is a serious disease in horses caused by Streptococcus equi subspecies equi. In this study, genes encoding putative extracellular proteins in this subspecies have been identified using signal sequence phage display. Among these, one showed similarities to the SclB protein, a member of the collagen-like proteins of Streptococcus pyogenes. The novel gene denoted sclC encodes a protein, SclC, of 302 amino acids, containing typical features found in cell wall-anchored proteins in Gram-positive bacteria. Based on similarities to the S. pyogenes collagen-like proteins the mature SclC protein can be divided into various domains: an N-terminal non-repetitive region (A), a highly repetitive collagen-like region (CL), and a C-terminal proline-rich wall-associated region (W). Using PCR, the sclC gene was detected in all studied strains of S. equi subsp. equi and S. equi subsp. zooepidemicus. Further, antibodies against recombinant SclC were detected in a collection of sera from horses with no history of strangles as well as horses previously infected with S. equi subsp. equi. Interestingly, the sera from convalescence horses were found to have significantly increased antibody titers against the SclC protein indicating that this protein is expressed during infection of S. equi subsp. equi.

Localization and mutagenesis of the sorting signal binding site on sortase A from Staphylococcus aureus

Surface proteins in Gram-positive bacteria are anchored to the cell wall by the action of sortase enzymes. The Staphylococcus aureus sortase A (SrtA) protein anchors proteins by recognizing a cell wall sorting signal containing the amino acid sequence LPXTG. To understand how SrtA binds this sequence, we carried out NMR studies of new peptidyl-cyanoalkene and peptidyl-sulfhydryl inhibitors that contain the sorting signal sequence LPAT. These studies combined with amino acid mutagenesis identified a catalytically important and conserved binding surface formed by residues A118, T180, and I182. Compatible with its recently proposed role as a general base, R197 is also shown to be required for catalysis.

Post-translocational folding of secretory proteins in Gram-positive bacteria

The transport of proteins from their site of synthesis in the cytoplasm to their functional location is an essential characteristic of all living cells. In Gram-positive bacteria the majority of proteins that are translocated across the cytoplasmic membrane are delivered to the membrane–cell wall interface in an essentially unfolded form. They must then be folded into their native configuration in an environment that is dominated by a high density of immobilised negative charge—in essence an ion exchange resin. It is essential to the viability of the cell that these proteins do not block the translocation machinery in the membrane, form illegitimate interactions with the cell wall or, through intermolecular interactions, form insoluble aggregates. Native Gram-positive proteins therefore have intrinsic folding characteristics that facilitate their rapid folding, and this is assisted by a variety of folding factors, including enzymes, peptides and metal ions. Despite these intrinsic and extrinsic factors, secretory proteins do misfold, particularly if the cell is subjected to certain types of stress. Consequently, Gram-positive bacteria such as Bacillus subtilis encode membrane- and cell wall-associated proteases that act as a quality control machine, clearing misfolded or otherwise aberrant proteins from the translocase and the cell wall.

Role for serine protease HtrA (DegP) of Streptococcus pyogenes in the biogenesis of virulence factors SpeB and the hemolysin streptolysin S.

The serine protease HtrA is involved in the folding and maturation of secreted proteins, as well as in the degradation of proteins that misfold during secretion. Depletion of HtrA has been shown to affect the sensitivity of many organisms to thermal and environmental stresses, as well as being essential for virulence in many pathogens. In the present study, we compared the behaviors of several different HtrA mutants of the gram-positive pathogen Streptococcus pyogenes (group A streptococcus). Consistent with prior reports, insertional inactivation of htrA, the gene that encodes HtrA, resulted in a mutant that grew poorly at 37 degrees C. However, an identical phenotype was observed when a similar polar insertion was placed immediately downstream of htrA in the streptococcal chromosome, suggesting that the growth defect of the insertion mutant was not a direct result of insertional inactivation of htrA. This conclusion was supported by the observation that a nonpolar deletion mutation of htrA did not produce the growth defect. However, this mutation did affect the production of several secreted virulence factors whose biogenesis requires extensive processing. For the SpeB cysteine protease, the loss of HtrA was associated with a failure to proteolytically process the zymogen to an active protease. For the streptolysin S hemolysin, a dramatic increase in hemolytic activity resulted from the depletion of HtrA. Interestingly, HtrA-deficient mutants were not attenuated in a murine model of subcutaneous infection. These data add to the growing body of information that implies an important role for HtrA in the biogenesis of secreted proteins in gram-positive bacteria.

CNE, a collagen-binding protein of Streptococcus equi

Streptococcus equi subspecies equi is an important horse pathogenic bacterium causing a serious disease called strangles. Using bioinformatics we identified a gene denoted cne (gene encoding collage n-binding protein from S. equi) coding for a novel potential virulence factor of this species called protein CNE. The protein is composed of 657 amino acids and has the typical features found in cell surface-anchored proteins in Gram-positive bacteria. CNE displays amino acid sequence similarities to the previously well-studied collagen-binding protein CNA from Staphylococcus aureus, a proven virulence factor in septic arthritis. Based on similarity to CNA the structure of the mature CNE protein can be divided into an N-terminal A domain and a C-terminal B domain. The highest similarity between CNA and CNE is found in the A domains. The A domain in CNA is known to be the collagen-binding domain. Two parts of cne were amplified using polymerase chain reaction (PCR) and ligated into an expression vector, and recombinant CNE proteins were produced in Escherichia coli. The purified CNE proteins were shown to display collagen-binding activity in a Western ligand blot and to inhibit collagen binding to cells of subsp. equi and to CNE-coated microtitre wells. Furthermore, the A domain of CNE was sufficient for binding collagen, and was shown to compete for the same site on collagen as CNA in inhibition studies. Using PCR, the cne gene was detected in all studied strains of subsp. equi and S. equi subsp. zooepidemicus.

Translocation of proteins across the cell envelope of Gram-positive bacteria.

In contrast to Gram-negative bacteria, secretory proteins of Gram-positive bacteria only need to traverse a single membrane to enter the extracellular environment. For this reason, Gram-positive bacteria (e.g. various Bacillus species) are often used in industry for the commercial production of extracellular proteins that can be produced in yields of several grams per liter culture medium. The central components of the main protein translocation system (Sec system) of Gram-negative and Gram-positive bacteria show a high degree of conservation, suggesting similar functions and working mechanisms. Despite this fact, several differences can be identified such as the absence of a clear homolog of the secretion-specific chaperone SecB in Gram-positive bacteria. The now available detailed insight into the organization of the Gram-positive protein secretion system and how it differs from the well-characterized system of Escherichia coli may in the future facilitate the exploitation of these organisms in the high level production of heterologous proteins which, so far, is sometimes very inefficient due to one or more bottlenecks in the secretion pathway. In this review, we summarize the current knowledge on the various steps of the protein secretion pathway of Gram-positive bacteria with emphasis on Bacillus subtilis, which during the last decade, has arisen as a model system for the study of protein secretion in this industrially important class of microorganisms.

D-Alanine substitution of teichoic acids as a modulator of protein folding and stability at the cytoplasmic membrane/cell wall interface of Bacillus subtilis.

The extracytoplasmic folding of secreted proteins in Gram-positive bacteria is influenced by the microenvironment of the compartment into which they are translocated, namely the negatively charged matrix of the cell wall polymers. In this compartment, the PrsA lipoprotein facilitates correct post-translocational folding or prevents misfolding of secreted proteins. In this study, a secretion mutant of B. subtilis (prsA3) encoding a defective PrsA protein was mutagenized and screened for restored secretion of the AmyQ alpha-amylase. One mini-Tn10 insertion, which partially suppressed the secretion deficiency, was found to interrupt dlt, the operon involved in the d-alanylation of teichoic acids. The inactivation of dlt rescued the mutant PrsA3 protein from degradation, and the increased amount of PrsA3 was shown to enhance the secretion of PrsA-dependent proteins. Heterologous or abnormal secreted proteins, which are prone to degradation after translocation, were also stabilized and secreted in increased quantities from a dlt prsA(+) strain. Furthermore, the dlt mutation partially suppressed the lethal effect of PrsA depletion, suggesting that the dlt deficiency also leads to stabilization of an essential cell wall protein(s). Our results suggest that main influence of the increased net negative charge of the wall caused by the absence of d-alanine is to increase the rate of post-translocational folding of exported proteins.

Sortase: the surface protein anchoring transpeptidase and the LPXTG motif

Although it is clear that the correct gene has been isolated, an attempt to repair the thermosensitivity of the sortase mutant by complementation has met with minimal success, suggesting that sortase might not be essential after all and that the temperature sensitivity was owing to a coincidental mutation in a second, essential gene. This has recently been corroborated by the finding that a sortase knockout is viable (O. Schneewind, pers. commun.). Although widely predicted on the presumption of essentiality to be an attractive target for the identification of novel antimicrobials, the non-essential nature of sortase has required some rethinking – presently, virulence tests of the sortase knockout are underway, with the idea that an anti-sortase agent could block virulence in a wide spectrum of Gram-positive bacteria, even if it did not block growth.Interestingly, in the sortase mutant, as with protein mutants lacking the LPXTG motif, the proteins that would normally be attached to the cell wall peptidoglycan do not associate with the cell wall, confirming that the carboxy- terminal membrane anchor is not sufficient, nor do they accumulate, either extra- or intracellularly (O. Schneewind, pers. commun.). Perhaps the accumulation of membrane-bound surface protein intermediates that cannot be sorted or secreted is toxic to the cell – as was originally found for Escherichia coli β galactosidase fused to a secretion signal17xSuppressor mutations that restore export of a protein with a defective signal sequence. Emr, S.D. et al. Cell. 1981; 23: 79–88Abstract | Full Text PDF | PubMed | Scopus (154)See all References, 18xE. coli mutant pleiotropically defective in the export of secreted proteins. Oliver, D.B. and Beckwith, J. Cell. 1981; 25: 765–772Abstract | Full Text PDF | PubMed | Scopus (203)See all References. Accordingly, there is probably an auto-regulatory system governing the synthesis and fate of the surface proteins, preventing their accumulation when sorting is defective.In conclusion, the elegant recent work of Schneewind and co- workers has provided final confirmation for the idea that surface proteins in Gram-positive bacteria are covalently anchored to the cell wall. Although this has been quite clear for nearly 30 years, nagging doubts remained and these must finally be laid to rest by the isolation and analysis of sortase.

Adherence of the gram-positive bacterium Ruminococcus albus to cellulose and identification of a novel form of cellulose-binding protein which belongs to the Pil family of proteins.

The adherence of Ruminococcus albus 8 to crystalline cellulose was studied, and an affinity-based assay was also used to identify candidate cellulose-binding protein(s). Bacterial adherence in cellulose-binding assays was significantly increased by the inclusion of either ruminal fluid or micromolar concentrations of both phenylacetic and phenylpropionic acids in the growth medium, and the addition of carboxymethylcellulose (CMC) to assays decreased the adherence of the bacterium to cellulose. A cellulose-binding protein with an estimated molecular mass following sodium dodecyl sulfate-polyacrylamide gel electrophoresis of approximately 21 kDa, designated CbpC, was present in both cellobiose- and cellulose-grown cultures, and the relative abundance of this protein increased in response to growth on cellulose. Addition of 0.1% (wt/vol) CMC to the binding assays had an inhibitory effect on CbpC binding to cellulose, consistent with the notion that CbpC plays a role in bacterial attachment to cellulose. The nucleotide sequence of the cbpC gene was determined by a combination of reverse genetics and genomic walking procedures. The cbpC gene encodes a protein of 169 amino acids with a calculated molecular mass of 17,655 Da. The amino-terminal third of the CbpC protein possesses the motif characteristic of the Pil family of proteins, which are most commonly involved with the formation of type 4 fimbriae and other surface-associated protein complexes in gram-negative, pathogenic bacteria. The remainder of the predicted CbpC sequence was found to have significant identity with 72- and 75-amino-acid motifs tandemly repeated in the 190-kDa surface antigen protein of Rickettsia spp., as well as one of the major capsid glycoproteins of the Chlorella virus PBCV-1. Northern blot analysis showed that phenylpropionic acid and ruminal fluid increase cbpC mRNA abundance in cellobiose-grown cells. These results suggest that CbpC is a novel cellulose-binding protein that may be involved in adherence of R. albus to substrate and extends understanding of the distribution of the Pil family of proteins in gram-positive bacteria.

Ccs1, a Nuclear Gene Required for the Post-translational Assembly of Chloroplast c-Type Cytochromes

Nuclear genes play important regulatory roles in the biogenesis of the photosynthetic apparatus of eukaryotic cells by encoding factors that control steps ranging from chloroplast gene transcription to post-translational processes. However, the identities of these genes and the mechanisms by which they govern these processes are largely unknown. By using glass bead-mediated transformation to generate insertional mutations in the nuclear genome of Chlamydomonas reinhardtii, we have generated four mutants that are defective in the accumulation of the cytochrome b6f complex. One of them, strain abf3, also fails to accumulate holocytochrome c6. We have isolated a gene, Ccs1, from a C. reinhardtii genomic library that complements both the cytochrome b6f and cytochrome c6 deficiencies in abf3. The predicted protein product displays significant identity with Ycf44 from the brown alga Odontella sinensis, the red alga Porphyra purpurea, and the cyanobacterium Synechocystis strain PCC 6803 (25-33% identity). In addition, we note limited sequence similarity with ResB of Bacillus subtilis and an open reading frame in a homologous operon in Mycobacterium leprae (11-12% identity). On the basis of the pleiotropic c-type cytochrome deficiency in the ccs1 mutant, the predicted plastid localization of the protein, and its relationship to candidate cytochrome biosynthesis proteins in Gram-positive bacteria, we conclude that Ccs1 encodes a protein that is required for chloroplast c-type holocytochrome formation.

Characterization of energetically functional inverted membrane vesicles from Corynebacterium glutamicum

We show that inverted membrane vesicles from Corynebacteriwn glutamicum, a Gram-positive bacterium, are able to generate and maintain an electrochemical gradient of protons in response to the addition of NADH. This result indicates that the respiratory chain is intact and that the vesicles are reasonably impermeable to protons. These membrane vesicles may be the starting point for in vitro translocation studies of proteins in Gram-positive bacteria.

Proteolytic cleavage and cell wall anchoring at the LPXTG motif of surface proteins in Gram‐positive bacteria

Many surface proteins are thought to be anchored to the cell wall of Gram-positive bacteria via their C-terminus. Cell wall anchoring requires a specific sorting signal, normally located at the predicted C-terminus of surface proteins. Here we show that when placed into the middle of a polypeptide chain, the sorting signal causes the specific cleavage of the precursor as well as the cell wall anchoring of its N-terminal fragment, while the C-terminal fragment remains within the cytoplasm. N-terminal sequencing of the C-terminal cleavage fragment suggests that the cleavage site is located between threonine (T) and glycine (G) of the LPXTG motif, the signature sequence of cell wall sorting signals. All surface proteins harbouring an LPXTG sequence motif may therefore be cleaved and anchored by a universal mechanism. We also propose a novel hypothesis for the cell wall linkage of surface proteins in Gram-positive bacteria.

Identification of an endogenous membrane anchor-cleaving enzyme for group A streptococcal M protein. Its implication for the attachment of surface proteins in gram-positive bacteria.

How streptococcal M protein or other surface proteins of gram-positive bacteria are anchored to the cell is poorly understood. Previously, we reported that M protein released after cell wall removal with a muralytic enzyme lacked the COOH terminal hydrophobic amino acids and charged tail predicted from DNA sequence. An endogenous membrane anchor-cleaving enzyme has now been identified with the ability to release M protein from isolated streptococcal protoplasts. At pH 5.5 in the presence of 30% raffinose, the streptococcal cell wall may be removed with a muralytic enzyme without releasing M protein from the resulting protoplasts indicating that the M molecule is attached through the bacterial cytoplasmic membrane. Release of M molecules occurs when the M protein-charged protoplasts are placed in raffinose buffer at pH 7.4. Although Zn2+, Cd2+, Ca2+, PHMB, and pHMPS inhibit the activity of the releasing enzyme, the blocking activity of Zn2+, Cd2+, and Ca2+ are reversible while PHMB and pHMPS are irreversible. PHMB-treated protoplasts are unable to release M protein at pH 7.4. However, M protein is liberated from these protoplasts when mixed with those prepared from M- streptococci serving as an enzyme source. The supernatant from M- protoplasts is unable to release M protein from PHMB-inactivated M+ protoplasts, confirming that the anchor-cleaving enzyme is membrane bound. Thus, the M protein releasing activity appears to be the result of a thiol-dependent anchor-cleaving enzyme. Streptococcal membranes treated with sodium carbonate and Triton X-114 still retain the M protein verifying that it is an integral membrane molecule. Evidence also is presented indicating significant sequence similarity between M protein and certain GPI-anchored proteins in the region responsible for protein anchoring.

Construction and use of signal sequence selection vectors in Escherichia coli and Bacillus subtilis.

To study the diversity and efficiency of signal peptides for secreted proteins in gram-positive bacteria, two plasmid vectors were constructed which were used to probe for export signal-coding regions in Bacillus subtilis. The vectors contained genes coding for extracellular proteins (the alpha-amylase gene from Bacillus licheniformis and the beta-lactamase gene from Escherichia coli) which lacked a functional signal sequence. By shotgun cloning of restriction fragments from B. subtilis chromosomal DNA, a great variety of different export-coding regions were selected. These regions were functional both in B. subtilis and in E. coli. In a number of cases where protein export had been restored, intracellular precursor proteins of increased size could be detected, which upon translocation across the cellular membrane were processed to mature products. The high frequency with which export signal-coding regions were obtained suggests that, in addition to natural signal sequences, many randomly cloned sequences can function as export signal.

32] Engineering for protein secretion in gram-positive bacteria

The chapter presents a discussion on engineering for protein secretion in gram-positive bacteria. The ability of gram-positive bacteria to excrete proteins into the medium makes them the more favorable candidates as the host organisms for the production of secreted proteins. Some members of this group of bacteria produce a number of economically important exoenzymes, such as cellulases, α-amylase, and proteases, in large quantity. The chapter discusses a number of examples of expression and directed secretion of heterologous proteins in gram-positive bacteria. Generally, the precursors to all secreted proteins contain an amino terminal extension of about 20 to 35 residues in length known as the “signal peptide.” This fragment, although relatively short in length, plays a central role in protein translocation across membranes. Mostly, this signal peptide is removed from the precursor by signal peptidases either co- or post-translationally, resulting in the formation of the mature protein in the designated extracytoplasmic locations. Signal peptide can be divided into three distinct regions based on their common structural features, which are as follows: (1) the amino terminal region, which contains one or more positively charged residues, (2) a stretch of 10–20 hydrophobic or neutral residues, and (3) the carboxy end four to seven residues, including the signal peptidase cleavage site sequence. The majority of the secretion studies in gram-positive bacteria have been conducted using B. subtilis.