Michelle D. Glew

The organisation of the multigene family which encodes the major cell surface protein, pMGA, of Mycoplasma gallisepticum

The genome of the avian pathogen Mycoplasma gallisepticum contains a number of related genes for putative adhesion molecules (pMGA). Cloning and sequence analysis of several pMGA genes suggested that all of them might be transcriptionally and translationally functional. Analysis of the gene sequence encoding the sole pMGA variant expressed in vitro in the S6 strain (pMGA1.1) revealed no unambiguous feature that could account for its unique expression. It is estimated that the pMGA gene family may contain up to 50 members, and its possible role is discussed herein.

PG0026 Is the C-terminal Signal Peptidase of a Novel Secretion System of Porphyromonas gingivalis

Background: Several virulence factors of Porphyromonas gingivalis have a novel C-terminal signal that directs secretion across the outer membrane. Results: The predicted catalytic amino acid of PG0026 was essential for the removal of this signal. Conclusion: PG0026 is a novel C-terminal signal peptidase. Significance: We have identified a novel signal peptidase of a new type of secretion system. Protein substrates of a novel secretion system of Porphyromonas gingivalis contain a conserved C-terminal domain (CTD) of ∼70–80 amino acid residues that is essential for their secretion and attachment to the cell surface. The CTD itself has not been detected in mature substrates, suggesting that it may be removed by a novel signal peptidase. More than 10 proteins have been shown to be essential for the proper functioning of the secretion system, and one of these, PG0026, is a predicted cysteine proteinase that also contains a CTD, suggesting that it may be a secreted component of the secretion system and a candidate for being the CTD signal peptidase. A PG0026 deletion mutant was constructed along with a PG0026C690A targeted mutant encoding an altered catalytic Cys residue. Analysis of clarified culture fluid fractions by SDS-PAGE and mass spectrometry revealed that the CTD was released intact into the surrounding medium in the wild type strain, but not in the PG0026 mutant strains. Western blot experiments revealed that the maturation of a model substrate was stalled at the CTD-removal step specifically in the PG0026 mutants, and whole cell ELISA experiments demonstrated partial secretion of substrates to the cell surface. The CTD was also shown to be accessible at the cell surface in the PG0026 mutants, suggesting that the CTD was secreted but could not be cleaved. The data indicate that PG0026 is responsible for the cleavage of the CTD signal after substrates are secreted across the OM.

The outer membrane protein LptO is essential for the O-deacylation of LPS and the co-ordinated secretion and attachment of A-LPS and CTD proteins in Porphyromonas gingivalis

Protein substrates of a novel secretion system of Porphyromonas gingivalis contain a conserved C‐terminal domain (CTD) essential for secretion and attachment to the cell surface. Inactivation of lptO (PG0027) or porT produced mutants that lacked surface protease activity and an electron‐dense surface layer. Both mutants showed co‐accumulation of A‐LPS and unmodified CTD proteins in the periplasm. Lipid profiling by mass spectrometry showed the presence of both tetra‐ and penta‐acylated forms of mono‐phosphorylated lipid A in the wild‐type and porT mutant, while only the penta‐acylated forms of mono‐phosphorylated lipid A were found in the lptO mutant, indicating a specific role of LptO in the O‐deacylation of mono‐phosphorylated lipid A. Increased levels of non‐phosphorylated lipid A and the presence of novel phospholipids in the lptO mutant were also observed that may compensate for the missing mono‐phosphorylated tetra‐acylated lipid A in the outer membrane (OM). Molecular modelling predicted LptO to adopt a β‐barrel structure characteristic of an OM protein, supported by the enrichment of LptO in OM vesicles. The results suggest that LPS deacylation by LptO is linked to the co‐ordinated secretion of A‐LPS and CTD proteins by a novel secretion and attachment system to form a structured surface layer.

Size and genomic location of the pMGA multigene family of Mycoplasma gallisepticum.

The pMGA multigene family encodes variant copies of the cell surface haemagglutinin of Mycoplasma gallisepticum. Quantitative Southern blotting, using an oligonucleotide probe complementary to a region conserved in the leader sequence of all known pMGA genes, was used to estimate the number of members of the family in the genome of seven strains of M. gallisepticum. The number of copies estimated to be present in the genome varied from 32 in strain F to 70 in strain R, indicating that the pMGA gene family may be second in size only to the tRNA family among prokaryotes. If all members of the pMGA family are of similar length to those which have been characterized, a minimum of 79 kb (7.7%) of the genome of strain S6, 82 kb (8.2%) of PG31 and 168 kb (16%) of the genome of strain R is dedicated to encoding variants of the same haemagglutinin. The GAA repeat motif identified in the intergenic region between all characterized pMGA genes appeared to be a feature common to most, if not all, pMGA genes, and furthermore probably exclusive to them. The genomic locations of members of the pMGA family were determined by PFGE and Southern blot hybridization of M. gallisepticum strain S6. The hybridizing regions were localized to four separate regions on the chromosome. The pMGA genes are likely to be predominantly arranged as tandem repeats within these regions, similar to the restricted regions for which the genomic sequence has been determined.

pMGA Phenotypic Variation in Mycoplasma gallisepticum Occurs In Vivo and Is Mediated by Trinucleotide Repeat Length Variation

ABSTRACT Chickens were infected with a pathogenic strain of Mycoplasma gallisepticum, and the expression of pMGA, the major surface protein, was inferred by examination of colonies from ex vivo cells. Within 2 days postinfection, 40% of cells had ceased the expression of the original pMGA surface protein (pMGA1.1), and by day 6, the majority of recovered cells were in this category. The switch in pMGA phenotype which had occurred in vivo was reversible, since most colonies produced from ex vivo progenitors exhibited frequent pMGA1.1+sectors. After prolonged in vivo habitation, increasing proportions of recovered cells gave rise to variant pMGA colonies which had switched from the expression of pMGA1.1 to another gene, pMGA1.2, concomitant with the acquisition of a (GAA)12 motif 5′ to its promoter. Collectively, the results suggest that changes in M. gallisepticum pMGA gene expression in vivo are normal, common, and possibly obligate events for successful colonization of the host. Surprisingly, the initial cessation of pMGA1.1 expression occurred in the absence of detectable pMGA antibodies and seemed to precede the adaptive immune response.

Expression studies on four members of the pMGA multigene family in Mycoplasma gallisepticum S6

A large family of related genes known as pMGA exists in the avian pathogen Mycoplasma gallisepticum but only a single member of this family was previously found to be expressed in one strain of this bacterium. In this work two unrelated strains of M. gallisepticum were also shown by amino-terminal sequencing to express a unique pMGA polypeptide in both cases. To investigate pMGA gene selection in M. gallisepticum, mRNA expression was analysed in M. gallisepticum strain 56 using reverse transcription-PCR (RT-PCR) and Northern blot techniques with probes for several members of the pMGA multigene family. It was shown that the pMGA message is 2.2 kb in size and is monocistronic. RT-PCR detected four different pMGA mRNA molecules but their relative yields were significantly affected by magnesium concentration. By quantitative Northern analysis, the relative abundances of the four pMGA mRNAs in M. gallisepticum S6 total RNA was determined: the pMGA1.1 mRNA predominated [1.88 ng (micrograms total RNA)-1] but at least three other pMGA genes were found to be transcribed but at much lower levels (20 to 40-fold lower). The pMGA1.1 mRNA is expressed at a level five times higher than the tuf gene, known to be one of the most abundantly expressed proteins in the prokaryotic cell. The start point of transcription for pMGA1.1 was determined and probable promoter assigned. From these data it appears likely that transcriptional control plays a major role in the selection of pMGA gene expression in the M. gallisepticum cell.

A gene family in Mycoplasma imitans closely related to the pMGA family of Mycoplasma gallisepticum

The avian pathogen Mycoplasma gallisepticum possesses a large gene family encoding lipoproteins which function as haemagglutinins. Representative species of the pneumoniae phylogenetic group of mycoplasmas were examined for the presence of genes homologous to members of this multigene family. Antisera against the pMGA1.1 lipoprotein recognized a 35 kDa protein in Mycoplasma imitans, but did not recognize proteins of Mycoplasma genitalium, Mycoplasma pneumoniae, Mycoplasma pirum, Mycoplasma penetrans of Mycoplasma iowae in Western blots. A fragment of the pMGA 1.2 gene and oligonucleotide probes complementary to highly conserved coding and non-coding regions of pMGA genes bound to fragments of genomic DNA of M. imitans, but not to the genomes of M. genitalium, M. pneumoniae, M. pirum or M. penetrans, and only one probe bound to a fragment of the M. iowae genome. One homologue of the pMGA genes was amplified from the M. imitans genome by PCR and used as a probe to clone a 3.1 kbp DNA fragment from a library of HindIII-digested M. imitans genomic DNA. The contiguous DNA sequence of the PCR and HindIII clones was predicted to encode one complete and one partial ORF which shared some peptide sequence identity with the pMGA genes, including the signal peptidase II cleavage site and the proline-rich amino-terminal region. Like the pMGA genes, the M. imitans genes were found to be members of a large gene family, with an association with GAA trinucleotide repeats, a feature which distinguishes these two families from the homologous vlhA gene family in Mycoplasma synoviae. The identification of these gene families in three phylogenetically distinct avian mycoplasma species, but not in human mycoplasmas, suggests their horizontal transfer between species infecting the same host.

Porphyromonas gingivalis Type IX Secretion Substrates Are Cleaved and Modified by a Sortase-Like Mechanism

The type IX secretion system (T9SS) of Porphyromonas gingivalis secretes proteins possessing a conserved C-terminal domain (CTD) to the cell surface. The C-terminal signal is essential for these proteins to translocate across the outer membrane via the T9SS. On the surface the CTD of these proteins is cleaved prior to extensive glycosylation. It is believed that the modification on these CTD proteins is anionic lipopolysaccharide (A-LPS), which enables the attachment of CTD proteins to the cell surface. However, the exact site of modification and the mechanism of attachment of CTD proteins to the cell surface are unknown. In this study we characterized two wbaP (PG1964) mutants that did not synthesise A-LPS and accumulated CTD proteins in the clarified culture fluid (CCF). The CTDs of the CTD proteins in the CCF were cleaved suggesting normal secretion, however, the CTD proteins were not glycosylated. Mass spectrometric analysis of CTD proteins purified from the CCF of the wbaP mutants revealed the presence of various peptide/amino acid modifications from the growth medium at the C-terminus of the mature CTD proteins. This suggested that modification occurs at the C-terminus of T9SS substrates in the wild type P. gingivalis. This was confirmed by analysis of CTD proteins from wild type, where a 648 Da linker was identified to be attached at the C-terminus of mature CTD proteins. Importantly, treatment with proteinase K released the 648 Da linker from the CTD proteins demonstrating a peptide bond between the C-terminus and the modification. Together, this is suggestive of a mechanism similar to sortase A for the cleavage and modification/attachment of CTD proteins in P. gingivalis. PG0026 has been recognized as the CTD signal peptidase and is now proposed to be the sortase-like protein in P. gingivalis. To our knowledge, this is the first biochemical evidence suggesting a sortase-like mechanism in Gram-negative bacteria.

Blue native-PAGE analysis of membrane protein complexes in Porphyromonas gingivalis

UNLABELLED Membrane complexes of Porphyromonas gingivalis were analyzed using two dimensional-blue native-PAGE. The molecular mass of the gingipain complexes, RgpA and Kgp, ranged from 450 kDa to greater than 1200 kDa, and did not change in single rgpA and kgp mutants indicating that the proteolytically processed polyproteins were independently capable of forming complexes. The outer membrane protein, LptO, which is essential for gingipain secretion, was found in up to seven different complex sizes. PG0026, also important for secretion, was observed to interact with the largest LptO complex [VII] at 480 kDa, supporting a cooperative role in secretion. Two pro-form RgpB intermediates formed a complex before cleavage of their C-terminal secretion signal domains (CTDs) such that complex formation may occur during secretion and processing. This may also be the case for other CTD-proteins as not only modified, mature RgpB, but also CPG70 was found to exist as multi-subunit complexes. RagA and RagB were observed in three different complex sizes. Elimination of the abundant gingipains enabled the identification of many inner and outer membrane protein complexes: TonB:ExbB:ExbD, Omp85, P51:PG2168, PorK:PorN, PG0056, PG0241, PG1430 and five proposed respiratory chain complexes (Mmd, Nqr, Rnf, Frd/Sdh and Atp). BIOLOGICAL SIGNIFICANCE Porphyromonas gingivalis is a major oral pathogen associated with chronic periodontitis in humans. Secreted gingipains are considered major virulence factors of this pathogen and are secreted by a newly described type IX secretion system. This work has used 2D-BN-PAGE and MS to demonstrate that mature gingipains can independently form complexes and that substrate intermediates and mature secreted proteins of the type IX secretion system form multi-subunit complexes. Based on this work we propose that the substrates of this secretion system are secreted as large multi-subunit protein complexes. Two known important components of the secretion machinery, PG0026 and the integral outer membrane protein, LptO, were found to interact which would anchor PG0026 to the outer membrane and perhaps aid in the function of PG0026 to cleave the CTD from secreted substrates. The work has also identified more than 100 membrane proteins forming multi-subunit complexes.

Structural Insights into the PorK and PorN Components of the Porphyromonas gingivalis Type IX Secretion System

The type IX secretion system (T9SS) has been recently discovered and is specific to Bacteroidetes species. Porphyromonas gingivalis, a keystone pathogen for periodontitis, utilizes the T9SS to transport many proteins including the gingipain virulence factors across the outer membrane and attach them to the cell surface via a sortase-like mechanism. At least 11 proteins have been identified as components of the T9SS including PorK, PorL, PorM, PorN and PorP, however the precise roles of most of these proteins have not been elucidated and the structural organization of these components is unknown. In this study, we purified PorK and PorN complexes from P. gingivalis and using electron microscopy we have shown that PorN and the PorK lipoprotein interact to form a 50 nm diameter ring-shaped structure containing approximately 32–36 subunits of each protein. The formation of these rings was dependent on both PorK and PorN, but was independent of PorL, PorM and PorP. PorL and PorM were found to form a separate stable complex. PorK and PorN were protected from proteinase K cleavage when present in undisrupted cells, but were rapidly degraded when the cells were lysed, which together with bioinformatic analyses suggests that these proteins are exposed in the periplasm and anchored to the outer membrane via the PorK lipid. Chemical cross-linking and mass spectrometry analyses confirmed the interaction between PorK and PorN and further revealed that they interact with the PG0189 outer membrane protein. Furthermore, we established that PorN was required for the stable expression of PorK, PorL and PorM. Collectively, these results suggest that the ring-shaped PorK/N complex may form part of the secretion channel of the T9SS. This is the first report showing the structural organization of any T9SS component.