Edeltraud Lüneberg

Chromosomal insertion and excision of a 30 kb unstable genetic element is responsible for phase variation of lipopolysaccharide and other virulence determinants in Legionella pneumophila

We recently described the phase‐variable expression of a virulence‐associated lipopolysaccharide (LPS) epitope in Legionella pneumophila. In this study, the molecular mechanism for phase variation was investigated. We identified a 30 kb unstable genetic element as the molecular origin for LPS phase variation. Thirty putative genes were encoded on the 30 kb sequence, organized in two putative opposite transcription units. Some of the open reading frames (ORFs) shared homologies with bacteriophage genes, suggesting that the 30 kb element was of phage origin. In the virulent wild‐type strain, the 30 kb element was located on the chromosome, whereas excision from the chromosome and replication as a high‐copy plasmid resulted in the mutant phenotype, which is characterized by alteration of an LPS epitope and loss of virulence. Mapping and sequencing of the insertion site in the genome revealed that the chromosomal attachment site was located in an intergenic region flanked by genes of unknown function. As phage release could not be induced by mitomycin C, it is conceivable that the 30 kb element is a non‐functional phage remnant. The protein encoded by ORF T on the 30 kb plasmid could be isolated by an outer membrane preparation, indicating that the genes encoded on the 30 kb element are expressed in the mutant phenotype. Therefore, it is conceivable that the phenotypic alterations seen in the mutant depend on high‐copy replication of the 30 kb element and expression of the encoded genes. Excision of the 30 kb element from the chromosome was found to occur in a RecA‐independent pathway, presumably by the involvement of RecE, RecT and RusA homologues that are encoded on the 30 kb element.

Cloning and functional characterization of a 30 kb gene locus required for lipopolysaccharide biosynthesis in Legionella pneumophila

The spontaneous Legionella pneumophila lipopolysaccharide (LPS) mutant 137, which did not bind the LPS-specific mAb 2625, was complemented with a genomic library from the parental wild-type strain. Transformants were screened for reconstitution of the wild-type LPS phenotype, able to bind mAb 2625. By this strategy, a 32,661 bp region comprising 30 open reading frames (Orfs) was identified. Orfs with significant homologies to genes encoding enzymes required for LPS or capsule biosynthesis of Gram-negative bacteria were located on the gene locus. The mutation of strain 137 could be assigned to a deletion of a cytosine residue in Orf 8. The protein encoded by Orf 8 exhibited homology to bacterial methyl-transferases. The L. pneumophila LPS gene locus included genes with deduced products likely to be involved in LPS core oligosaccharide biosynthesis (rmlA-D, rhamnosyl-transferases, acetyl-transferase) as well as LPS O-chain biosynthesis and translocation (mnaA, neuB, neuA, wecA, wzt, wzm). The neuA (Orf 25) and neuB (Orf 24) gene products were functionally characterized by complementation of the capsule negative E. coli K1 mutants EV5 and EV24, respectively. By introduction of the L. pneumophila neuA gene into E. coli EV5 and the neuB gene into EV24, expression of the K1 polysialic acid capsule could be restored. We, therefore, conclude that the biosynthesis pathway of legionaminic acid, the structural unit of the L. pneumophila Sg1 O-antigen, might be similar to the biosynthesis of sialic acid. Southern blot analysis indicated the entire gene locus to be present in L. pneumophila serogroup (Sg)1 strains, whereas only parts of the DNA stretch hybridized to DNA from Sg2 to Sg14 strains.

A point mutation in the active site of Legionella pneumophila O-acetyltransferase results in modified lipopolysaccharide but does not influence virulence

The majority of clinical isolates of Legionella pneumophila serogroup 1 produce lipopolysaccharide (LPS) that reacts with monoclonal antibody (MAb) 3/1. By using a negative cell sorting method, we isolated a spontaneous LPS mutant from L. pneumophila serogroup 1 strain Corby that lost reactivity with this MAb. The mutant contained a single nucleotide exchange in position 169 of the lag-1 gene that encodes an O-acetyltransferase that is responsible for O-acetylation of the L. pneumophila O-repeat unit (legionaminic acid). This mutation resulted in a single amino acid exchange in a highly conserved motif present in many O-acetyltransferase-like proteins. RT-PCR analysis revealed that the mutant lag-1 gene was transcribed, but the resulting protein lacked O-acetyltransferase activity. Chemical analysis of the mutant LPS revealed that it lacked 8-O-acetyl groups in legionaminic acid. In addition, the mutant failed to produce high-molecular-weight long-chain O-polysaccharide. Complementation of the mutant with the wild-type lag-1 gene restored reactivity with MAb 3/1 and the chemical structure of the wild-type LPS. Strain Corby and its MAb 3/1-negative mutant were indistinguishable in their serum resistance characteristics, and in uptake and intracellular multiplication in Acanthamoeba castellanii and macrophages.

Sequence and expression in Escherichia coli of a Mycoplasma hominis gene encoding elongation factor Tu

We describe the molecular cloning and the complete nucleotide (nt) sequence of a Mycoplasma hominis gene common to a broad range of Mycoplasma species, as defined by hybridization analysis with the cloned gene. Production of M. hominis protein in Escherichia coli was assayed by use of a monoclonal antibody. The nt sequence analysis revealed a 1194-bp open reading frame that could encode a 43 516-Da protein. Computer-aided sequence comparison indicated that the gene codes for elongation factor Tu.

Lipooligosaccharide of Campylobacter jejuni prevents myelin-specific enteral tolerance to autoimmune neuritis--a potential mechanism in Guillain-Barre syndrome?

Campylobacter jejuni-induced enteritis is the most common infection preceding Guillain-Barre syndrome (GBS), an immune-mediated polyradiculoneuritis. The acute autoimmune attack is thought to be based on C. jejuni antigens which may mimick antigens of the peripheral nervous system. Additional pathomechanisms, like disturbance of natural T cell immunoregulation by C. jejuni, have not been evaluated so far. In experimental autoimmune neuritis (EAN), a T lymphocyte-mediated animal model of human GBS, tolerance to myelin-derived autoantigens can be induced by oral feeding of the respective antigen. Here we investigated whether the lipooligosaccharide (LOS) fraction of C. jejuni may directly alter immunologic tolerance through gastrointestinal pathways. While EAN, actively induced by immunization with bovine peripheral nerve myelin could be ameliorated by precedent feeding of myelin, feeding of C. jejuni LOS along with the myelin antigen not only prevented the tolerizing effects of oral myelin but even accelerated the onset of overt EAN and augmented the myelin-specific B cell response. These findings provide evidence that LOS of C. jejuni, as produced in the gut during C. jejuni-induced enteritis, can disturb natural tolerance to definite proteins which may be or may mimic peripheral nerve antigens. In human patients this may be one of the potential mechanisms to explain why C. jejuni enteritis is a common trigger of GBS.