Identification and complementation of frameshift mutations associated with loss of cytadherence in Mycoplasma pneumoniae.

Mycoplasma pneumoniae cytadherence is mediated by a specialized, polar attachment organelle. Certain spontaneously arising cytadherence mutants (designated class I) lack HMW2, fail to localize the adhesin protein P1 to the attachment organelle, and exhibit accelerated turnover of proteins HMW1, HMW3, and P65. Insertional inactivation of hmw2 by Tn4001 results in a phenotype nearly identical to that of the class I mutants, suggesting that the latter may result from a defect in hmw2. In this study, the recombinant wild-type hmw2 allele successfully complemented a class I mutant when introduced by transposon delivery. Synthesis of recombinant HMW2 at wild-type levels resulted in reacquisition of hemadsorption and normal levels of HMW1, HMW3, and P65. Low-level production of HMW2 in some transformants resulted in only an intermediate capacity to hemadsorb. Furthermore, full restoration of HMW1 and P65, but not that of HMW3, was directly proportional to the amount of recombinant HMW2 produced, reflecting the importance of proper stoichiometry for certain cytadherence-associated proteins. The recombinant class I hmw2 allele did not restore cytadherence, consistent with a defect in hmw2 in this mutant. A frameshift was discovered in different oligoadenine tracts in hmw2 from two independent class I mutants. Finally, protein P28 is thought to be the product of internal translation initiation in hmw2. A transposon excision-deletion mutant produced a truncated HMW2 but no P28, consistent with this conclusion. However, this deletion mutant was hemadsorption positive, indicating that P28 may not be required for cytadherence.     

Expression in Mycoplasma pneumoniae of the recombinant gene encoding the cytadherence-associated protein HMW1 and identification of HMW4 as a product

Mycoplasma pneumoniae is a major cause of tracheobronchitis and pneumonia in older children and young adults. The lack of adequate tools for genetic analysis has hindered the elucidation of function and regulation of mycoplasma virulence determinants. We describe here the use of a transposon vector to deliver the cloned gene for the cytadherence-associated protein HMW1 in M. pneumoniae . A 4.95 kbp Bam HI fragment encoding all but the C-terminal end of HMW1 was cloned into a modified Tn 4001 and transformed into wild-type M. pneumoniae and into a non-cytadhering mutant lacking HMW1–HMW5. Southern blot hybridizations confirmed insertion of the transposon and the presence of both the resident and recombinant hmw1 alleles. Analysis by Western immunoblotting revealed a truncated HMW1 (HMW1') in the transformants, the level of HMW1' being dependent upon the orientation of the hmw1 gene in the transposon and the site of insertion. Similar expression patterns were noted in wild-type and mutant backgrounds. However, expression of wild-type levels of HMW1' in the mutant did not restore adherence. Finally, HMW4 and HMW1 were shown to be products of the same gene, HMW4 being a heat-modified derivative of HMW1.     

Construction and use of derivatives of transposon Tn4001 that function in Mycoplasma pulmonis and Mycoplasma arthritidis

Previous attempts to introduce transposon Tn4001 into Mycoplasma pulmonis and Mycoplasma arthritidis have not been successful, possibly due to functional failure of the transposon's gentamicin resistance determinant. Tn4001C and Tn4001T were constructed, respectively, by insertion of a chloramphenicol acetyltransferase gene and the tetM tetracycline resistance determinant into Tn4001. Both Tn4001C and Tn4001T transposed in M. pulmonis, and Tn4001T transposed in M. arthritidis. The incorporation of a Tn4001T derivative that contained lacZ into either Mycoplasma species resulted in transformants with readily detectable LacZ activity. Tn4001T may be of general utility for use as a mycoplasma cloning vehicle because tetM functions in all species of Mycoplasma examined thus far.     

Construction and analysis of a modified Tn4001 conferring chloramphenicol resistance in Mycoplasma pneumoniae

The Staphylococcus aureus transposon Tn4001 and derivatives thereof have been transformed successfully in several mycoplasma species. In order to expand the versatility of Tn4001 for other genetic manipulations and for use in mycoplasma species resistant to gentamicin (Gm), chloramphenicol acetyltransferase (Cat) from S. aureus was evaluated as a selectable marker. The cat gene was cloned in both orientations into a modified Tn4001 and transformed into Mycoplasma pneumoniae, conferring resistance to Cm and Gm. Replacement of the gene for GmR in Tn4001 with cat likewise conferred CmR when transformed into M. pneumoniae. The minimum inhibitory concentration to Cm in transformants with cat derivatives of Tn4001 was 300-500 microg/ml, and Cat enzyme activity was demonstrated by using a fluorescent substrate.     

Large-scale transposon mutagenesis of Mycoplasma pulmonis

To obtain mutants for the study of the basic biology and pathogenic mechanisms of mycoplasmas, the insertion site of transposon Tn 4001T was determined for 1700 members of a library of Mycoplasma pulmonis mutants. After evaluating several criteria for gene disruption, we concluded that 321 of the 782 protein coding regions were inactivated. The dispensable and essential genes of M. pulmonis were compared with those reported for Mycoplasma genitalium and Bacillus subtilis . Perhaps the most surprising result of the current study was that unlike other bacteria, ribosomal proteins S18 and L28 were dispensable. Carbohydrate transport and the susceptibility of selected mutants to UV irradiation were examined to assess whether active transposition of Tn 4001T within the genome would confound phenotypic analysis. In contrast to earlier reports suggesting that mycoplasmas were limited in their DNA repair machinery, mutations in recA , uvrA , uvrB and uvrC resulted in a DNA-repair deficient phenotype. A mutant with a defect in transport of N -acetylglucosamine was identified.     

Physical map of Mycoplasma gallisepticum.

Physical chromosomal maps of two Mycoplasma gallisepticum strains, R and ATCC 19610, were constructed by using field inversion gel electrophoresis. To assist in the ordering of chromosomal fragments and the construction of the chromosomal maps, the gram-positive transposon Tn4001 was modified to serve as a mobile restriction site. The total sizes of the M. gallisepticum R and ATCC 19610 genomes were estimated to be 1,037 and 998 kb, respectively. The restriction enzyme locations for EagI and SmaI were determined along with several transposon insertion sites. The two strain maps were similar except for three small deletions and one additional EagI site in strain ATCC 19610.     

HMW1 Is Required for Cytadhesin P1 Trafficking to the Attachment Organelle in Mycoplasma pneumoniae

Mycoplasma pneumoniae proteins HMW1-HMW3 collectively are essential for cytadherence, but the function or requirement for each has not been defined. Cytadherence mutant M6 lacks HMW1 because of a frameshift in hmw1 and produces a truncated adherence-associated protein P30 because of a deletion at the 3′ end of p30. Genetic manipulation of this mutant was used to evaluate the role of HMW1 in cytadherence. Mutant M6 was transformed with a recombinant transposon containing a wild-type p30 allele. Transformants synthesized both truncated and full-length P30, from the resident and recombinant alleles, respectively. However, these transformants remained hemadsorption negative, suggesting that HMW1 is required for cytadherence. Wild-type M. pneumoniae cells are generally elongated, tapering to form the attachment organelle at one end of the cell. The cytadhesin protein P1 is normally densely clustered on the mycoplasma surface at this differentiated terminal structure. However, both mutant M6 and M6 transformed with recombinant p30 had a striking ovoid morphology with no tapering at the tip structure, making the attachment organelle indistinguishable. Furthermore, protein P1 was randomly distributed on the mycoplasma surface rather than clustered at a polar location. In contrast, mutant M6 transformed with a recombinant transposon expressing the wild-type hmw1 allele exhibited a near-normal morphology and localized P1 to the attachment organelle. Significantly, M6 transformed with an hmw1 gene truncated slightly at the 3′ end failed to restore proper morphology or P1 localization to the attachment organelle, suggesting a functional importance to the C-terminal domain of HMW1.     

Molecular characterization of the P1-like adhesin gene from Mycoplasma pirum.

A DNA fragment has been isolated from the genome of Mycoplasma pirum by use of a genetic probe derived from the conserved region within the genes for the major adhesins of Mycoplasma genitalium and Mycoplasma pneumoniae. A gene encoding an adhesin-like polypeptide was localized, and sequence analysis indicated a G + C content of only 28%, with A- and T-rich codons being preferentially used. A total of 91% of positions 3 were either A or T. The deduced polypeptide is 1,144 amino acids long (126 kDa) and shows 26% identity with the adhesins of M. genitalium and M. pneumoniae. Other features in common with these two membrane proteins include a similar hydropathic profile and a proline-rich C terminus. Antibodies were prepared by using as an immunogen a peptide derived from the C terminus of the M. pirum adhesin-like polypeptide and were found to recognize on immunoblots a 126-kDa polypeptide from an M. pirum cellular extract. The characterization of the adhesin-like gene is a first step toward a better understanding of the mechanisms allowing this human mycoplasma to attach to host cells.     

Random insertion of the gentamicin resistance transposon Tn4001 in Mycoplasma pulmonis

The staphylococcal transposon Tn4001 was introduced into Mycoplasma pulmonis using an Escherichia coli-derived vector by polyethylene glycol-mediated transformation. Using a reaction mixture containing 10 micrograms plasmid DNA, 10 micrograms yeast tRNA, and 34-35% polyethylene glycol per 1 x 10(8) cells, Tn4001 could be introduced into M. pulmonis at a frequency of 5 x 10(-5) per colony forming unit. DNA-DNA hybridization studies illustrated that Tn4001 could occupy a diversity of insertion sites in the M. pulmonis chromosome. These data indicated that Tn4001 is a potentially useful tool for the introduction of mutations and for genetic studies in M. pulmonis.     

Deletion analysis identifies key functional domains of the cytadherence-associated protein HMW2 of Mycoplasma pneumoniae

Mycoplasma pneumoniae attachment to host cells requires biogenesis of a functional attachment organelle, including proper localization of the adhesion protein P1 to this structure. Mutations in the hmw2 gene result in the inability to cytadhere, failure to localize P1 to the attachment organelle, altered cell morphology and accelerated turnover of the cytadherence-associated proteins HMW1, HMW3 and P65. The hmw2 gene encodes HMW2 (190 kDa) and P28 (28 kDa), the latter apparently the product of internal translation initiation near the 3' end of the hmw2 coding region. Transformation of hmw2 mutant I-2 with recombinant wild-type hmw2 restores a wild-type phenotype. In the current study, a severely truncated hmw2 gene with an in frame internal deletion of 80% of the HMW2 coding region that leaves the P28-encoding region intact restored cytadherence to mutant I-2. Transformants produced the expected 38 kDa HMW2 derivative (HMW2Deltamid) at levels comparable to that of HMW2 in wild-type cells; like HMW2, HMW2Deltamid exhibited marked Triton X-100 insolubility. HMW3, P65 and P28 were fully restored, but not HMW1. These transformants were morphologically similar to wild-type M. pneumoniae but failed to localize P1 to the attachment organelle. Finally, a C-terminally truncated HMW2 derivative was partly Triton X-100 soluble and incapable of restoring HMW1, HMW3 and P65 to wild-type levels. These data are consistent with a model in which the C-terminal domain of HMW2 imparts normal localization to the protein, and this localization itself is required for productive interactions with downstream cytadherence-associated proteins. Furthermore, these results emphasize the association of HMW1 with P1 clustering.     

Transposon mutagenesis identifies genes associated with Mycoplasma pneumoniae gliding motility

The wall-less prokaryote Mycoplasma pneumoniae, a common cause of chronic respiratory tract infections in humans, is considered to be among the smallest and simplest known cells capable of self-replication, yet it has a complex architecture with a novel cytoskeleton and a differentiated terminal organelle that function in adherence, cell division, and gliding motility. Recent findings have begun to elucidate the hierarchy of protein interactions required for terminal organelle assembly, but the engineering of its gliding machinery is largely unknown. In the current study, we assessed gliding in cytadherence mutants lacking terminal organelle proteins B, C, P1, and HMW1. Furthermore, we screened over 3,500 M. pneumoniae transposon mutants individually to identify genes associated with gliding but dispensable for cytadherence. Forty-seven transformants having motility defects were characterized further, with transposon insertions mapping to 32 different open reading frames widely distributed throughout the M. pneumoniae genome; 30 of these were dispensable for cytadherence. We confirmed the clonality of selected transformants by Southern blot hybridization and PCR analysis and characterized satellite growth and gliding by microcinematography. For some mutants, satellite growth was absent or developed more slowly than that of the wild type. Others produced lawn-like growth largely devoid of typical microcolonies, while still others had a dull, asymmetrical leading edge or a filamentous appearance of colony spreading. All mutants exhibited substantially reduced gliding velocities and/or frequencies. These findings significantly expand our understanding of the complexity of M. pneumoniae gliding and the identity of possible elements of the gliding machinery, providing a foundation for a detailed analysis of the engineering and regulation of motility in this unusual prokaryote.     

Construction of mini-Tn4001tet and its use in Mycoplasma gallisepticum

The Mollicutes are a group of cell-wall-less bacteria and are important plant and animal pathogens. Progress toward analyzing their pathogenic mechanisms has been hampered by the few available genetic tools. Of the two transposons shown to function in mycoplasmas, only Tn4001 is readily amenable to modification and development. One disadvantage of using Tn4001 in mycoplasmas has been independent insertion of the insertion sequence, IS256, probably as a result of inadequate control of the transposase expression in mycoplasmas. In this study, we describe the construction of a mini-Tn4001 containing the tetM antibiotic resistance gene from Tn916. The transposase gene was placed outside the inverted repeats to lower the frequency of independent transposition events. Transposition of mini-Tn4001tet in Mycoplasma gallisepticum occurred at a frequency of 1-8 x 10(-6), a frequency similar to that of the parent transposon. Insertions of mini-Tn4001tet were random and only single insertions were observed. Several unique restriction sites between the inverted repeat sequences provide for further development of mini-Tn4001.     

Juxtaposition of the genes encoding Mycoplasma pneumoniae cytadherence-accessory proteins HMW1 and HMW3.

The loss and reacquisition of high-Mr (HMW) proteins, HMW1, 2, 3, 4 and 5, by Mycoplasma pneumoniae correlates with cytadherence phase variation. We are cloning and characterizing the genes encoding HMW1-5 to understand the mechanism regulating their coordinate expression. HMW1 was purified by polyacrylamide-gel electrophoresis. Amino acid (aa) sequence data were obtained from enzymatically generated peptide fragments from HMW1. A degenerate 17-mer probe synthesized based upon the aa sequence of one peptide clearly identified a single 4.75-kb BamHI fragment of M. pneumoniae DNA under stringent hybridization conditions. This fragment was cloned into pUC19 to generate pKV16. Restriction mapping of the 4.75-kb BamHI fragment in pKV16 revealed a possible overlap with the 9.4-kb EcoRI fragment containing the gene encoding protein HMW3. Southern blotting and reciprocal hybridization studies confirmed this overlap, establishing the juxtaposition of the genes encoding HMW1 and HMW3. Finally, physical mapping analysis by probing restriction fragments of M. pneumoniae DNA resolved by pulsed-field gel electrophoresis with the cloned genes encoding HMW1 and HMW3 revealed definitively that the hmw locus maps to a 106.8-kb ApaI fragment, rather than a 117.5-kb ApaI fragment, as had been reported previously for hmw3 [Krause and Mawn, J. Bacteriol. 172 (1990) 4790-4797].     

Peptide Methionine Sulfoxide Reductase (MsrA) Is a Virulence Determinant in Mycoplasma genitalium

Mycoplasma genitalium is the smallest self-replicating microorganism and is implicated in human diseases, including urogenital and respiratory infections and arthritides. M. genitalium colonizes host cells primarily through adherence mechanisms mediated by a network of surface-associated membrane proteins, including adhesins and cytadherence-related proteins. In this paper, we show that cytadherence in M. genitalium is affected by an unrelated protein known as peptide methionine sulfoxide reductase (MsrA), an antioxidant repair enzyme that catalyzes the reduction of methionine sulfoxide [Met(O)] residues in proteins to methionine. An msrA disruption mutant of M. genitalium, constructed through homologous recombination, displayed markedly reduced adherence to sheep erythrocytes. In addition, the msrA mutant was incapable of growing in hamsters and exhibited hypersensitivity to hydrogen peroxide when compared to wild-type virulent M. genitalium. These results indicate that MsrA plays an important role in M. genitalium pathogenicity, possibly by protecting mycoplasma protein structures from oxidative damage or through alternate virulence-related pathways.     

Construction of mini-Tn4001 transposon vector for Mycoplasma gallisepticum

The detailed genetic analysis of mycoplasmas has long been hampered by the lack of appropriate tools for genetic manipulation. In this study, the transposon vector, mini-Tn4001tetM, was constructed containing the tnp gene, encoding a transposase gene in Staphylococcus aureus, two copies of the IS256 inverted repeat sequence (inner and outer) and the tetM gene, from the Enterococcus faecalis Tn916 transposon, conferring resistance to tetracycline. This vector was electro-transformed into Mycoplasma gallisepticum (MG). The recombinant cells were screened by tetracycline selection. The results indicated that the transposon vector could replicate in MG strain R by successive passages, indicating that MG is a potential vector for expressing protective antigens of other pathogens.     

Location of sites of transposon Tn916 insertion in the Mycoplasma mycoides genome.

The genome of Mycoplasma mycoides subsp. mycoides GC1176-2 was cleaved into six large fragments by the endonuclease KpnI which also cleaved the transposon Tn916 once. This has allowed genomic mapping of insertion sites for 50 transformants of GC1176-2 containing Tn916. Almost all of the mapped sites were clearly separate. The transformants provide a bank of genomes each with a KpnI site at a different position to facilitate mapping of gene loci.     

Identification of a small RNA within the pdh gene cluster of Mycoplasma pneumoniae and Mycoplasma genitalium

A highly abundant and heterogeneous small RNA about 205 to 210 bases long named MP200 RNA has been identified in Mycoplasma pneumoniae. It was localized on the genome within a 319-bp-long intergenic space of the pyruvate dehydrogenase (pdh) gene cluster. A database search at the DNA level revealed the highest similarity to a sequence located within the pdh gene cluster of Mycoplasma genitalium that was also shown to be transcribed into two abundant, but smaller RNAs than the ones in Mycoplasma pneumoniae. The RNAs from both M. pneumoniae and M. genitalium have the potential to code for cysteine-rich 29- and 23-amino-acid-long peptides, but so far, these peptides have not been identified experimentally in bacterial protein extracts.