James M. Daubenspeck scite author profile

Several mycoplasma species have been shown to form biofilms that confer resistance to antimicrobials and which may affect the host immune system, thus making treatment and eradication of the pathogens difficult. The present study shows that the biofilms formed by two strains of the human pathogen Mycoplasma pneumoniae differ quantitatively and qualitatively. Compared with strain UAB PO1, strain M129 grows well but forms biofilms that are less robust, with towers that are less smooth at the margins. A polysaccharide containing Nacetylglucosamine is secreted by M129 into the culture medium but found in tight association with the cells of UAB PO1. The polysaccharide may have a role in biofilm formation, contributing to differences in virulence, chronicity and treatment outcome between strains of M. pneumoniae. The UAB PO1 genome was found to be that of a type 2 strain of M. pneumoniae, whereas M129 is type 1. Examination of other M. pneumoniae isolates suggests that the robustness of the biofilm correlates with the strain type.

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Identification of exopolysaccharide‐deficient mutants of Mycoplasma pulmonis

Daubenspeck¹,

Bolland²,

Luo

et al. 2009

Molecular Microbiology

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SummaryThe presence of capsular exopolysaccharide (EPS) in Mollicutes has been inferred from electron micrographs for over 50 years without conclusive data to support the production of complex carbohydrates by the organism. Mycoplasma pulmonis binds the lectin Griffonia simplicifolia I (GS-I), which is specific for terminal b-linked galactose residues. Mutants that failed to produce the EPS bound by GS-I were isolated from a transposon library. All of the mutants had the transposon located in open reading frame MYPU_7410 or MYPU_7420. These overlapping genes are predicted to code for a heterodimeric pair of ABC transporter permeases and may code for part of a new pathway for synthesis of EPS. Analysis by lectinaffinity chromatography in conjunction with gas chromatography demonstrated that the wild-type mycoplasma produced an EPS (EPS-I) composed of equimolar amounts of glucose and galactose that was lacking in the mutants. Phenotypic analysis revealed that the mutants had an increased propensity to form a biofilm on glass surfaces, colonized mouse lung and trachea efficiently, but had a decreased association with the A549 lung cell line. Confounding the interpretation of these results is the observation that the mutants missing EPS-I had an eightfold overproduction of an apparent second EPS (EPS-II) containing N-acetylglucosamine.

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Integrative characterization of the near‐minimal bacterium Mesoplasma florum

Matteau

Lachance

Grenier

et al. 2020

Molecular Systems Biology

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The near‐minimal bacterium Mesoplasma florum is an interesting model for synthetic genomics and systems biology due to its small genome (~ 800 kb), fast growth rate, and lack of pathogenic potential. However, fundamental aspects of its biology remain largely unexplored. Here, we report a broad yet remarkably detailed characterization of M. florum by combining a wide variety of experimental approaches. We investigated several physical and physiological parameters of this bacterium, including cell size, growth kinetics, and biomass composition of the cell. We also performed the first genome‐wide analysis of its transcriptome and proteome, notably revealing a conserved promoter motif, the organization of transcription units, and the transcription and protein expression levels of all protein‐coding sequences. We converted gene transcription and expression levels into absolute molecular abundances using biomass quantification results, generating an unprecedented view of the M. florum cellular composition and functions. These characterization efforts provide a strong experimental foundation for the development of a genome‐scale model for M. florum and will guide future genome engineering endeavors in this simple organism.

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A Stochastic Mechanism for Biofilm Formation by Mycoplasma pulmonis

Simmons¹,

Bolland

Daubenspeck

et al. 2007

J Bacteriol

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Bacterial biofilms are communities of bacteria that are enclosed in an extracellular matrix. Within a biofilm the bacteria are protected from antimicrobials, environmental stresses, and immune responses from the host. Biofilms are often believed to have a highly developed organization that is derived from differential regulation of the genes that direct the synthesis of the extracellular matrix and the attachment to surfaces. The mycoplasmas have the smallest of the prokaryotic genomes and apparently lack complex gene-regulatory systems. We examined biofilm formation by Mycoplasma pulmonis and found it to be dependent on the length of the tandem repeat region of the variable surface antigen (Vsa) protein. Mycoplasmas that produced a short Vsa protein with few tandem repeats formed biofilms that attached to polystyrene and glass. Mycoplasmas that produced a long Vsa protein with many tandem repeats formed microcolonies that floated freely in the medium. The biofilms and the microcolonies contained an extracellular matrix which contained Vsa protein, lipid, DNA, and saccharide. As variation in the number of Vsa tandem repeats occurs by slipped-strand mispairing, the ability of the mycoplasmas to form a biofilm switches stochastically.Biofilm formation can enhance the resistance of pathogens to antimicrobial agents (6) and immune surveillance (36). This has been attributed in part to the encasement within an extracellular matrix of the biofilm that isolates and protects the bacteria from the host immune response. The extracellular matrix of a biofilm is complex and usually contains lipid, protein, DNA, and exopolysaccharide (1, 2, 4, 38). Most studies have focused on the complexity of the molecular systems involved in the formation of the matrix constituents. The formation of biofilms by some bacteria is dependent on two-component and quorum-sensing systems that regulate macromolecules necessary for attachment and matrix synthesis (24). A recent trend is to describe biofilm formation in the context of a multicellular structure that develops as a result of programmed gene expression (7,21).Few studies address the formation of biofilms from the viewpoint of simplicity. The recent finding that mycoplasmas can form biofilms (19) provides us with a model in which microorganisms using minimally regulated genetic systems, or perhaps stochastically modulated genetic systems, can form biofilms. The mycoplasmas are the smallest and simplest of self-replicating cells (11,22). Although some mycoplasmas can produce complex structures such as an attachment organelle, their genomes encode only a few hundred proteins. There are no known two-component regulatory systems or other recognizable global regulators in most species of mycoplasmas, including Mycoplasma pulmonis. The lack of such regulators can be attributed to the survival of the mycoplasmas in only one environmental niche: the animal host.The variable surface antigen (Vsa) proteins of the murine respiratory pathogen M. pulmonis are associated with virulence (34) and media...

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