Vaccination of BALB/c Mice with an Avirulent Mycoplasma pneumoniae P30 Mutant Results in Disease Exacerbation upon Challenge with a Virulent Strain

Szczepanek, Steven M.; Majumder, Sanjukta; Sheppard, Edward S.; Liao, X.; Rood, Debra; Tulman, E. R.; Wyand, S.; Krause, Duncan C.; Silbart, Lawrence K.; Geary, Steven J.

doi:10.1128/iai.06078-11

Cited by 31 publications

(28 citation statements)

References 44 publications

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“…Mycoplasma access to the basolateral compartment may also have been facilitated by epithelial remodelling and the coordinated formation of epithelial furrows, based on the high mycoplasma density commonly observed in these regions. Both mechanisms likely require mycoplasma gliding motility, which is supported by in vivo animal studies (Hara et al, 1974;Hardy et al, 2002;Szczepanek et al, 2012). Regardless of the route, migration to the basal lamina might provide a favourable site for nutrient acquisition and immune evasion and potentiate spread to extrapulmonary sites, as occurs in a significant number of cases (Waites & Talkington, 2004).…”

Section: Epithelial Remodelling During Mycoplasma Pneumoniae Infectionmentioning

confidence: 95%

Modelling persistentMycoplasma pneumoniaeinfection of human airway epithelium

Prince

Krunkosky

Sheppard

et al. 2017

Cellular Microbiology

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Mycoplasma pneumoniae is a human respiratory tract pathogen causing acute and chronic airway disease states that can include long-term carriage and extrapulmonary spread. The mechanisms of persistence and migration beyond the conducting airways, however, remain poorly understood. We previously described an acute exposure model using normal human bronchial epithelium (NHBE) in air-liquid interface culture, showing that M. pneumoniae gliding motility is essential for initial colonisation and subsequent spread, including localisation to epithelial cell junctions. We extended those observations here, characterizing M. pneumoniae infection of NHBE for up to 4 weeks. Colonisation of the apical surface was followed by pericellular invasion of the basolateral compartment and migration across the underlying transwell membrane. Despite fluctuations in transepithelial electrical resistance and increased NHBE cell desquamation, barrier function remained largely intact. Desquamation was accompanied by epithelial remodelling that included cytoskeletal reorganisation and development of deep furrows in the epithelium. Finally, M. pneumoniae strains S1 and M129 differed with respect to invasion and histopathology, consistent with contrasting virulence in experimentally infected mice. In summary, this study reports pericellular invasion, NHBE cytoskeletal reorganisation, and tissue remodelling with persistent infection in a human airway epithelium model, providing clear insight into the likely route for extrapulmonary spread.

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Section: Epithelial Remodelling During Mycoplasma Pneumoniae Infectionmentioning

confidence: 95%

Modelling persistentMycoplasma pneumoniaeinfection of human airway epithelium

Prince

Krunkosky

Sheppard

et al. 2017

Cellular Microbiology

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“…Azithromycin and other macrolides are used for the treatment of infections caused by M. pneumoniae [4], but an increase in the frequency of reports of macrolide resistance, particularly in Europe, Asia and North America, is of major concern [5,6,7,8,9,10,11,12,13,14,15,16,17,18,19]. Efficacious vaccines for the prevention of infections caused by M. pneumoniae are yet to be developed and are complicated by the presence of antigens that are capable of evoking an autoimmune response [20]. While the infiltration of neutrophils and lymphocytes is a characteristic immunological hallmark of infections caused by M. pneumoniae , the severity of the response varies widely.…”

Section: Introductionmentioning

confidence: 99%

“…While the infiltration of neutrophils and lymphocytes is a characteristic immunological hallmark of infections caused by M. pneumoniae , the severity of the response varies widely. In severe cases, the immune response is known to generate immunopathological sequelae, complicating vaccine design [2,20]. …”

Section: Introductionmentioning

confidence: 99%

P40 and P90 from Mpn142 are Targets of Multiple Processing Events on the Surface of Mycoplasma pneumoniae

et al. 2015

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Mycoplasma pneumoniae is a significant cause of community acquired pneumonia globally. Despite having a genome less than 1 Mb in size, M. pneumoniae presents a structurally sophisticated attachment organelle that (i) provides cell polarity, (ii) directs adherence to receptors presented on respiratory epithelium, and (iii) plays a major role in cell motility. The major adhesins, P1 (Mpn141) and P30 (Mpn453), are localised to the tip of the attachment organelle by the surface accessible cleavage fragments P90 and P40 derived from Mpn142. Two events play a defining role in the formation of P90 and P40; removal of a leader peptide at position 26 (23SLA↓NTY28) during secretion to the cell surface and cleavage at amino acid 455 (452GPL↓RAG457) generating P40 and P90. Liquid Chromatography Tandem Mass Spectrometry (LC-MS/MS) analysis of tryptic peptides generated by digesting size-fractionated cell lysates of M. pneumoniae identified 15 cleavage fragments of Mpn142 ranging in mass from 9–84 kDa. Further evidence for the existence of cleavage fragments of Mpn142 was generated by mapping tryptic peptides to proteins recovered from size fractionated eluents from affinity columns loaded with heparin, fibronectin, fetuin, actin, plasminogen and A549 surface proteins as bait. To define the sites of cleavage in Mpn142, neo-N-termini in cell lysates of M. pneumoniae were dimethyl-labelled and characterised by LC-MS/MS. Our data suggests that Mpn142 is cleaved to generate adhesins that are auxiliary to P1 and P30.

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“…Mycoplasma-host interactions in vivo typically begin at mucosal barriers (11-13), which we define here as including ciliary motion, mucus production, and tight-junction formation (11, 18). Gliding motility is required for lung colonization in experimentally infected hamsters and mice (19,20), and we speculate that this requirement begins with the need to cross the gel layer mucus and gain access to ciliated airway cells.We previously described the use of normal human bronchial epithelial (NHBE) cells in air-liquid interface (ALI) culture to model M. pneumoniae interactions with the human airway (21) and noted then that impaired gliding motility was correlated with reduced colonization (22). Here, we extend that analysis further in three important ways.…”

mentioning

confidence: 99%

mentioning

confidence: 99%

In Vitro Spatial and Temporal Analysis of Mycoplasma pneumoniae Colonization of Human Airway Epithelium

2014

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Mycoplasma pneumoniae is an important cause of respiratory disease, especially in school-age children and young adults. We employed normal human bronchial epithelial (NHBE) cells in air-liquid interface culture to study the interaction of M. pneumoniae with differentiated airway epithelium. These airway cells, when grown in air-liquid interface culture, polarize, form tight junctions, produce mucus, and develop ciliary function. We examined both qualitatively and quantitatively the role of mycoplasma gliding motility in the colonization pattern of developing airway cells, comparing wild-type M. pneumoniae and mutants thereof with moderate to severe defects in gliding motility. Adherence assays with radiolabeled mycoplasmas demonstrated a dramatic reduction in binding for all strains with airway cell polarization, independent of acquisition of mucociliary function. Adherence levels dropped further once NHBE cells achieved terminal differentiation, with mucociliary activity strongly selecting for full gliding competence. Analysis over time by confocal microscopy demonstrated a distinct colonization pattern that appeared to originate primarily with ciliated cells, but lateral spread from the base of the cilia was slower than expected. The data support a model in which the mucociliary apparatus impairs colonization yet cilia provide a conduit for mycoplasma access to the host cell surface and suggest acquisition of a barrier function, perhaps associated with tethered mucin levels, with NHBE cell polarization.M ycoplasma pneumoniae is a human respiratory tract pathogen primarily associated with tracheobronchitis and pneumonia. Infections are typically not life threatening but can be life altering due to the long-term lung damage that can result, including asthma and chronic obstructive pulmonary disease (1). M. pneumoniae initiates colonization of the airway mucosal epithelium via its terminal organelle (2-4). This highly differentiated polar structure functions in adhesion to host cell receptors, gliding motility, and cell division (5-8). Adhesin proteins P1 and P30 localize to the terminal organelle surface, where they participate directly in adherence to host cells and gliding motility (5, 6, 9, 10).Colonization of the human airways requires circumvention of mucociliary defenses, which effectively obstruct, capture, and remove inhaled substances, limiting access to the epithelium (11-13). Previous M. pneumoniae colonization models employed submerged organ and tissue culture systems and have contributed to our current understanding of pathogen-host cell interactions, but they are limited in their ability to accurately reflect the environment of the airway mucosa (3, 4, 14-17). Mycoplasma-host interactions in vivo typically begin at mucosal barriers (11-13), which we define here as including ciliary motion, mucus production, and tight-junction formation (11, 18). Gliding motility is required for lung colonization in experimentally infected hamsters and mice (19,20), and we speculate that this requirement begins with...

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Vaccination of BALB/c Mice with an Avirulent Mycoplasma pneumoniae P30 Mutant Results in Disease Exacerbation upon Challenge with a Virulent Strain

Cited by 31 publications

References 44 publications

Modelling persistentMycoplasma pneumoniaeinfection of human airway epithelium

Modelling persistentMycoplasma pneumoniaeinfection of human airway epithelium

P40 and P90 from Mpn142 are Targets of Multiple Processing Events on the Surface of Mycoplasma pneumoniae

In Vitro Spatial and Temporal Analysis of Mycoplasma pneumoniae Colonization of Human Airway Epithelium

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