Otitis media (OM) is among the leading diseases of childhood and is caused by opportunists that reside within the nasopharynx, such as Haemophilus influenzae and Moraxella catarrhalis. As with most airway infections, it is now clear that OM infections involve multiple organisms. This study addresses the hypothesis that polymicrobial infection alters the course, severity, and/or treatability of OM disease. The results clearly show that coinfection with H. influenzae and M. catarrhalis promotes the increased resistance of biofilms to antibiotics and host clearance. Using H. influenzae mutants with known biofilm defects, these phenotypes were shown to relate to biofilm maturation and autoinducer-2 (AI-2) quorum signaling. In support of the latter mechanism, chemically synthesized AI-2 (dihydroxypentanedione [DPD]) promoted increased M. catarrhalis biofilm formation and resistance to antibiotics. In the chinchilla infection model of OM, polymicrobial infection promoted M. catarrhalis persistence beyond the levels seen in animals infected with M. catarrhalis alone. Notably, no such enhancement of M. catarrhalis persistence was observed in animals infected with M. catarrhalis and a quorum signaling-deficient H. influenzae luxS mutant strain. We thus conclude that H. influenzae promotes M. catarrhalis persistence within polymicrobial biofilms via interspecies quorum signaling. AI-2 may therefore represent an ideal target for disruption of chronic polymicrobial infections. Moreover, these results strongly imply that successful vaccination against the unencapsulated H. influenzae strains that cause airway infections may also significantly impact chronic M. catarrhalis disease by removing a reservoir of the AI-2 signal that promotes M. catarrhalis persistence within biofilm.
Nontypeable Haemophilus influenzae (NTHi) is a leading cause of acute and chronic otitis media, which are a major public health problem worldwide. The persistence of NTHi during chronic and recurrent otitis media infections involves multicellular biofilm communities formed within the middle-ear chamber. Bacterial biofilms resist immune clearance and antibiotic therapy due in part to encasement within a polymeric matrix. In this study, the contribution of biofilms to bacterial persistence in vivo and composition of the NTHi biofilm matrix during experimental otitis media were investigated. The presence of biofilms within the chinchilla middle-ear chamber was significantly correlated with increased bacterial load in middle-ear effusions and tissue. Examination of thin sections revealed polymorphonuclear cells within a DNA lattice containing elastase and histones, which is consistent with the definition of neutrophil extracellular traps. Viable multicellular biofilm communities with biofilm phenotypes were found within the DNA lattice throughout the biofilm. Further, NTHi was resistant to both phagocytic and extracellular neutrophil killing in vitro by means of lipooligosaccharide moieties that promote biofilm formation. These data support the conclusion that NTHi subverts neutrophil extracellular traps to persist in vivo. These data also indicate that a more inclusive definition for biofilms may be warranted.
Nontypeable Haemophilus influenzae (NTHI) causes chronic infections that feature the formation of biofilm communities. NTHI variants within biofilms have on their surfaces lipooligosaccharides containing sialic acid (NeuAc) and phosphorylcholine (PCho). Our work showed that NeuAc promotes biofilm formation, but we observed no defect in the initial stages of biofilm formation for mutants lacking PCho. In this study, we asked if alterations in NTHI PCho content affect later stages of biofilm maturation. Biofilm communities were compared for NTHI 2019 and isogenic mutants that either lacked PCho (NTHI 2019 licD) or were constitutively locked in the PCho-positive phase (NTHI 2019 lic ON ). Transformants expressing green fluorescent protein were cultured in continuous-flow biofilms and analyzed by confocal laser scanning microscopy. COMSTAT was used to quantify different biofilm parameters. PCho expression correlated significantly with increased biofilm thickness, surface coverage, and total biomass, as well as with a decrease in biofilm roughness. Comparable results were obtained by scanning electron microscopy. Analysis of thin sections of biofilms by transmission electron microscopy revealed shedding of outer membrane vesicles by NTHI bacteria within biofilms and staining of matrix material with ruthenium red in biofilms formed by NTHI 2019 lic ON . The biofilms of all three strains were comparable in viability, the presence of extracellular DNA, and the presence of sialylated moieties on or between bacteria. In vivo infection studies using the chinchilla model of otitis media showed a direct correlation between PCho expression and biofilm formation within the middle-ear chamber and an inverse relationship between PCho and persistence in the planktonic phase in middle-ear effusions. Collectively, these data show that PCho correlates with, and may promote, the maturation of NTHI biofilms. Further, this structure may be disadvantageous in the planktonic phase.Nontypeable Haemophilus influenzae (NTHI) is a commensal of the human upper airways that can cause localized opportunistic airway infections when mucociliary defenses are compromised (24). NTHI is a leading cause of otitis media with effusion (2), acute otitis media (1), chronic sinusitis (20), and pulmonary infections associated with chronic obstructive pulmonary disease (31). For many of these infections, NTHI bacteria persist within dense biofilm communities that are thought to provide resistance to host clearance (12,25,29). NTHI biofilms contain variants expressing lipooligosaccharides (LOS) that contain phosphorylcholine (PCho) and sialic acid (NeuAc) (10,19,36,41). Mutants lacking these structures are unable to establish persistent biofilms in vivo (14,19,36). The addition of PCho to LOS occurs in a phase-variable manner, and thus, NTHI populations contain discrete subpopulations of PCho-positive (PCho ϩ ) and PCho-negative (PCho Ϫ ) variants (40). PCho contributes to NTHI colonization and persistence by promoting bacterial adherence to host cells (9,32,...
Otitis media is an extremely common pediatric ailment caused by opportunists that reside within the nasopharynx. Inflammation within the upper airway can promote ascension of these opportunists into the middle ear chamber. Otitis media can be chronic/recurrent in nature, and a wealth of data indicates that in these cases the bacteria persist within biofilms. Epidemiological data demonstrates most cases of otitis media are polymicrobial, which may have significant impact on antibiotic resistance. In this study, we used in vitro biofilm assays and rodent infection models to examine the impact of polymicrobial infection with Moraxella catarrhalis and Streptococcus pneumoniae (pneumococcus) on biofilm resistance to antibiotic treatment and persistence in vivo. Consistent with prior work, M. catarrhalis conferred beta-lactamase dependent passive protection from beta-lactam killing to pneumococci within polymicrobial biofilms. Moreover, pneumococci increased resistance of M. catarrhalis to macrolide killing in polymicrobial biofilms. However, pneumococci increased colonization in vivo by M. catarrhalis in a quorum signal-dependent manner. We also found that co-infection with M. catarrhalis affects middle ear ascension of pneumococci in both mice and chinchillas. Therefore, we conclude that residence of M. catarrhalis and pneumococci within the same biofilm community significantly impacts resistance to antibiotic treatment and bacterial persistence in vivo.
Nontypeable Haemophilus influenzae (NTHI) is a leading cause of otitis media infections, which are often chronic and/or recurrent in nature. NTHI and other bacterial species persist in vivo within biofilms during otitis media and other persistent infections. These biofilms have a significant host component that includes neutrophil extracellular traps (NETs). These NETs do not mediate clearance of NTHI, which survives within NET structures by means of specific subpopulations of lipooligosaccharides on the bacterial surface that are determinants of biofilm formation in vitro. In this study, the ability of NTHI and NTHI components to initiate NET formation was examined using an in vitro model system. Both viable and nonviable NTHI strains were shown to promote NET formation, as did preparations of bacterial DNA, outer membrane proteins, and lipooligosaccharide (endotoxin). However, only endotoxin from a parental strain of NTHI exhibited equivalent potency in NET formation to that of NTHI. Additional studies showed that NTHI entrapped within NET structures is resistant to both extracellular killing within NETs and phagocytic killing by incoming neutrophils, due to oligosaccharide moieties within the lipooligosaccharides. Thus, we concluded that NTHI elicits NET formation by means of multiple pathogen-associated molecular patterns (most notably endotoxin) and is highly resistant to killing within NET structures. These data support the conclusion that, for NTHI, formation of NET structures may be a persistence determinant by providing a niche within the middle-ear chamber.Nontypeable Haemophilus influenzae (NTHI) is a common commensal of the human nasopharynx, in which setting carriage is usually asymptomatic and without adverse effect. When host mucociliary clearance is impaired, NTHI can cause localized opportunistic infections within the airway (14). For example, NTHI is a leading cause of otitis media (OM), which is among the most common and costly pediatric infections and can be a persistent and/or recurrent infection (30). Persistent populations of NTHI in vivo during chronic and recurrent otitis media are found within biofilm communities within the middle-ear chamber (19,40). Other factors that provide an environment for NTHI to cause infections include age, genetic predisposition, atopy, and immune system impairment (44), as well as Eustachian tube dysfunction and pressure dysregulation caused by virus-induced congestion (11,12,33). Biofilms have long been thought to promote microbial resistance to pharmaceutical or immune clearance during persistent infections (17,20). Bacterial factors important to NTHI biofilms include specific subsets of lipooligosaccharides (LOS) containing sialic acid and/or phosphorylcholine (23, 24, 45), pili (28), and double-stranded DNA (25,27). Our recent work demonstrated that NTHI biofilms also have a significant host component, including a double-stranded DNA lattice decorated with histones and elastase, that fits the defining traits of a neutrophil extracellular trap (NET) (22)....
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