Author Correction: Enhanced tenacity of mycobacterial aerosols from necrotic neutrophils.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Enhanced tenacity of mycobacterial aerosols from necrotic neutrophils.

The tuberculosis agent Mycobacterium tuberculosis is primarily transmitted through air, but little is known about the tenacity of mycobacterium-containing aerosols derived from either suspensions or infected neutrophils. Analysis of mycobacterial aerosol particles generated from bacterial suspensions revealed an average aerodynamic diameter and mass density that may allow distant airborne transmission. The volume and mass of mycobacterial aerosol particles increased with elevated relative humidity. To more closely mimic aerosol formation that occurs in active TB patients, aerosols from mycobacterium-infected neutrophils were analysed. Mycobacterium-infected intact neutrophils showed a smaller particle size distribution and lower viability than free mycobacteria. In contrast, mycobacterium-infected necrotic neutrophils, predominant in M. tuberculosis infection, revealed particle sizes and viability rates similar to those found for free mycobacteria, but in addition, larger aggregates of viable mycobacteria were observed. Therefore, mycobacteria are shielded from environmental stresses in multibacillary aggregates generated from necrotic neutrophils, which allows improved tenacity but emphasizes short distance transmission between close contacts.

[Pulmonary Immune Mechanisms in Tuberculosis]. / Pulmonale Immunität bei Tuberkulose.

Tuberculosis is transmitted by inhalation of Mycobacterium tuberculosis-containing aerosols; 75 % of all patients show pulmonary manifestation. Immune responses after exposure that lead to clinical symptoms occur mainly in the respiratory tract and are only poorly understood. In most cases, cells of the innate immune system are believed to control the growth of or eradicate inhaled mycobacteria. However, this cannot be verified in vivo using standard methods. Subsequently, CD4+ and CD8+ T cell-driven adaptive immune responses are induced that attempt to control bacterial growth. The humoral defence appears to be less important. This article gives an overview of the current understanding of pulmonary immune mechanisms during exposure, latent infection, active disease and therapy of tuberculosis.