Mycobacterium tuberculosis Extracellular Vesicle Enrichment through Size Exclusion Chromatography.

The role of extracellular vesicles (EVs) in the context of bacterial infection has emerged as a new avenue for understanding microbial physiology. Specifically, Mycobacterium tuberculosis (Mtb) EVs play a role in the host-pathogen interaction and response to environmental stress. Mtb EVs are also highly antigenic and show potential as vaccine components. The most common method for purifying Mtb EVs is density gradient ultracentrifugation. This process has several limitations, including low throughput, low yield, reliance on expensive equipment, technical challenges, and it can negatively impact the resulting preparation. Size exclusion chromatography (SEC) is a gentler alternative method that combats many of the limitations of ultracentrifugation. This protocol demonstrates that SEC is effective for Mtb EV enrichment and produces high-quality Mtb EV preparations of increased yield in a rapid and scalable manner. Additionally, a comparison to density gradient ultracentrifugation by quantification and qualification procedures demonstrates the benefits of SEC. While the evaluation of EV quantity (nanoparticle tracking analysis), phenotype (transmission electron microscopy), and content (Western blotting) is tailored to Mtb EVs, the workflow provided can be applied to other mycobacteria.

Extracellular Vesicles in Mycobacteria and Tuberculosis.

Tuberculosis (TB) remains a public health issue causing millions of infections every year. Of these, about 15% ultimately result in death. Efforts to control TB include development of new and more effective vaccines, novel and more effective drug treatments, and new diagnostics that test for both latent TB Infection and TB disease. All of these areas of research benefit from a good understanding of the physiology of Mycobacterium tuberculosis (Mtb), the primary causative agent of TB. Mtb secreted protein antigens have been the focus of vaccine and diagnosis research for the past century. Recently, the discovery of extracellular vesicles (EVs) as an important source of secreted antigens in Mtb has gained attention. Similarly, the discovery that host EVs can carry Mtb products during in vitro and in vivo infection has spiked interest because of its potential use in blood-based diagnostics. Despite advances in understanding the content of Mtb and Mtb-infected host extracellular vesicles, our understanding on the biogenesis and role of Mtb and host extracellular vesicles during Mtb infection is still nascent. Here, we explore the current literature on extracellular vesicles regarding Mtb, discuss the host and Mtb extracellular vesicles as distinct entities, and discuss current gaps in the field.

Extraction and Separation of Mycobacterial Proteins.

The extraction and separation of native mycobacterial proteins remain necessary for antigen discovery, elucidation of enzymes to improve rational drug design, identification of physiologic mechanisms, use as reagents for diagnostics, and defining host immune responses. In this chapter, methods for the manipulation of whole mycobacterial cells and culture exudates are described in detail as these methods are the requisite first steps towards native protein isolation. Specifically, several methods for the inactivation of viable Mycobacterium tuberculosis along with qualification assays are provided, as this is key to safe manipulation of cell pastes for downstream processes. Next, the concentration of spent culture filtrate media in order to permit separation of soluble, secreted proteins is described followed by the separation of mycobacteria extracellular vesicles (MEV) from the remaining soluble proteins in spent media. We then describe the generation of whole-cell lysate and facile separation of lysate into subcellular fractions to afford cell wall, cell membrane, and cytosol-enriched proteins. Due to the hydrophobic nature of cell wall and cell membrane proteins, several extraction protocols to resolve protein subsets (such as extraction with urea and SDS) are also provided. Finally, methods for separation of hydrophobic and hydrophilic proteins from both whole-cell lysate and spent culture media are included. While these methods were optimized for the manipulation of Mycobacterium tuberculosis cells, they have been successfully applied to extract and isolate Mycobacterium leprae, Mycobacterium ulcerans, and Mycobacterium avium proteins.