AC
Arturo Casadevall
  • Johns Hopkins University Bloomberg School of Public Health Baltimore
Cryptococcus neoformans Virulence Assay Using a Galleria mellonella Larvae Model System
Authors:  Piotr R. Stempinski, Daniel F. Q. Smith and Arturo Casadevall, date: 08/05/2022, view: 1707, Q&A: 0

Cryptococcus neoformans is a human pathogenic fungus that can cause pulmonary infections and meningitis in both immunocompromised and otherwise healthy individuals. Limited treatment options and a high mortality rate underlie the necessity for extensive research of the virulence of C. neoformans. Here we describe a detailed protocol for using the Galleria mellonella (Greater Wax Moth) larvae as a model organism for the virulence analysis of the cryptococcal infections. This protocol describes in detail the evaluation of G. mellonella larvae viability and the alternatives for troubleshooting the infection procedure. This protocol can be easily modified to study different inocula or fungal species, or the effects of a drug or antifungal agent on fungal disease within the larvae. We describe modified alternative versions of the protocol that allow using G. mellonella to study fungal diseases with different inocula and at different temperatures.

Study of Microbial Extracellular Vesicles: Separation by Density Gradients, Protection Assays and Labelling for Live Tracking
Extracellular vesicles (EVs) are produced by all domains of life including Bacteria, Archaea and Eukarya. EVs are critical for cellular physiology and contain varied cargo: virulence factors, cell wall remodeling enzymes, extracellular matrix components and even nucleic acids and metabolites. While various protocols for isolating EVs have been established for mammalian cells, the field is actively developing tools to study EVs in other organisms. In this protocol we describe our methods to perform density gradient purification of EVs in bacterial cells, allowing for separation of EV subpopulations, followed by protection assays for EV cargo characterization. Furthermore, we devised a protocol which incorporates a fluorescent conjugate of fatty acids into EVs, the first to allow live-cell EV tracking to observe release of EVs, including during infection of mammalian cells by pathogenic bacteria. These protocols are powerful tools for EV researchers as they enable the observation of EV release and the study of the mechanisms of their formation and release.
Imaging Cryptococcus spp. Capsule by Differential Interference Contrast Microscopy Using Percoll®
The most important virulence factor in the Cryptococcus genus is the polysaccharide capsule. This genus includes several species that cause life-threatening invasive disease. An increase in capsule thickness is important during fungal infection. The capsule is usually imaged using India ink, and crucial insights on the dynamics of its growth have been obtained using capsule-binding proteins such as specific antibodies or complement. We have developed an alternative method that allows both static and time-lapse imaging of the capsule using Percoll®, a suspension of nanometric spheres that do not penetrate the capsule. Given that these particles have a higher refractive index than the capsule, the latter can be imaged by differential interference contrast (DIC) microscopy. Static observation of the capsule with DIC and Percoll® results in capsule thickness measurements that match those made with India ink. Using capsule-inducing media, a glass-bottom incubation chamber and a live-imaging system equipped for DIC microscopy, this method allows time-lapse imaging of capsule growth. In contrast with India ink staining, DIC imaging of Percoll® exclusion halos result in crisp images. The greatest advantage of this method, though, is that unlike India ink, the Percoll® particles are non-toxic and unlike opsonins they do not bind the capsule, resulting in observations of capsule growth that are free from interference of bound proteins on capsule physiology.
Vesicle Isolation from Bacillus subtilis Biofilm
Authors:  Lisa Brown, Anne Kessler and Arturo Casadevall, date: 03/05/2015, view: 12521, Q&A: 2
Bacterial biofilms are associated clinically with many bacterial infections including those caused by bacteria such as Pseudomonas aeruginosa and Staphylococcus aureus. In recent years, extracellular vesicles produced by bacteria have been isolated from biofilm communities. Vesicles have been described in depth and can encapsulate various virulence factors including toxins and immunomodulatory compounds. Vesicles may be important for virulence and survival by serving as a vehicle for the secretion and concentrated delivery of these molecules. Studying extracellular vesicles is an important step towards understanding biofilm formation, structure, and disruption with the ultimate goal of preventing or treating hospital infections caused by bacterial pathogens residing in biofilms. Here we describe the protocol for isolating vesicles from biofilm produced by Bacillus subtilis.
Differentiation of Naturally Produced Extracellular Membrane Vesicles from Lipid Aggregation by Glucuronoxylomannan Immunogold Transmission Electron Microscopy in Bacillus subtilis
Authors:  Lisa Brown, Geoff Perumal and Arturo Casadevall, date: 03/05/2015, view: 10143, Q&A: 0
Recently, membrane vesicle (MV) production was described in Gram-positive bacteria, which harbor a variety of components such as toxins, antibiotic resistance proteins, proteases, DNA, and immune modulators. Free lipids have the ability to form micelles, thus it is important to rule out spontaneous association of lipids into vesicle-like structures and rather, that MVs are produced naturally by a metabolically active cell. Here, we describe a protocol utilizing the polysaccharide, glucuronoxylomannan (GXM) from Cryptococcus neoformans (C. neoformans) as a marker to differentiate naturally produced MVs from vesicles that form spontaneously in the Gram-positive model organism, Bacillus subtilis (B. subtilis). MVs are purified from bacterial cultures grown in the presence of GXM; MVs naturally produced by cells would not contain GXM in the lumen whereas vesicular structures forming in the media could encapsulate GXM and this can be visualized via immunogold transmission electron microscopy.
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