Raymond Hellio

Targeting of Listeria monocytogenes ActA protein to the plasma membrane as a tool to dissect both actin-based cell morphogenesis and ActA function.

Actin assembly on the surface of Listeria monocytogenes in the cytoplasm of infected cells provides a model to study actin‐based motility and changes in cell shape. We have shown previously that the ActA protein, exposed on the bacterial surface, is required for polarized nucleation of actin filaments. To investigate whether plasma membrane‐associated ActA can control the organization of microfilaments and cell shape, variants of ActA, in which the bacterial membrane signal had been replaced by a plasma membrane anchor sequence, were produced in mammalian cells. While both cytoplasmic and membrane‐bound forms of ActA increased the F‐actin content, only membrane‐associated ActA caused the formation of plasma membrane extensions. This finding suggests that ActA acts as an actin filament nucleator and shows that permanent association with the inner face of the plasma membrane is required for changes in cell shape. Based on the observation that the amino‐terminal segment of ActA and the remaining portion which includes the proline‐rich repeats cause distinct phenotypic modifications in transfected cells, we propose a model in which two functional domains of ActA cooperate in the nucleation and dynamic turnover of actin filaments. The present approach is a new model system to dissect the mechanism of action of ActA and to further investigate interactions of the plasma membrane and the actin cytoskeleton during dynamic changes of cell shape.

Immunology and the confocal microscope.

The techniques of classical epifluorescence microscopy are already widely used by the immunological community to detect antigens at the cellular level. Coupled with the use of specific inhibitors that affect diverse intracellular events, these techniques have provided valuable information on the mechanisms involved in antigen presentation. The same biological samples can now be examined by confocal microscopy, which has a higher resolution than conventional microscopy and allows one to analyse quantitatively single cross-sections of the sample. The confocal microscope is therefore especially well-suited for studies on intracellular membrane traffic, cell-to-cell interactions, and the distribution of particular antigens and their co-localization with other intracellular markers. This review describes the technique of confocal microscopy and the goals of sample preparation, along with several detailed protocols for fixing and permeabilizing cells and mounting them on microscope slides. Representative examples are cited from studies on the endocytosis of surface receptors, the distribution of adhesion and major histocompatibility complex (MHC) molecules, and the interaction of an intracellular parasite with MHC molecules of the host cell.

Nutritionally variant streptococci develop ultrastructural abnormalities during experimental endocarditis

Nutritionally variant streptococci (NVS) are fastidious micro-organisms responsible for most of the so-called negative blood culture endocarditis. In patients, the relative resistance of these bacteria to antibiotic treatment may be relevant to bacterial alterations in infected tissues. We used here a rabbit experimental model of endocarditis in order to examine, under scanning and transmission electron microscope, the NVS ultrastructure inside cardiac vegetations and to follow alterations at the different stages of the disease. In the early phase (day 7) of endocarditis, NVS were found dispersed inside vegetations and exhibited a typical streptococcal morphology similar to that observed during an in vitro balanced growth. In contrast, on day 11 and day 18, bacteria were found gathered as large and numerous clusters, in which they exhibited abnormal ultrasturctural features similar to those previously described during in vitro unbalanced growth. At this stage, ruthenium red staining revealed a large amount of exopolysaccharide surrounding the bacteria. None of these bacterial alterations were observed inside the vegetations of rabbits treated from day 7 to day 11 with penicillin or vancomycin. These abnormalities might be mainly related to nutrient limitation inside the clusters and could contribute to the pathogenicity of these micro-organisms.

Electron cytochemistry of mycobacteria: Evidence that strongly acidic sulfate groups are present on the surface of H37Rv (virulent) strain ofMycobacterium tuberculosis

Cytochemical characterization of mycobacterial surfaces was carried out on virulent (H37Rv) and avirulent (H37Ra) strains ofMycobacterium tuberculosis. The results were quantified and compared with those obtained with three colony types of the opportunistic pathogenMycobacterium avium. Mycobacterium aurum, a rapidly growing, nonpathogenic species, served as a model for the cytochemical methods. Concanavalin A (ConA) reacted with α-d-mannose and α-d-glucose residues, whereas negative charged residues were detected with either the ionized ferritin (CF) or the colloidal ferric hydroxide (CIH) method. Strongly acidic sulfate groups were detected by their selective blockage with alcian blue (AB) at pH 1 prior to the CIH labeling at pH 1.8. Weakly acidic groups were demonstrated by AB blockage at pH 2.5 prior to staining with CF stain. Except forM. aurum, all other strains showed a marked heterogeneity in regard to the abundance of their surface labeling. Accessible sulfate groups were present on the cell surface of the virulent H37Rv strain ofM. tuberculosis, but not on the avirulent strain H37Ra. Distribution of ConA receptors, on the other hand, was unrelated to the virulence or pathogenicity of the bacterial strain.