Gabriella Gambellini

Streptococcus pyogenes pili promote pharyngeal cell adhesion and biofilm formation

Group A Streptococcus (GAS, Streptococcus pyogenes) is a Gram‐positive human pathogen responsible for several acute diseases and autoimmune sequelae that account for half a million deaths worldwide every year. GAS infections require the capacity of the pathogen to adhere to host tissues and assemble in cell aggregates. Furthermore, a role for biofilms in GAS pathogenesis has recently been proposed. Here we investigated the role of GAS pili in biofilm formation. We demonstrated that GAS pilus‐negative mutants, in which the genes encoding either the pilus backbone structural protein or the sortase C1 have been deleted, showed an impaired capacity to attach to a pharyngeal cell line. The same mutants were much less efficient in forming cellular aggregates in liquid culture and microcolonies on human cells. Furthermore, mutant strains were incapable of producing the typical three‐dimensional layer with bacterial microcolonies embedded in a carbohydrate polymeric matrix. Complemented mutants had an adhesion and aggregation phenotype similar to the wild‐type strain. Finally, in vivo expression of pili was indirectly confirmed by demonstrating that most of the sera from human patients affected by GAS‐mediated pharyngitis recognized recombinant pili proteins. These data support the role of pili in GAS adherence and colonization and suggest a general role of pili in all pathogenic streptococci.

Targeted Amino Acid Substitutions Impair Streptolysin O Toxicity and Group A Streptococcus Virulence

ABSTRACT Streptolysin O is a potent pore-forming toxin produced by group A Streptococcus. The aims of the present study were to dissect the relative contributions of different structural domains of the protein to hemolytic activity, to obtain a detoxified form of streptolysin O amenable to human vaccine formulation, and to investigate the role of streptolysin O-specific antibodies in protection against group A Streptococcus infection. On the basis of in silico structural predictions, we introduced two amino acid substitutions, one in the proline-rich domain 1 and the other in the conserved undecapeptide loop in domain 4. The resulting streptolysin O derivative showed no toxicity, was highly impaired in binding to eukaryotic cells, and was unable to form organized oligomeric structures on the cell surface. However, it was fully capable of conferring consistent protection in a murine model of group A Streptococcus infection. When we engineered a streptococcal strain to express the double-mutated streptolysin O, a drastic reduction in virulence as well as a diminished capacity to kill immune cells recruited at the infection site was observed. Furthermore, when mice immunized with the toxoid were challenged with the wild-type and mutant strains, protection only against the wild-type strain, not against the strain expressing the double-mutated streptolysin O, was obtained. We conclude that protection occurs by antibody-mediated neutralization of active toxin. IMPORTANCE We present a novel example of structural design of a vaccine antigen optimized for human vaccine use. Having previously demonstrated that immunization of mice with streptolysin O elicits a protective immune response against infection with group A Streptococcus strains of different serotypes, we developed in this study a double-mutated nontoxic derivative that represents a novel tool for the development of protective vaccine formulations against this important human pathogen. Furthermore, the innovative construction of an isogenic strain expressing a functionally inactive toxin and its use in infection and opsonophagocytosis experiments allowed us to investigate the mechanism by which streptolysin O mediates protection against group A Streptococcus. Finally, the ability of this toxin to directly attack and kill host immune cells during infection was studied in an air pouch model, which allowed parallel quantification of cellular recruitment, vitality, and cytokine release at the infection site. We present a novel example of structural design of a vaccine antigen optimized for human vaccine use. Having previously demonstrated that immunization of mice with streptolysin O elicits a protective immune response against infection with group A Streptococcus strains of different serotypes, we developed in this study a double-mutated nontoxic derivative that represents a novel tool for the development of protective vaccine formulations against this important human pathogen. Furthermore, the innovative construction of an isogenic strain expressing a functionally inactive toxin and its use in infection and opsonophagocytosis experiments allowed us to investigate the mechanism by which streptolysin O mediates protection against group A Streptococcus. Finally, the ability of this toxin to directly attack and kill host immune cells during infection was studied in an air pouch model, which allowed parallel quantification of cellular recruitment, vitality, and cytokine release at the infection site.

Yolk granules are differentially acidified during embryo development in the stick insect Carausius morosus

Abstract. Newly laid eggs of stick insects comprise a unique fluid ooplasm that is gradually partitioned into a number of yolk granules by invasion of secondary vitellophages. This study aimed at establishing how yolk granules become acidified in the course of embryonic development. Data show that acidified yolk granules are rather scarce and randomly distributed in vitellophages of early embryos, while they tend to increase gradually in number as development proceeds to completion. Yolk granule acidification is progressively more inhibited in the presence of increasing concentrations of chloroquine, monensin and bafilomycin. A pro-protease was identified cytochemically and by immunoblotting in yolk extracts of progressively more advanced embryos. A specific monoclonal antibody raised against this pro-protease helped to demonstrate that it is gradually processed to yield a lower molecular weight polypeptide as development proceeds to completion. This latter polypeptide was identified as a protease using electrophoresis in polyacrylamide gels containing yolk extracts. Simultaneous administration of a fluorescent substrate for cysteine protease and an acidotropic probe produced superimposable labelling patterns, suggesting that only acidified yolk granules possess a proteolytic activity. On the other hand, yolk granules probed simultaneously for acidification and latent pro-protease yielded labelling patterns partially superimposed. Pro-protease labelling is gradually lost as yolk granules are progressively more acidified during development. Distinct labelling patterns were also obtained in vitellophages processed for the simultaneous detection of pro-protease and protease, suggesting that the two activities are expressed by different yolk granule populations, and that one is gradually converted into the other as time goes by.

The diverticulated crop of adult Phormia regina.

The crop of adult Phormia regina consists of a duct that diverges from the esophagus, just in front of the cardia, and extends ventrally and posteriorly into the thorax and abdomen where it forms a bilobed sac. Flattened epithelial cells produce the cuticular lining of the crop. When empty, or partially full, the epithelial cells and cuticular lining form folds extending into the lumen, thus providing for expansion as the crop sac fills. Covering the sac on the hemolymph side is a layer of anastomosed, intrinsic muscles connected to one another by intercellular cytoplasmic bridges. Mitochondria are located at the periphery of the sarcomere. Also inside the sarcomere are glycogen, sarcoplasmic reticula, and transverse tubular systems (T-system). I, A, and Z-bands are present and the Z-bands are not in register making the muscle-type supercontractile. Important structures, not previously researched and associated with the crop muscles, are the crop nerves. Coming off the corpora cardiaca, and running down each side of the crop duct, is a pair of nerves, each housing several axons. These nerves extend to and branch over the crop sac. Here they penetrate the muscle mass and form neuromuscular junctions where electron-dense droplets of neurosecretion are released. Based on the literature, and research in our laboratory, it has now been shown that these nerves carry adipokinetic hormone, Drosophila insulin-like peptide, and a dromyosuppressin-like neuropeptide.

A morphological and biochemical analysis comparative study of the collagen products Biopad, Promogram, Puracol, and Colactive.

ABSTRACT The aim of this study was to compare the capacity of the collagen products Biopad (Euroresearch, Milano, Italy), Promogran (Systagenix Wound Management, Quincy, Massachusetts), Colactive (Smith & Nephew, St Petersburg, Florida), and Puracol (Medline Industries, Mundelein, Illinois) to interact with biological tissues and to start restoring the healing process. These results demonstrate how these products can interact differently with enzymes and cells that characterize the environment of a healing wound.

Ultrastructural investigation on fibroblast interaction with collagen scaffold

Collagen-based scaffolds are used as temporary or permanent coverings to help wound healing. Under natural conditions, wound healing is affected by such factors as cell types, growth factors and several components of the extracellular matrix. Due to the complexity of the cell-to-matrix interaction, many cell based mechanisms regulating wound healing in vivo are not yet properly understood. However, the whole process can be partially simulated in vitro to determine how cells interact with the collagen scaffold in relation to such features as physico-chemical properties, matrix architecture and fiber stability. Under these conditions, cell migration into the collagen matrix can be easily assessed and causally correlated with these features. In this study, we aimed at providing a structural analysis of how NIH3T3 fibroblasts migrate and proliferate in vitro when seeded on a native type-I collagen scaffold. To this end, samples were collected at regular time intervals and analyzed by light microscopy (LM), scanning electron microscopy (SEM) and transmission electron microscopy (TEM). Through this experimental approach we demonstrate that collagen is gradually frayed into progressively thinner fibrils as fibroblasts migrate into the matrix, embrace the collagen fibers with long filopodia and form large intracellular vacuoles. A key role in this process is also played by microvesicles shed from the fibroblast plasma membrane and spread over long distances inside the collagen matrix. These observations indicate that a native type-I equine collagen provides favorable conditions for simulating collagen processing in vitro and eventually for unraveling the mechanisms controlling cell uptake and intracellular degradation.

Microvesicles shed from fibroblasts act as metalloproteinase carriers in a 3-D collagen matrix

This study shows that fibroblasts migrating into a collagen matrix release numerous microvesicles into the surrounding medium. By spreading in regions of the matrix far distant from cells of origin, microvesicles carry metalloproteinase 9 (MMP-9) to act upon the collagen fibrils. As a result, the collagen matrix is gradually transformed from a laminar to a fibrillar type of architecture. As shown by western blots and gelatin zymography, MMP-9 is secreted as a 92 kDa precursor and activated upon release of 82 kDa product into the culture medium. Activation is more efficient under three-dimensional than in two-dimensional culturing conditions. While MMP-9 labeling is associated with intraluminal vesicles clustered inside the microvesicles, the microvesicle’s integrin β1 marker is bound to the outer membrane. The intraluminal vesicles are recruited from the cortical cytoplasm and eventually released following uploading inside the microvesicle. Here, we propose that fusion of the intraluminal vesicles with the outer microvesicle’s membrane could work as a mechanism controlling the extent to which MMP-9 is first activated and then released extracellularly.

Ultrastructure of the salivary glands of non-infected and infected glands in Glossina pallidipes by the salivary glands hypertrophy virus

Light, scanning electron, and transmission electron microscopy analyses were conducted to examine the morphology and ultrastructure of the salivary glands of Glossina pallidipes. Three distinct regions, each with a characteristic composition and organization of tissues and cells, were identified: secretory, reabsorptive and proximal. When infected with the salivary gland hypertrophy (SGH) virus, glands showed a severe hypertrophy, accompanied by profound changes in their morphology and ultrastructure. In addition, the muscular fibers surrounding the secretory region of the glands were disrupted. The morphological alterations in the muscular tissue, caused by viral infection, could be an important aspect of the pathology and may shed light on the mode of action of the SGH virus. Results were discussed with regard to the potential effect of viral infection on normal salivation and on the ability of infected tsetse flies to transmit a trypanosome parasite.

Serosa membrane plays a key role in transferring vitellin polypeptides to the perivitelline fluid in insect embryos

In mid‐embryogenesis, the stick insect Carausius morosus comes to be comprised of three distinct districts: the embryo proper, the yolk sac and the perivitelline fluid. A monolayered epithelium, the so‐called serosa membrane, encloses the yolk sac and its content of vitellophages and large yolk granules. During embryonic development, the yolk sac declines gradually in protein concentration due to Vt polypeptides undergoing limited proteolysis to yield a number of Vt cleavage products of lower molecular weights. mAbs 1D1 and 5H11 are monoclonal antibodies raised against some of the Vt cleavage products generated by this process in the yolk sac. At the confocal microscope, antibody fluorescence is initially associated with a few yolk granules, while it is gradually displaced in the cytosolic spaces of the vitellophages. With the proceeding of embryonic development, label appears also in the serosa membrane in the form of clustered dots. At the ultrastructural level, gold particles are initially associated with the vitellophages that are labeled on a few yolk granules and in the cytosolic space flanking the yolk granules. Subsequently, the serosa cells become labeled on vesicles close to the yolk granules or just underneath the plasma membrane. Inside the serosa cells, label is also associated with granules budding from the Golgi apparatus, but never with the intercellular channels percolating the serosa membrane. These observations are interpreted as indicating that Vt cleavage products leak out from the yolk granules into the cytosolic spaces of the vitellophages and are eventually transferred to the perivitelline fluid via transcytosis through the serosa cells.

Disruption of the salivary gland muscle in tsetse, Glossina pallidipes Austen, as a result of salivary gland hypertrophy virus infection

The secretory region of the salivary glands in Glossina pallidipes Austen (Diptera: Glossinidae) is characterized by an external muscle layer. Scanning electron microscopy and transmission electron microscopy investigations provide a detailed description of the longitudinal muscle fibres and a comparison of their structure when affected by salivary gland hypertrophy virus. The virus is responsible for hypertrophy of the salivary glands in symptomatic flies, specifically of the muscle fibres, the cytoarchitecture of which is completely altered. Although observations did not reveal viral particles in the muscle cells of either asymptomatic or symptomatic flies, muscle fibres were enlarged and detached from one another and their associated basement membrane only in symptomatic flies. A decrease in type IV collagen labelling in the basement membrane of the muscles in symptomatic flies is reported and is considered a potential cause of the salivary gland muscle alteration and, possibly, myopathy. The maintenance of an organized muscular layer is essential for the normal secretion of saliva and hence its pathology in symptomatic tsetse flies could affect the normal transmission of the trypanosome that develops inside the salivary gland epithelium. Therefore, a better understanding of the possible role of the virus is essential in order to elucidate its impact on salivary deployment in symptomatic flies.