SummaryEncephalopathies and neurological disorders are sometimes associated with respiratory tract infections caused by Bordetella pertussis. For these complications to occur cerebral barriers have to be compromised. Therefore, the influence of pertussis toxin (PT), a decisive virulence determinant of B. pertussis, on endothelial barrier integrity was investigated. Human brain microvascular endothelial cells cultured on Transwell filter devices were used as model for the blood brain barrier. PT, but not its B-oligomer, induced a reduction of the transendothelial resistance and enhanced the permeability for the protein marker horseradish peroxidase. Moreover, transmigration of human monocytes was also elevated suggesting a PT-associated enhancement of the diapedesis of blood leucocytes. Uptake and trafficking of PT was followed by electron microscopy via clathrin-coated pits and accumulation in lysosomes and microvesicular bodies. The breach in barrier integrity was accompanied by a transient disintegration of Golgi structures. Interestingly, PT-induced effects were only transient and restoration of barrier function was observed after 24 h. In summary, intoxication by PT causes a transient destruction of the cellular organization in human brain-derived endothelial cells resulting in a transient disruption of barrier functions. We suggest that these findings reflect early steps in the development of neurological disorders associated with pertussis disease.
The success of Histoplasma capsulatum as an intracellular pathogen depends completely on successful conversion of the saprophytic mycelial (mold) form of this fungus to a parasitic yeast form. It is therefore not surprising that yeast phase-specific genes and gene products are proving to be important for survival and proliferation of H. capsulatum within macrophages. In this study, we have focused on the role and regulation of two yeast-specific characteristics: ␣-(1,3)-glucan, a cell wall polysaccharide modulated by cell-density (quorum) sensing, and a secreted calcium-binding protein (CBP) that is essential for pathogenicity.
Dimorphism is an essential feature of Histoplasma capsulatum pathogenesis, and much attention has been focused on characteristics that are unique to the saprophytic mycelial phase or the parasitic yeast phase. Recently, we identified a secreted calcium‐binding protein, CBP, that is produced in large amounts by yeast cells but is undetectable in mycelial cultures. In this study, the green fluorescent protein (GFP) was established as a reporter in H. capsulatum to study regulation of CBP1 expression in cultures and in single cells grown under different conditions and inside macrophages. One GFP version that was optimized for human codon usage yielded highly fluorescent Histoplasma yeast cells. By monitoring GFP fluorescence during the transition from mycelia to yeast, we demonstrated that the CBP1 promoter is only fully active after complete morphological conversion to the yeast form, indicating for the first time that CBP1 is developmentally regulated rather than simply temperature regulated. Continuous activity of the CBP1 promoter during infection of macrophages supports the hypothesis that CBP secretion plays an important role for Histoplasma survival within the phagolysosome. Broth cultures of Histoplasma yeasts carrying a CBP–GFP protein fusion construct were able to secrete a full‐length fluorescent fusion protein that remained localized within the phagolysosomes of infected macrophages. Additionally, a comparison of two Histoplasma strains carrying the CBP1 promoter fusion construct either epichromosomally or integrated into the chromosome revealed cell‐to‐cell variation in plasmid copy number due to uneven plasmid partitioning into daughter cells.
Host eukaryotic cell genes that are differentially transcribed after phagocytosis of various pathogenic and nonpathogenic bacterial cells were identified by a differential PCR (DPCR) system. This DPCR procedure favors detection and isolation of host genes affected at the transcriptional level by selecting for poly(A) tails but differs substantially from reverse transcription-PCR. Several unidentified macrophage gene fragments from genes that were either transcriptionally activated or downregulated following uptake of Listeria monocytogenes into J774 mouse macrophage cells were initially defined by this DPCR procedure. Because of the sensitivity of the DPCR technique, all of the genes exhibited less than a 10-fold difference in transcription compared with noninfected cells as measured by limiting-dilution PCR. One of the gene fragments has a very high level of homology with a mitogen-activated protein kinase phosphatase (MKP-1), whereas the other affected fragments showed no homologies to known gene sequences. In addition, one of the gene fragments (WS30-B2/1) was specifically downregulated after L. monocytogenes uptake and another gene was repressed by uptake of either Shigella flexneri or L. monocytogenes, while transcription of the genes represented by fragment WS13-B9/9, and to some extent MKP-1, was activated following general phagocytosis (i.e., following uptake of any species of bacterium tested). Further characterization of the affected genes was conducted by using mutants of L. monocytogenes. A hemolysin-negative mutant of L. monocytogenes failed to elicit transcriptional regulation of gene fragment WS10-B4/14 or WS30-B2/1, and it elicited only minimal regulation of MKP-1, suggesting that escape from the phagosome may be required to initiate these responses. Furthermore, mutants with mutations in mpl and actA, two genes whose gene products are involved in actin polymerization and intrahost spread, also did not induce regulation of WS10-B4/14. These results demonstrate that (i) DPCR can identify specific host cell genes which are differentially transcribed after infection with certain microorganisms and (ii) some of these genes may be new or may never before have been linked to interactions between hosts and pathogens.
In this study we show that protein tyrosine kinases and also protein tyrosine phosphatases are involved in the uptake of Listeria monocytogenes by J774 macrophages to a different extent than in the uptake of inert latex beads. In addition, protein tyrosine kinases are necessary for the intracellular growth and survival of L. monocytogenes. The expression of the MAP kinase phosphatase MKP-1, a protein tyrosine phosphatase, is induced upon infection, and phagocytosis of L. monocytogenes by J774 cells overexpressing the MKP-1 protein is reduced compared to control cells. The decreased phagocytosis of L. monocytogenes as a result of the MKP-1 overexpression in J774 macrophages suggests that the activation of the MAP kinase(s) ERK-1 and/or ERK-2 is an essential requirement for the uptake of L. monocytogenes by J774 macrophages.
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