Biofilm formation (BF) in the setting of candiduria has not been well studied. We determined BF and MIC to antifungals in Candida spp. isolates grown from urine samples of patients and performed a retrospective chart review to examine the correlation with risk factors. A total of 67 Candida spp. isolates were grown from urine samples from 55 patients. The species distribution was C. albicans (54%), C. glabrata (36%), and C. tropicalis (10%). BF varied greatly among individual Candida isolates but was stable in sequential isolates during chronic infection. BF also depended on the growth medium and especially in C. albicans was significantly enhanced in artificial urine (AU) compared to RPMI medium. In nine of the C. albicans strains BF was 4-to 10-fold higher in AU, whereas in three of the C. albicans strains and two of the C. glabrata strains higher BF was measured in RPMI medium than in AU. Determination of the MICs showed that planktonic cells of all strains were susceptible to amphotericin B (AMB) and caspofungin (CASPO) and that three of the C. glabrata strains and two of the C. albicans strains were resistant to fluconazole (FLU). In contrast, all biofilm-associated adherent cells were resistant to CASPO and FLU. The biofilms of 14 strains (28%) were sensitive to AMB (MIC 50 of <1 g/ml). Correlation between degree of BF and MIC of AMB was not seen in RPMI grown biofilms but was present when grown in AU. A retrospective chart review demonstrated no correlation of known risk factors of candiduria with BF in AU or RPMI. We conclude that BF is a stable characteristic of Candida strains that varies greatly among clinical strains and is dependent on the growth medium. Resistance to AMB is associated with higher BF in AU, which may represent the more physiologic medium to test BF. Future studies should address whether in vitro BF can predict treatment failure in vivo.
Although several virulence factors and associated genes have been identified, the mechanisms that allow Cryptococcus neoformans to adapt during chronic infection and to persist in immunocompromised hosts remain poorly understood. Characterization of senescent cells of C. neoformans demonstrated that these cells exhibit a significantly enlarged cell body and capsule but still cross the blood-brain barrier. C. neoformans cells with advanced generational age are also more resistant to phagocytosis and killing by antifungals, which could promote their selection during chronic disease in humans. Senescent cells of RC-2, a C. neoformans strain that undergoes phenotypic switching, manifest switching rates up to 11-fold higher than those of younger cells. Infection experiments with labeled cells suggest that senescent yeast cells can potentially accumulate in vivo.Mathematical modeling incorporating different switching rates demonstrates how increased switching rates promote the emergence of hypervirulent mucoid variants during chronic infection. Our findings introduce the intriguing concept that senescence in eukaryotic pathogens could be a mechanism of microevolution that may promote pathoadaptation and facilitate evasion of an evolving immune response.
T-cell stimulating activity of Staphylococcal enterotoxin B (SEB) is an important factor in the pathogenesis of certain staphylococcal diseases including SEB mediated shock. SEB is one of the most potent superantigens known and treatment of SEB induced shock remains a challenge. We generated and characterized murine monoclonal antibodies (mAbs) to SEB in mice. We tested mAbs neutralize mitogenic effects of SEB in vitro and in vivo with T-cell proliferation assays and 2 murine models for SEB induced lethal shock (SEBILS). Epitope mapping suggests that all these mAbs recognize conformational epitopes that are destroyed by deleting the C terminus of the protein. Further site-directed mutagenesis identified potential residues involved in binding to SEB that differ between Methicillin resistant and sensitive Staphylococcus aureus strains. Only mAb 20B1 was effective as a monotherapy in treating SEBILS in HLA DR3 transgenic mice, which exhibit enhanced sensitivity to SEB. It is noteworthy that mAbs, 14G8 and 6D3 were not protective when given alone in the HLA DR3 mice but their efficacy of protection could be greatly enhanced when mAbs were co-administered simultaneously. Our data suggest combinations of defined mAbs may constitute a better treatment strategy and provide a new insight for the development of passive immunotherapy. The Staphylococcal enterotoxins (SEs)2 comprise a family of distinct toxins (A-E) all of which are excreted by various strains of Staphylococcus aureus (S. aureus) (1). Staphylococcal enterotoxin B (SEB) is a well characterized 28 kDa protein that is related to SEC1-3 on the basis of sequence homology (1, 2). SEB is a superantigen that triggers cytokine production and T-cell proliferation by cross-linking MHC class II molecules on antigen presenting cells and T-cell receptors (TCR) (2-5). In humans, SEB can trigger toxic shock, profound hypotension and multi-organ failure. SEB is the major enterotoxin associated with non-menstrual toxic shock syndrome and accounts for the majority of intoxications that are not caused by toxic shock syndrome toxin 1 (TSST-1). In addition, some reports indicate that SEB induces an IgE response and thereby might contribute to the pathogenesis of asthma, chronic rhinitis, and dermatitis (6 -9). SEB is considered a select agent. The quantities needed to produce a desired effect are much lower than with synthetic chemicals. Also SEB can be easily produced in large quantities (10).Currently there are no therapies available for treating enterotoxin-induced shock, but clinical data suggests that immunoglobulins can alleviate disease (11). Moreover, passive administration of pooled human immunoglobulin, as well as murine and chicken antibodies (Abs) can protect against SEB induced lethal shock (SEBILS) in murine and primate animal models as well as against SEB triggered release of cytokines by SEB stimulated T-cells (12, 13). The efficacy of humoral immunity in protection against SEB was established by demonstrating an inverse relationship between susceptibility and an...
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