Differential Candida albicans lipase gene expression during alimentary tract colonization and infection

The human pathogenic fungus Candida albicans, which can reside as a benign commensal of the gut, possesses a large family of lipase encoding genes whose extracellular activity may be important for colonization and subsequent infection. The expression of the C. albicans lipase gene family (LIP1-10) was investigated using a mouse model of mucosal candidiasis during alimentary tract colonization (cecum contents) and orogastric infection. LIPs4-8 were expressed in nearly every sample prepared from the cecum contents and infected mucosal tissues (stomach, hard palate, esophagus and tongue) suggesting a maintenance function for these gene products. In contrast, LIPs1, 3, and 9, which were detected consistently in infected gastric tissues, were essentially undetectable in infected oral tissues. In addition, LIP2 was expressed consistently in cecum contents but was undetectable in infected oral tissues suggesting LIP2 may be important for alimentary tract colonization, but not oral infection. The host responded to a C. albicans infection by significantly increasing expression of the chemokines MIP-2 and KC at the site of infection. Therefore, differential LIP gene expression was observed during colonization, infection and at different infected mucosal sites.     

Immunosensing during colonization by Candida albicans: does it take a village to colonize the intestine?

Candida albicans, an opportunistic fungal pathogen and a component of the normal flora of the gastrointestinal tract, is a frequent colonizer of humans. Is C. albicans capable of sensing the immune status of its host, a process we term immunosensing, and, if so, how? C. albicans causes serious disease only in immunocompromised hosts and therefore the ability to immunosense would be advantageous to an organism. We propose a speculative model whereby, during colonization, C. albicans produces phenotypic variants that vary in relative concentration depending on host status. One variant is optimized for persistence as a commensal, whereas the other variant has higher capacity to initiate pathogenic interactions. When the ratio of the two variants changes, the pathogenic potential of the population changes. The critical element of this model is that the C. albicans colonizing population is not uniform but is composed of subpopulations of phenotypic variants that are advantageous under different host conditions.     

Role of the fungal Ras-protein kinase A pathway in governing epithelial cell interactions during oropharyngeal candidiasis

Tpk1p, Tpk2p and Efg1p are members of the Ras-protein kinase A pathway that governs the yeast-to-hyphal transition in Candida albicans. We used tpk1Delta/tpk1Delta, tpk2Delta/tpk2Delta and efg1Delta/efg1Delta mutants to investigate the role of these proteins in regulating the interactions of C. albicans with oral epithelial cell lines in vitro and virulence in murine models of oropharyngeal candidiasis (OPC) and haematogenously disseminated candidiasis (HDC). The tpk1Delta/tpk1Delta strain adhered to, invaded and damaged oral epithelial cells in vitro similarly to the wild-type strain. In contrast, both the tpk2Delta/tpk2Delta and efg1Delta/efg1Delta strains had reduced capacity to invade and damage oral epithelial cells, and the efg1Delta/efg1Delta strain also exhibited decreased adherence to these cells. Consistent with these in vitro findings, the tpk2Delta/tpk2Delta and efg1Delta/efg1Delta strains also had significantly attenuated virulence during OPC. Therefore, Tpk2p and Efg1p both govern factors that enable C. albicans to invade and damage oral epithelial cells in vitro and cause OPC. These results also suggest that hyphal formation mediated by the Ras-protein kinase A pathway is a key virulence mechanism during OPC. Interestingly, the efg1Delta/efg1Delta strain, but not the tpk2Delta/tpk2Delta had reduced virulence during HDC. Thus, Tpk2p may be more important for governing virulence during OPC than HDC.     

Chlamydospore-like cells of Candida albicans in the gastrointestinal tract of infected, immunocompromised mice

We have demonstrated in a previously described murine model of gastrointestinal (GI) and systemic candidiasis that the antifungal angent cilofungin was efficacious in clearing infection of body organs when administered subcutaneously by infusion, but permitted large numbers of Candida albicans in the GI tract to persist. Yeast and hyphae in these animals were associated primarily with the stratified squamous epithelium of the stomach. Administration of immunocompromising drugs (cyclophosphamide plus cortisone acetate) to animals with persistent GI infection resulted in relapse of systemic candidiasis. Histological examination of the gastric mucosa revealed invasive hyphal elements and yeast as well as multiple chlamydospore-like cells. Comparative histochemical and electron-microscopic examinations of these latter cells produced in host tissue and chlamydospores formed in vitro were conducted. The results suggested that similarities in wall and cytoplasmic composition and ultrastructure exist between these in vivo and in vitro produced C. albicans cells. Exposure of C. albicans to cyclophosphamide during in vitro growth resulted in stimulation of chlamydospore production. No significant effect of cortisone acetate on C. albicans morphogenesis was detected. The murine model used in this study permits investigation of the formation of chlamydospore-like cells of C. albicans during early stages of fungal invasion of cyclophosphamide-treated mice, and of the possible influence of these cells on immunological response of the host to persistent candidiasis of the GI tract.     

Candida albicans Niche Specialization: Features That Distinguish Biofilm Cells from Commensal Cells

The fungus Candida albicans is a frequent commensal colonizer of the human gastrointestinal (GI) tract, but is also an opportunistic pathogen. This review explores features that distinguish the colonizing and pathogenic forms of C. albicans. Candida albicans in a biofilm is used as an example of a pathogenic form of the organism, because biofilms are a common feature of device-associated C. albicans infections. Biofilms (complex, sessile communities of cells) have been the subject of several large-scale gene expression studies. Biofilms and commensal C. albicans colonizing the murine GI tract show a variety of differentially expressed genes. Cell surface proteins encoded by these differentially expressed genes are especially attractive as targets for new clinical prevention, diagnosis, or treatment tools that are specific for C. albicans in its pathogenic biofilm state.     

Genome-wide transcriptional profiling of the cyclic AMP-dependent signaling pathway during morphogenic transitions of Candida albicans

Candida albicans is an opportunistic human fungal pathogen that causes systemic candidiasis as well as superficial mucosal candidiasis. In response to the host environment, C. albicans transitions between yeast and hyphal forms. In particular, hyphal growth is important in facilitating adhesion and invasion of host tissues, concomitant with the expression of various hypha-specific virulence factors. In previous work, we showed that the cyclic AMP (cAMP) signaling pathway plays a crucial role in morphogenic transitions and virulence of C. albicans by studying genes encoding adenylate cyclase-associated protein (CAP1) and high-affinity phosphodiesterase (PDE2) (Y. S. Bahn, J. Staab, and P. Sundstrom, Mol. Microbiol. 50:391-409, 2003; and Y. S. Bahn and P. Sundstrom, J. Bacteriol. 183:3211-3223, 2001). However, little is known about the downstream targets of the cAMP signaling pathway that are responsible for morphological transitions and the expression of virulence factors. Here, microarrays were probed with RNA from strains with hypoactive (cap1/cap1 null mutant), hyperactive (pde2/pde2 null mutant), and wild-type cAMP signaling pathways to provide insight into the molecular mechanisms of virulence that are regulated by cAMP and that are related to the morphogenesis of C. albicans. Genes controlling metabolic specialization, cell wall structure, ergosterol/lipid biosynthesis, and stress responses were modulated by cAMP during hypha formation. Phenotypic traits predicted to be regulated by cAMP from the profiling results correlated with the relative strengths of the mutants when tested for resistance to azoles and subjected to heat shock stress and oxidative/nitrosative stress. The results from this study provide important insights into the role of the cAMP signaling pathway not only in morphogenic transitions of C. albicans but also for adaptation to stress and for survival during host infections.     

Candida glabrata and Candida albicans; dissimilar tissue tropism and infectivity in a gnotobiotic model of mucosal candidiasis

Germ-free transgenic epsilon 26 (Tgepsilon26) mice, deficient in both natural killer (NK)- and T-cells, were inoculated (orally) with each of two Candida glabrata (BG2 or BG1003) or Candida albicans (CAF2-1 or SC5314) strains. Candida glabrata- or C. albicans-colonized mice exhibited similar numbers of viable Candida in the alimentary tract. Neither C. glabrata nor C. albicans caused systemic candidiasis of endogenous (alimentary tract) origin. Candida albicans invaded oroesophageal (tongue, palate, esophagus) and keratinized gastric tissues, evoked hyperkeratosis and a prominent, chronic, granulocyte-dominated, inflammatory response in all infected tissues, stimulated the production of splenic granulocytes and was lethal for the mice within 3-5 weeks after oral colonization. The two C. glabrata strains colonized the alimentary tract and penetrated into the keratinized (cardia-antrum) gastric tissues, but in contrast to C. albicans, were unable to infect oroesophageal tissues. Furthermore, C. glabrata strains were not lethal for the Tgepsilon26 mice, and did not evoke an inflammatory response in colonized gastric tissues or stimulate the production of splenic granulocytes. This 'stealth-like' behavior could explain the ability of C. glabrata to persist in infected tissues and survive as a commensal in the alimentary tract.