Calcineurin-Crz1 signaling in lower eukaryotes.

Calcium ions are ubiquitous intracellular messengers. An increase in the cytosolic Ca(2+) concentration activates many proteins, including calmodulin and the Ca(2+)/calmodulin-dependent protein phosphatase calcineurin. The phosphatase is conserved from yeast to humans (except in plants), and many target proteins of calcineurin have been identified. The most prominent and best-investigated targets, however, are the transcription factors NFAT (nuclear factor of activated T cells) in mammals and Crz1 (calcineurin-responsive zinc finger 1) in yeast. In recent years, many orthologues of Crz1 have been identified and characterized in various species of fungi, amoebae, and other lower eukaryotes. It has been shown that the functions of calcineurin-Crz1 signaling, ranging from ion homeostasis through cell wall biogenesis to the building of filamentous structures, are conserved in the different organisms. Furthermore, frequency-modulated gene expression through Crz1 has been discovered as a striking new mechanism by which cells can coordinate their response to a signal. In this review, I focus on the latest findings concerning calcineurin-Crz1 signaling in fungi, amoebae and other lower eukaryotes. I discuss the potential of Crz1 and its orthologues as putative drug targets, and I also discuss possible parallels with calcineurin-NFAT signaling in mammals.

Systemic fungal infections caused by Candida species: epidemiology, infection process and virulence attributes.

Candida species, in particular C. albicans, represent a major threat to immunocompromised patients. Able to exist as a commensal on mucosal surfaces of healthy individuals, these opportunistic fungi frequently cause superficial infections of mucosae and skin. Furthermore, in hospital settings, Candida species may cause life-threatening invasive infections in a growing population of vulnerable patients. In fact, candidaemia is associated with the highest crude mortality of all bloodstream infections. Candida cells may enter the bloodstream by direct penetration from epithelial tissues, due to damage of barriers in the body caused by surgery, polytrauma or drug treatment, or may spread from biofilms produced on medical devices. From the bloodstream, cells may infect almost all organs but appear to prefer certain organs depending upon the route of infection. The exact mechanisms by which Candida cells survive the challenge of the blood environment and escape from the bloodstream to cause deep-seated infections have not yet been elucidated, but various investigations are reviewed. It is clear, however, that Candida must have particular attributes which enable the organism to survive and grow within the environment of healthy individuals and to invade tissues in the immunocompromised host. Most studies have focussed on C. albicans and this review will therefore summarise work on the various known virulence factors and methods used to identify further virulence attributes of this fungus.

Characterization of a gene in the car cluster of Fusarium fujikuroi that codes for a protein of the carotenoid oxygenase family.

The ascomycete Fusarium fujikuroi produces carotenoids by means of the enzymes encoded by three car genes. The enzymes encoded by carRA and carB are responsible of the synthesis of beta-carotene and torulene, respectively, while the product encoded by carT cleaves torulene to produce the acidic xanthophyll neurosporaxanthin. carRA and carB are found in a cluster with a third gene, carO, which codes for an opsin-like protein. However, no information is available on the sequence or chromosomal location of carT, which has been identified only by mutant analysis. Transcription of the three clustered genes is stimulated by light and by mutations in a regulatory gene, leading to overproduction of carotenoids. We have now identified a fourth gene in the car cluster, called carX, which codes for a protein similar to known carotenoid-cleaving oxygenases. carX is transcribed divergently from carRA, and exhibits the same transcriptional pattern as carRA, carB and carO. Targeted deletion of carX resulted in a phenotype characterized by a significant increase in the overall carotenoid content. In the dark, the carX mutants accumulate at least five times more carotenoids than the wild type, and exhibit partial derepression of carRA and carB transcription. The mutants also show more intense pigmentation in the light, but the increase in the carotenoid content relative to the wild type is less than twofold. Under these conditions, the mutants also show a relative increase in the amounts of phytoene and cyclic carotenoids formed, suggesting that CarRA activity is enhanced.

Characterization of the eugenol hydroxylase genes (ehyA/ehyB) from the new eugenol-degrading Pseudomonas sp. strain OPS1.

During the screening for bacteria capable of converting eugenol to vanillin, strain OPS1 was isolated, which was identified as a new Pseudomonas species by 16 s rDNA sequence analysis. When this bacterium was grown on eugenol, the intermediates, coniferyl alcohol, ferulic acid, vanillic acid, and protocatechuic acid, were identified in the culture supernatant. The genes encoding the eugenol hydroxylase (ehyA, ehyB), which catalyzes the first step of this biotransformation, were identified in a genomic library of Pseudomonas sp. strain OPS1 by complementation of the eugenol-negative mutant SK6165 of Pseudomonas sp. strain HR199. EhyA and EhyB exhibited 57% and 85% amino acid identity to the eugenol hydroxylase subunits of Pseudomonas sp. strain HR199 and up to 34% and 54% identity to the corresponding subunits of p-cresol methylhydroxylase from P. putida. Moreover, the amino-terminal sequences of the alpha- and beta-subunits reported recently for an eugenol dehydrogenase of P fluorescens E118 corresponded well with the appropriate regions of EhyA and EhyB. Downstream of ehyB, an open reading frame was identified, whose deduced amino acid sequence exhibited up to 71% identity to azurins, representing most probably the gene (azu) of the physiological electron acceptor of the eugenol hydroxylase. The eugenol hydroxylase genes were amplified by PCR, cloned, and functionally expressed in Escherichia coli.