Case of chromoblastomycosis appearing in an Okinawa patient with a medical history of Hansen's disease.

Chromoblastomycosis is one of several chronic infectious skin diseases caused by various species of dematiaceous fungi. It is clinically characterized by verrucous skin eruptions and occurs most commonly in tropical and subtropical regions. In Okinawa, a subtropical area, there have been only three reported cases of chromoblastomycosis including the present one. Direct microscopic examination of crust specimens and findings of sclerotic cells in histopathology can confirm the diagnosis, and cultures of crust and/or tissue specimens can identify the causative fungi. We herein report the third case of chromoblastomycosis in Okinawa; it arose in an 87-year-old Japanese woman with a history of Hansen's disease, who lived in a leprosarium in Miyako Island. To identify the causative agent as Fonsecaea pedrosoi, we used the polymerase chain reaction and direct sequencing analysis in addition to the usual methods, which include 20% potassium hydroxide microscopy, histopathological confirmation of sclerotic cells by periodic acid-Schiff stain, culture by Sabouraud's glucose agar, slide culture method, and observation of conidia by scanning electron microscopic examination.

Why do some yeast species require niacin for growth? Different modes of NAD synthesis.

NAD holds a key position in metabolism and cellular regulatory events as a major redox carrier and a signalling molecule. NAD biosynthesis pathways have been reconstructed and compared in seven yeast species with completely sequenced genomes, including Saccharomyces cerevisiae, Kluyveromyces lactis, Candida glabrata, Debaryomyces hansenii, Candida albicans, Yarrowia lipolytica and Schizosaccharomyces pombe. Both amino acid and nucleotide sequence similarity analysis in silico indicated that de novo NAD biosynthesis might not exist in K. lactis, C. glabrata and Schiz. pombe, while other species have the kynurenine pathway. It also showed that the NAD salvage pathway via nicotinic acid and nicotinic acid mononucleotide is conserved in all of these yeasts. Deletion of KlNPT1 (the gene for nicotinate phosphoribosyl-transferase) is lethal, which demonstrates that this salvage pathway, utilizing exogenous nicotinic acid, is the unique route to synthesize NAD in K. lactis. The results suggested that the basis of the variation of niacin requirements in yeasts lies in their different combinations of NAD biosynthesis pathways. The de novo pathway is absent but the salvage pathway is conserved in niacin-negative yeasts, while both pathways coexist in niacin-positive yeasts.

Effects of aliphatic acids, furfural, and phenolic compounds on Debaryomyces hansenii CCMI 941.

Debaryomyces hansenii is a polyol overproducing yeast that can have a potential use for upgrading lignocellulosic hydrolysates. Therefore, the establishment of its tolerance to metabolic inhibitors found in hydrolysates is of major interest. We studied the effects of selected aliphatic acids, phenolic compounds, and furfural. Acetic acid favored biomass production for concentrations <6.0 g/L. Formic acid was more toxic than acetic acid and induced xylitol accumulation (maximum yield of 0.21 g/g of xylose). All tested phenolics strongly decreased the specific growth rate. Increased toxicity was found for hydroquinone, syringaldehyde, and 4-methylcatechol and was correlated to the compound's hydrophobicity. Increasing the amount of furfural led to longer lag phases and had a detrimental effect on specific growth rate and biomass productivity.

Induction of the sexual stage of Pestalotiopsis microspora, a taxol-producing fungus.

Pestalotiopsis microspora, isolate NE-32, is an endophyte of the Himalayan yew (Taxus wallichiana) that produces taxol, an important chemotherapeutic drug used in the treatment of breast and ovarian cancers. Conditions were determined to induce the perfect stage (teleomorph) of this organism in the laboratory as a critical first step to study inheritance of taxol biosynthetic genes. The perfect stage of Pestalotiopsis microspora NE-32 forms in a period of 3-6 weeks on water agarose with dried yew needles at 16-20 degrees C with 12 h of light per day. Morphological analysis of the teleomorph and sequencing of the 18S rDNA indicates that Pestalosphaeria hansenii is the perfect stage of Pestalotiopsis microspora. Only certain plants (e.g. yews, some pines, pecan, oat and some barley cultivars) allow the production of perithecia. Exhaustive methylene chloride extraction of yew (Taxus cuspidata) needles removes their capacity to induce production of perithecia. The methylene chloride extract is able to induce formation of perithecia by strain NE-32 in a bioassay system utilizing the sterilized sheaths of the Cholla cactus (Opuntia bigelovii) spine, indicating that a chemical compound(s) in yew stimulates the formation of the perfect stage. This hydrophobic plant compound(s) has been designated the perithecial-stimulating factor (PSF). The data suggest that plant products may play a role in regulating the biology of endophytic microbes.