Grf10 regulates the response to copper, iron, and phosphate in Candida albicans.

The pathogenic yeast, Candida albicans, and other microbes must be able to handle drastic changes in nutrient availability within the human host. Copper, iron, and phosphate are essential micronutrients for microbes that are sequestered by the human host as nutritional immunity; yet high copper levels are employed by macrophages to induce toxic oxidative stress. Grf10 is a transcription factor important for regulating genes involved in morphogenesis (filamentation, chlamydospore formation) and metabolism (adenylate biosynthesis, 1-carbon metabolism). The grf10Δ mutant exhibited resistance to excess copper in a gene dosage-dependent manner but grew the same as the wild type in response to other metals (calcium, cobalt, iron, manganese, and zinc). Point mutations in the conserved residues D302 and E305, within a protein interaction region, conferred resistance to high copper and induced hyphal formation similar to strains with the null allele. The grf10Δ mutant misregulated genes involved with copper, iron, and phosphate uptake in YPD medium and mounted a normal transcriptional response to high copper. The mutant accumulated lower levels of magnesium and phosphorus, suggesting that copper resistance is linked to phosphate metabolism. Our results highlight new roles for Grf10 in copper and phosphate homeostasis in C. albicans and underscore the fundamental role of Grf10 in connecting these with cell survival.

Histological and molecular evaluation of iron as degradable medical implant material in a murine animal model.

A small animal model was established to evaluate the potential of iron as a degradable implant material. After insertion into the tail of mice, the implants gradually degraded over a clinically relevant time period of several months. Histological analysis and gene expression data from whole-genome microarray analyses indicated a limited inflammatory reaction. No evidence of cellular responses to excess iron ions was detected, suggesting that the iron degradation products were metabolically inactive. Iron-rich compounds could be detected in the vicinity of the implant and in individual cells distant from the implantation site. These results demonstrate that the mouse model could be useful for the primary in vivo evaluation of novel implant materials and that iron degradation products can accumulate in diverse organs of the body.

Development of a new procedure based on the energy charge measurement using ATP bioluminescence assay for the detection of living mould from graphic documents.

Fungal contamination is a major cause of deterioration in libraries and archives. Curators and conservators increasingly need rapid microbiological analyses. This paper presents a rapid detection method for the fungal contaminants on documents. A previous study showed that the calculation of energy charge, using bioluminescence ATP assays, provides a useful indicator to determinate the viability of fungal strains. We argue that this sensitive and time-saving method is better than traditional culture techniques. However, the procedure needs to be modified to make it usable for lay persons. An improved and simplified protocol is proposed here for the extraction of adenylate nucleotides (AN) from fungal spores and for their measurements. Our new procedure can detect the existence of viable fungal strains on documents, presenting suspect spots within minutes. The extraction is performed by filtration with DMSO-TE solution as extractant. The different step of the measurement of AN content is carried out successively in a single test tube instead of the three tubes necessary in the initial method. The new procedure was tested on 12 strains among those most frequently found in archives and libraries and validated on swab samples from real documents.