Real-time monitoring of the spatial and temporal progression of infection/gene expression in animals will contribute greatly to our understanding of host-pathogen interactions while reducing the number of animals required to generate statistically significant data sets. Sensitive in vivo imaging technologies can detect low levels of light emitted from luciferase reporters in vivo, but the existing reporters are not optimal for fungal infections. Therefore, our aim was to develop a novel reporter system for imaging Candida albicans infections that overcomes the limitations of current luciferase reporters for this major fungal pathogen. This luciferase reporter was constructed by fusing a synthetic, codon-optimized version of the Gaussia princeps luciferase gene to C. albicans PGA59, which encodes a glycosylphosphatidylinositol-linked cell wall protein. Luciferase expressed from this PGA59-gLUC fusion (referred to as gLUC59) was localized at the C. albicans cell surface, allowing the detection of luciferase in intact cells. The analysis of fusions to strong (ACT1 and EFT3), oxidative stress-induced (TRX1, TRR1, and IPF9996), and morphogenesis-dependent (HWP1) promoters confirmed that gLUC59 is a convenient and sensitive reporter for studies of gene regulation in yeast or hyphal cells, as well as a flexible screening tool. Moreover, the ACT1-gLUC59 fusion represented a powerful tool for the imaging of disease progression in superficial and subcutaneous C. albicans infections. gLUC59 and related cell surfaceexposed luciferase reporters might find wide applications in molecular biology, cell biology, pathobiology, and high-throughput screens.Candida albicans is responsible for a large fraction of fungal infections in humans (5) and, as such, has received considerable attention from the research community over the last two decades. C. albicans now represents an invaluable model for dissecting the interplay between fungal pathogens and their hosts at the molecular level (31,32,43,45,50). Studies of host-pathogen interactions have been greatly facilitated by the use of ex vivo infection models where isolated microorganisms and host cells or reconstituted tissues are brought into contact and the kinetics of pathogen and host cell responses are monitored (12,14,23,36,45). Yet, animal models remain necessary complements to ex vivo infection models, because none of these models fully reflect the development of clinical infections. Animal models allow researchers to monitor the behavior of mutant microorganisms or the expression of reporter genes in the complex environments of organs and in the presence of a fully functional or debilitated immune system (3,20,24).A current limitation of animal models is the need to sacrifice animals in order to image microorganisms at the site of infection. In particular, studies aimed at evaluating whether conditions known to trigger the expression of a specific C. albicans gene in vitro are encountered at sites of infection have often relied on the detection of a reporter in tissue section...
