Hironobu Nakayama

Development of a Highly Efficient Gene Targeting System Induced by Transient Repression of YKU80 Expression in Candida glabrata

ABSTRACT In the pathogenic yeast Candida glabrata, gene targeting to generate knockouts and “knockins” is a potentially powerful method for the analysis of gene function. Its importance increased after the C. glabrata genome sequence project, but progress in the field is hampered by inefficient mechanisms for gene targeting. With the use of 40-bp homologous flanking DNA, no gene targeting was identified. To address this issue, YKU80 was disrupted, leading to an increase in targeting efficiency of 5.1% using 40-bp flanking homologous DNA. To harness the beneficial effects of YKU80 inactivation on gene targeting frequency without incurring any negative effects, such as synthetic sickness or lethality, we developed a new system whereby the expression of YKU80 was restored following a transient knockdown of expression during transformation. Strains used for this new system carried a SAT1 flipper in the YKU80 promoter region, which was used to repress expression during transformation but was spontaneously excised from the locus after the transformation. By using this strain, DNA damage induced by methyl methane sulfonate, H2O2, UV irradiation, and hydroxyurea before and during gene targeting was evaluated and the mutation rate of URA3 was determined. No significant effects of the SAT1 flipper on these processes have been identified. After the SAT1 flipper is excised, a 34-bp FLP recombination target sequence is left in the promoter region. However, the levels of mRNA transcription were restored and no difference in the survival ratio in vivo compared to that with the YKU80 wild-type strain was identified.

Transcription factors CgUPC2A and CgUPC2B regulate ergosterol biosynthetic genes in Candida glabrata

Zn[2]‐Cys[6] binuclear transcription factors Upc2p and Ecm22p regulate the expression of genes involved in ergosterol biosynthesis and exogenous sterol uptake in Saccharomyces cerevisiae. We identified two UPC2/ECM22 homologues in the pathogenic fungus Candida glabrata which we designated CgUPC2A and CgUPC2B. The contribution of these two genes to sterol homeostasis was investigated. Cells that lack CgUPC2A (upc2AΔ) exhibited enhanced susceptibility to the sterol biosynthesis inhibitors, fluconazole and lovastatin, whereas upc2BΔ‐mutant cells were as susceptible to the drugs as wild‐type cells. The growth of upc2AΔ cells was also severely attenuated under anaerobic conditions. Lovastatin treatment enhanced the expression of ergosterol biosynthetic genes, ERG2 and ERG3 in wild‐type and upc2BΔ but not in upc2AΔ cells. Similarly, serum‐induced expression of ERG2 and ERG3 was completely impaired in upc2AΔ cells but was unaffected in upc2BΔ cells, whereas serum‐induced expression of the sterol transporter gene CgAUS1 was impaired in both upc2AΔ and upc2BΔ cells. These results suggest that in C. glabrata CgUPC2A but not in CgUPC2B is the main transcriptional regulator of the genes responsible for maintaining sterol homeostasis as well as susceptibility to sterol inhibitors.

Candida glabrata drug:H+ antiporter CgTpo3 (ORF CAGL0I10384g): role in azole drug resistance and polyamine homeostasis

OBJECTIVES The ability of opportunistic pathogenic Candida species to persist and invade specific niches in the human host depends on their resistance to natural growth inhibitors and antifungal therapy. This work describes the role of the Candida glabrata drug:H(+) antiporter CgTpo3 (ORF CAGL0I10384g) in this context. METHODS Deletion and cloning of CgTPO3 was achieved using molecular biology tools. C. glabrata strain susceptibility was assayed based on growth in liquid and solid media and through MIC determination. Radiolabelled compound accumulation or HPLC were used for the assessment of the role of CgTpo3 as a drug or polyamine transporter. Quantitative RT-PCR was used for expression analysis. RESULTS CgTpo3 was found to confer resistance to azole drugs in C. glabrata. This protein was found to be localized to the plasma membrane and to decrease the intracellular accumulation of [(3)H]clotrimazole, playing a direct role in its extrusion from pre-loaded C. glabrata cells. CgTPO3 was further found to confer resistance to spermine, complementing the susceptibility phenotypes exhibited by the deletion of its Saccharomyces cerevisiae homologue, TPO3. In spermine-stressed C. glabrata cells, CgTPO3 is transcriptionally activated in a CgPdr1-dependent manner, contributing to a decrease in the intracellular concentration of this polyamine. Clotrimazole exposure was found to lead to the intracellular accumulation of spermine, and pre-exposure to this polyamine was found consistently to lead to increased clotrimazole resistance. CONCLUSIONS Altogether, these results point to a significant role for CgTpo3 in azole drug resistance and in the tolerance to high polyamine concentrations, such as those found in the urogenital tract.

The Candida glabrata sterol scavenging mechanism, mediated by the ATP‐binding cassette transporter Aus1p, is regulated by iron limitation

During disseminated infection by the opportunistic pathogen Candida glabrata, uptake of sterols such as serum cholesterol may play a significant role during pathogenesis. The ATP‐binding cassette transporter Aus1p is thought to function as a sterol importer and in this study, we show that uptake of exogenous sterols occurred under anaerobic conditions in wild‐type cells of C. glabrata but not in AUS1‐deleted mutant (aus1Δ) cells. In aerobic cultures, growth inhibition by fluconazole was prevented in the presence of serum, and AUS1 expression was upregulated. Uptake of sterol by azole treated cells required the presence of serum, and sterol alone did not reverse FLC inhibition of growth. However, if iron availability in the growth medium was limited by addition of the iron chelators ferrozine or apo‐transferrin, growth of wild‐type cells, but not aus1Δ cells, was rescued. In a mouse model of disseminated infection, the C. glabrata aus1Δ strain caused a significantly decreased kidney fungal burden than the wild‐type strain or a strain in which AUS1 was restored. We conclude that sterol uptake in C. glabrata can occur in iron poor environment of host tissues and thus may contribute to C. glabrata pathogenesis.

Growth defects resulting from inhibiting ERG20 and RAM2 in Candida glabrata

Farnesyl pyrophosphate (FPP) is utilized for many cellular processes, including the production of dolichols, ubiquinone (CoQ), sterols, farnesylated heme A and prenylated proteins. This lipid synthesized by FPP synthetase (ERG20) becomes attached to target proteins by the prenyltransferases, CDC43/RAM2 and RAM1/RAM2 complexes after the formation of the C15 and C20 units, respectively. Defects in protein prenylation as a result of inhibiting these enzyme complexes lead to pleiotropic effects in all eukaryotes. In this study, using Candida glabrata conditional mutants, the importance of the ERG20 and RAM2 genes for growth using both in vivo and in vitro assays was assessed by placing the RAM2 and ERG20 genes under the control of a regulatable promoter. Repression of RAM2 gene expression revealed growth defects under both conditions. However, repression of ERG20 gene expression did not impair fungal growth in a mouse host, but did result in growth defects on laboratory media. Thus, FPP synthase is not required for survival in an infected mouse, but the RAM2-encoded prenyltransferase was critical for growth under both conditions. This study strongly suggests that inhibitors of prenyltransferase may be promising antifungals.

Reconstitution of high-level micafungin resistance detected in a clinical isolate of Candida glabrata identifies functional homozygosity in glucan synthase gene expression

OBJECTIVES A mechanism for the acquisition of high-level echinocandin resistance in Candida glabrata was investigated. FKS mutants were constructed to: determine whether clinically significant micafungin resistance requires a hot-spot mutation in FKS1 and a premature stop codon in FKS2, as was observed in a clinical isolate; select for variants with reduced susceptibility and locate mutations in FKS genes; and assess the roles of FKS1 and FKS2. METHODS A panel of FKS mutants was constructed using micafungin-susceptible parents by site-directed mutagenesis. Drug susceptibility, gene expression and glucan synthase activities were compared between mutants. Mutations acquired by selection were identified by DNA sequence analysis of FKS genes from selected variants. Single FKS deletants were constructed and their phenotypes examined. RESULTS Introduction of the hot-spot mutation in FKS1 alone conferred an intermediate reduction in susceptibility, and the premature stop codon in FKS2 alone had no effect on susceptibility, while severely reduced susceptibility equivalent to that of the clinical isolate required both mutations. Exposure of susceptible strains to micafungin yielded variants with an intermediate reduction in susceptibility that possessed a hot-spot mutation in FKS1. Further exposure to micafungin yielded variants with severely reduced susceptibility that acquired various single mutations in FKS2. The phenotypes of Δfks1 and Δfks2 mutants indicate that the two FKS genes are functionally redundant, while deletion of both FKS1 and FKS2 conferred synthetic lethality. CONCLUSIONS In the laboratory mutants of C. glabrata, clinically significant reduced susceptibility to micafungin required single nucleotide changes in both FKS1 and FKS2, and both genes encoded β-1,3-glucan synthase catalytic subunits.

Iron-depletion promotes mitophagy to maintain mitochondrial integrity in pathogenic yeast Candida glabrata

ABSTRACT Candida glabrata, a haploid budding yeast, is the cause of severe systemic infections in immune-compromised hosts. The amount of free iron supplied to C. glabrata cells during systemic infections is severely limited by iron-chelating proteins such as transferrin. Thus, the iron-deficiency response in C. glabrata cells is thought to play important roles in their survival inside the hosts body. In this study, we found that mitophagy was induced under iron-depleted conditions, and that the disruption of a gene homologous to ATG32, which is responsible for mitophagy in Saccharomyces cerevisiae, blocked mitophagy in C. glabrata. The mitophagic activity in C. glabrata cells was not detected on short-period exposure to nitrogen-starved conditions, which is a mitophagy-inducing condition used in S. cerevisiae. The mitophagy-deficient atg32Δ mutant of C. glabrata also exhibited decreased longevity under iron-deficient conditions. The mitochondrial membrane potential in Cgatg32Δ cells was significantly lower than that in wild-type cells under iron-depleted conditions. In a mouse model of disseminated infection, the Cgatg32Δ strain resulted in significantly decreased kidney and spleen fungal burdens compared with the wild-type strain. These results indicate that mitophagy in C. glabrata occurs in an iron-poor host tissue environment, and it may contribute to the longevity of cells, mitochondrial quality control, and pathogenesis.

Genome‐wide survey of transcriptional initiation in the pathogenic fungus, Candida glabrata

DNA sequencing of the 5′‐flanking region of the transcriptome effectively identifies transcription initiation sites and also aids in identifying unknown genes. This study describes a comprehensive polling of transcription start sites and an analysis of full‐length complementary DNAs derived from the genome of the pathogenic fungus Candida glabrata. A comparison of the sequence reads derived from a cDNA library prepared from cells grown under different culture conditions against the reference genomic sequence of the Candida Genome Database (CGD: http://www.candidagenome.org/) revealed the expression of 4316 genes and their acknowledged transcription start sites (TSSs). In addition this analysis also predicted 59 new genes including 22 that showed no homology to the genome of Saccharomyces cerevisiae, a genetically close relative of C. glabrata. Furthermore, comparison of the 5′‐untranslated regions (5′‐UTRs) and core promoters of C. glabrata to those of S. cerevisiae showed various global similarities and differences among orthologous genes. Thus, the C. glabrata transcriptome can complement the annotation of the genome database and should provide new insights into the organization, regulation, and function of genes of this important human pathogen.

Serum cholesterol promotes the growth of Candida glabrata in the presence of fluconazole

The pathogenic fungus Candida glabrata is thought to utilize extracellular sterols during infection, but there have been few reports on the sterol uptake mechanisms of this fungus. The addition of serum promoted the growth of C. glabrata cells in the presence of the sterol inhibitor fluconazole, probably as the result of incorporation of cholesterol from serum. We demonstrated that lipoprotein-deficient serum, in which most of the cholesterol was eliminated, could not rescue the growth of fluconazole-treated C. glabrata cells, but it successfully promoted the expression of the sterol transporter gene AUS1. After supplementation of free cholesterol to lipoprotein-deficient serum, the serum was again competent to promote the growth of fluconazole-treated C. glabrata. The serum-mediated growth rescue from fluconazole inhibition was observed in the nonpathogenic yeast Saccharomyces cerevisiae when it was followed by the activation of anaerobic sterol uptake. These results suggested that serum cholesterol was incorporated into yeast cells to compensate for sterol depletion when sterol uptake was activated. The uptake of serum cholesterol could support the growth of C. glabrata cells during bloodstream infections.

Neuronal differentiation of human iPS cells induced by baicalin via regulation of bHLH gene expression.

Efficient differentiation is important for regenerative medicine based on pluripotent stem cells, including treatment of neurodegenerative disorders and trauma. Baicalin promotes neuronal differentiation of neural stem/progenitor cells of rats and mice. To evaluate the suitability of baicalin for neuronal differentiation of human iPS cells, we investigated whether it promotes neuronal differentiation in human iPS cells and monitored basic helix-loop-helix (bHLH) gene expression during neuronal differentiation. Baicalin promoted neuronal differentiation and inhibited glial differentiation, suggesting that baicalin can influence the neuronal fate decision in human iPS cells. Notch signaling, which is upstream of bHLH proteins, was not involved in baicalin-induced neuronal differentiation. Baicalin treatment did not down-regulate Hes1 gene expression, but it reduced Hes1 protein levels and up-regulated Ascl1 gene expression. Thus, baicalin promoted neuronal differentiation via modulation of bHLH transcriptional factors. Therefore, baicalin has potential to be used as a small-molecule drug for regenerative treatment of neurodegenerative disorders.