Candida glabrata persistence in mice does not depend on host immunosuppression and is unaffected by fungal amino acid auxotrophy.

Candida glabrata has emerged as an important fungal pathogen of humans, causing life-threatening infections in immunocompromised patients. In contrast, mice do not develop disease upon systemic challenge, even with high infection doses. In this study we show that leukopenia, but not treatment with corticosteroids, leads to fungal burdens that are transiently increased over those in immunocompetent mice. However, even immunocompetent mice were not capable of clearing infections within 4 weeks. Tissue damage and immune responses to microabscesses were mild as monitored by clinical parameters, including blood enzyme levels, histology, myeloperoxidase, and cytokine levels. Furthermore, we investigated the suitability of amino acid auxotrophic C. glabrata strains for in vitro and in vivo studies of fitness and/or virulence. Histidine, leucine, or tryptophan auxotrophy, as well as a combination of these auxotrophies, did not influence in vitro growth in rich medium. The survival of all auxotrophic strains in immunocompetent mice was similar to that of the parental wild-type strain during the first week of infection and was only mildly reduced 4 weeks after infection, suggesting that C. glabrata is capable of utilizing a broad range of host-derived nutrients during infection. These data suggest that C. glabrata histidine, leucine, or tryptophan auxotrophic strains are suitable for the generation of knockout mutants for in vivo studies. Notably, our work indicates that C. glabrata has successfully developed immune evasion strategies enabling it to survive, disseminate, and persist within mammalian hosts.

Sec12p-dependent membrane binding of the small GTP-binding protein Sar1p promotes formation of transport vesicles from the ER.

Sec12p is an integral membrane protein required in vivo and in vitro for the formation of transport vesicles generated from the ER. Vesicle budding and protein transport from ER membranes containing normal levels of Sec12p is inhibited in vitro by addition of microsomes isolated from a Sec12p-overproducing strain. Inhibition is attributable to titration of a limiting cytosolic protein. This limitation is overcome by addition of a highly enriched fraction of soluble Sar1p, a small GTP-binding protein, shown previously to be essential for protein transport from the ER and whose gene has been shown to interact genetically with sec12. Furthermore, Sar1p binding to isolated membranes is enhanced at elevated levels of Sec12p. Sar1p-Sec12p interaction may regulate the initiation of vesicle budding from the ER.

Structural and functional dissection of a membrane glycoprotein required for vesicle budding from the endoplasmic reticulum.

Sec12p is a membrane glycoprotein required for the formation of a vesicular intermediate in protein transport from the endoplasmic reticulum to the Golgi apparatus in Saccharomyces cerevisiae. Comparison of the N-linked glycosylation of Sec12p, a Sec12p-invertase hybrid protein, and a derivative of Sec12p lacking 71 carboxy-terminal amino acids showed that Sec12p is a type II membrane protein. Analysis of two truncated forms of Sec12p and of a temperature-sensitive mutant indicated that the C-terminal domain of Sec12p is not essential for protein transport, whereas the integrity and membrane attachment of the cytoplasmic N-terminal domain are essential. Expression of a soluble cytoplasmic domain dramatically inhibited the growth of a sec12 temperature-sensitive strain by increasing the transport defect at a normally permissive temperature. This growth inhibition as well as the sec12 temperature-sensitive defect were suppressed by the overproduction of Sar1p, a small GTP-binding protein that participates in protein transport. Sar1p membrane association was enhanced by elevated levels of Sec12p. These results suggest that the cytoplasmic domain of Sec12p interacts with Sar1p and that the complex may function to promote vesicle formation.

CandidaDB: a genome database for Candida albicans pathogenomics.

CandidaDB is a database dedicated to the genome of the most prevalent systemic fungal pathogen of humans, Candida albicans. CandidaDB is based on an annotation of the Stanford Genome Technology Center C.albicans genome sequence data by the European Galar Fungail Consortium. CandidaDB Release 2.0 (June 2004) contains information pertaining to Assembly 19 of the genome of C.albicans strain SC5314. The current release contains 6244 annotated entries corresponding to 130 tRNA genes and 5917 protein-coding genes. For these, it provides tentative functional assignments along with numerous pre-run analyses that can assist the researcher in the evaluation of gene function for the purpose of specific or large-scale analysis. CandidaDB is based on GenoList, a generic relational data schema and a World Wide Web interface that has been adapted to the handling of eukaryotic genomes. The interface allows users to browse easily through genome data and retrieve information. CandidaDB also provides more elaborate tools, such as pattern searching, that are tightly connected to the overall browsing system. As the C.albicans genome is diploid and still incompletely assembled, CandidaDB provides tools to browse the genome by individual supercontigs and to examine information about allelic sequences obtained from complementary contigs. CandidaDB is accessible at http://genolist.pasteur.fr/CandidaDB.

The intraspecies diversity of C. albicans triggers qualitatively and temporally distinct host responses that determine the balance between commensalism and pathogenicity.

The host immune status is critical for preventing opportunistic infections with Candida albicans. Whether the natural fungal diversity that exists between C. albicans isolates also influences disease development remains unclear. Here, we used an experimental model of oral infection to probe the host response to diverse C. albicans isolates in vivo and found dramatic differences in their ability to persist in the oral mucosa, which inversely correlated with the degree and kinetics of immune activation in the host. Strikingly, the requirement of interleukin (IL)-17 signaling for fungal control was conserved between isolates, including isolates with delayed induction of IL-17. This underscores the relevance of IL-17 immunity in mucosal defense against C. albicans. In contrast, the accumulation of neutrophils and induction of inflammation in the infected tissue was strictly strain dependent. The dichotomy of the inflammatory neutrophil response was linked to the capacity of fungal strains to cause cellular damage and release of alarmins from the epithelium. The epithelium thus translates differences in the fungus into qualitatively distinct host responses. Altogether, this study provides a comprehensive understanding of the antifungal response in the oral mucosa and demonstrates the relevance of evaluating intraspecies differences for the outcome of fungal-host interactions in vivo.

A rapid method for efficient gene replacement in the filamentous fungus Aspergillus nidulans.

The construction of mutant fungal strains is often limited by the poor efficiency of homologous recombination in these organisms. Higher recombination efficiencies can be obtained by increasing the length of homologous DNA flanking the transformation marker, although this is a tedious process when standard molecular biology techniques are used for the construction of gene replacement cassettes. Here, we present a two-step technology which takes advantage of an Escherichia coli strain expressing the phage lambda Red(gam, bet, exo) functions and involves (i) the construction in this strain of a recombinant cosmid by in vivo recombination between a cosmid carrying a genomic region of interest and a PCR-generated transformation marker flanked by 50 bp regions of homology with the target DNA and (ii) genetic exchange in the fungus itself between the chromosomal locus and the circular or linearized recombinant cosmid. This strategy enables the rapid establishment of mutant strains carrying gene knock-outs with efficiencies >50%. It should also be appropriate for the construction of fungal strains with gene fusions or promoter replacements.

Multilocus sequence typing reveals intrafamilial transmission and microevolutions of Candida albicans isolates from the human digestive tract.

Candida albicans is a human commensal that is also responsible for superficial and systemic infections. Little is known about the carriage of C. albicans in the digestive tract and the genome dynamics that occur during commensalisms of this diploid species. The aim of this study was to evaluate the prevalence, diversity, and genetic relationships among C. albicans isolates recovered during natural colonization of the digestive tract of humans, with emphasis on Crohn's disease patients who produce anti-yeast antibodies and may have altered Candida sp. carriage. Candida sp. isolates were recovered from 234 subjects within 25 families with multiple cases of Crohn's disease and 10 control families, sampled at the oral and fecal sites. Prevalences of Candida sp. and C. albicans carriage were 53.4% and 46.5%, respectively, indicating frequent commensal carriage. No differences in prevalence of carriage could be observed between Crohn's disease patients and healthy subjects. Multilocus sequence typing (MLST) of C. albicans isolates revealed frequent colonization of a subject or several members of the same family by genetically indistinguishable or genetically close isolates. These latter isolates differed by loss-of-heterozygosity events at one or several of the MLST loci. These loss-of-heterozygosity events could be due to either chromosome loss followed by duplication or large mitotic recombination events between complementary chromosomes. This study was the first to jointly assess commensal carriage of C. albicans, intrafamilial transmission, and microevolution. The high frequency of each of these events suggests that the digestive tract provides an important and natural niche for microevolutions of diploid C. albicans through the loss of heterozygosity.

Selection of multiple disruption events in Aspergillus fumigatus using the orotidine-5'-decarboxylase gene, pyrG, as a unique transformation marker.

A 8.6-kb disruption cassette, referred to here as a pyrG-blaster and consisting of the Aspergillus niger pyrG gene flanked by a direct repeat that encodes the neomycin phosphotransferase of transposon Tn5 was constructed. Following transformation of a uridine/uracil auxotrophic pyrG strain of A. fumigatus, genomic insertions of the pyrG-blaster were obtained either by targeted gene replacement at the rodA locus, resulting in the formation of hydrophilic spores, or by ectopic integration. In both cases, recombination between the two elements of the direct repeat could be selected in the presence of 5-fluoro-orotic acid and resulted in the excision of the A. niger pyrG gene, producing A. fumigatus uridine/uracil auxotrophs that retained their additional mutant phenotype because of the persistence of one of the two elements of the direct repeat at the site of insertion of the pyrG-blaster. Selection for uracil/uridine prototrophy can therefore be used again to disrupt another gene.

A gene fusion approach to the study of pullulanase export and secretion in Escherichia coli.

A series of fusions between the gene for the Klebsiella pneumoniae secreted lipoprotein pullulanase (pulA) and the genes for cytoplasmic beta-galactosidase (lacZ) or periplasmic alkaline phosphatase (phoA) were created by transposon mutagenesis using mini-MudII1681 or TnphoA, respectively. The hybrid genes were expressed in Escherichia coli K-12 with or without the K. pneumoniae genes that promote pullulanase secretion in E. coli. We characterized seven different pulA-lacZ gene fusions encoding hybrid polypeptides containing from 14 to c. 1060 residues of pro-pullulanase. All but the smallest hybrid were fatty acylated and were toxic to producing cells, causing the accumulation of precursors of other exported proteins. Four different pulA-phoA gene fusions encoded hybrids with alkaline phosphatase activity. All four hybrids were fatty acylated, but were not toxic. Although the hybrids were apparently membrane-associated, they were not secreted into the medium either by E. coli carrying pullulanase secretion genes or by K. pneumoniae. Immunofluorescence tests indicated that the pullulanase secretion genes promoted the localization of one of these hybrids to the outer face of the E. coli outer membrane, which may have important implications for the design of live vaccine strains and of immobilized enzymes.

Klebsiella pneumoniae pulS gene encodes an outer membrane lipoprotein required for pullulanase secretion.

The product of the Klebsiella pneumoniae gene pulS, which is located downstream from the pullulanase structural gene (pulA), is essential for the cell surface localization and extracellular release of pullulanase in Escherichia coli K-12. pulS is transcribed in the opposite direction to pulA, from which it is separated by a region of 624 nucleotides. Although this latter region contains a new component of the maltose regulon, pulB, which is transcribed from the pulA promoter, it is not required for pullulanase synthesis or secretion. Unlike pulA and all other pullulanase secretion genes characterized so far, the expression of pulS is not induced by growth in the presence of maltose and is unaffected by mutations in the maltose regulator gene malT. The pulS gene product was identified as a ca. 12-kilodalton outer membrane lipoprotein. The characterization of PulS brings to three the number of identified proteins which are known to be required for pullulanase secretion in addition to the components of the signal sequence-dependent general protein export pathway.

Molecular characterization of the Aspergillus nidulans treA gene encoding an acid trehalase required for growth on trehalose.

Aspergillus nidulans conidiospores contain high levels of the non-reducing disaccharide trehalose. We show that upon induction of conidiospore germination, the trehalose pool is rapidly degraded and a glycerol pool is transiently accumulated. A trehalase with an acidic pH optimum was purified from conidiospores. Characterization of the treA gene encoding this trehalase shows that it is homologous to Saccharomyces cerevisiae vacuolar acid trehalase, the product of the ATH1 gene, and to two related proteins of unknown function identified in Mycobacterium tuberculosis and Mycobacterium leprae. A. nidulans mutants that lack acid trehalase activity were constructed by gene replacement at the treA locus. Analysis of these mutants suggests that the treA gene product is localized in the conidiospore wall, is required for growth on trehalose as a carbon source, and is not involved in the mobilization of the intracellular pool of trehalose. Therefore, it is proposed that a cytoplasmic regulatory trehalase is controlling this latter process.

Export and secretion of the lipoprotein pullulanase by Klebsiella pneumoniae.

Pullulanase, a secreted lipoprotein of Klebsiella pneumoniae, is initially localized to the outer face of the outer membrane, as shown by protease and substrate accessibility and by immunofluorescence tests. Freeze-thaw disruption of these cells released both membrane-associated and apparently soluble forms of pullulanase. Membrane-associated pullulanase co-fractionated with authentic outer membrane vesicles upon isopycnic sucrose-gradient centrifugation, whereas the quasi-soluble form had the same equilibrium density as inner membrane vesicles and extracellular pullulanase aggregates. The latter also contained outer membrane maltoporin, but were largely devoid of other membrane components including LPS and lipids. K. pneumoniae carrying multiple copies of the pullulanase structural gene (pulA) produced increased amounts of cell-associated and secreted pullulanase, but a large proportion of the enzyme was neither exposed on the cell surface nor released into the medium, even after prolonged incubation. This suggests that factors necessary for pullulanase secretion were saturated by the over-produced pullulanase. When pulA was expressed under lacZ promotor control, the pullulanase which was produced was not exposed on the cell surface at any time, suggesting that pullulanase secretion genes are not expressed constitutively, and raising the possibility that they, like pulA, may be part of the maltose regulon.

Purification and characterization of SAR1p, a small GTP-binding protein required for transport vesicle formation from the endoplasmic reticulum.

SEC12 encodes an integral membrane glycoprotein essential for vesicle formation from the endoplasmic reticulum (ER) in yeast. The SAR1 gene was discovered as a multicopy suppressor of a sec12ts strain and encodes a 21-kDa GTP-binding protein also required for protein transport from the ER to the Golgi apparatus (Nakano, A., and Muramatsu, M. (1989) J. Cell Biol. 109, 2677-2691). We have purified Sar1p to apparent homogeneity from cells harboring a galactose-regulated recombinant SAR1. Purified Sar1p binds guanine nucleotides specifically and exhibits GTPase activity (0.001 min-1). Nucleotide exchange and hydrolysis rates are greatly increased in the presence of Mg2+ and nonionic detergents or phospholipids. An assay that measures the formation of a vesicle intermediate in ER to Golgi transport was devised that is dependent on the addition of purified Sar1p. This assay employs membranes prepared from wild-type cells and cytosol fractions depleted of Sar1p due to overproduction of Sec12p or by gel filtration chromatography. The gel-filtered cytosol requires the addition of Sar1p and GTP to support vesicle budding. Sar1p prebound with GTP gamma S inhibits Sar1p function in the vesicle formation assay. The results indicate a role for Sar1p in vesicle budding from the ER and suggest that GTP hydrolysis by Sar1p is required for this event.

Fission yeast and a plant have functional homologues of the Sar1 and Sec12 proteins involved in ER to Golgi traffic in budding yeast.

Sec12p and Sar1p are required for the formation of transport vesicles generated from the endoplasmic reticulum (ER) in the yeast Saccharomyces cerevisiae. Sec12p is an ER type II membrane protein that mediates the membrane attachment of the GTP-binding Sar1 protein. The SAR1 gene is a multi-copy suppressor of a thermosensitive sec12 mutation. In an attempt to identify functional homologues of Sec12p and Sar1p from other eukaryotic organisms, we screened cDNA expression libraries derived from the fission yeast Schizosaccharomyces pombe and from the plant Arabidopsis thaliana for complementation of the sec12ts mutation. Four individual cDNAs were isolated, two of which encode the S. pombe and A. thaliana homologues of Sar1p. The three Sar1 proteins are 67% identical on average. The two other cDNAs encode type II membrane proteins which were designated Stl1p for the S. pombe protein and Stl2p for the A. thaliana protein (Stl stands for Sec12p-like). Both proteins have NH2-terminal cytoplasmic domains which resemble that of Sec12p: they are similar in size and present a significant degree of amino acid identity with the cytoplasmic domain of Sec12p. In contrast, the lumenal domains of Sec12p, Stl1p and Stl2p are very different in size and do not show any appreciable homology. That Stl1p and Stl2p are functional homologues of Sec12p was confirmed by showing that expression of either cloned gene complements a sec12 null mutation. Our results indicate that some of the mechanisms regulating vesicle formation at the ER are conserved not only in yeasts, but also in plants.

Cloning and expression in Escherichia coli of the Klebsiella pneumoniae genes for production, surface localization and secretion of the lipoprotein pullulanase.

This article describes the reconstitution in Escherichia coli of a heterologous protein secretion system comprising a gene for an extracellular protein together with its cognate secretion genes. The protein concerned, pullulanase, is a secreted lipoprotein of the Gram-negative bacterium Klebsiella pneumoniae. It is initially localized to the cell surface before being specifically released into the medium. E. coli carrying the cloned pullulanase structural gene (pulA) produces pullulanase but does not expose or secrete it. Secretion genes were cloned together with pulA in an 18.8 kbp fragment of K. pneumoniae chromosomal DNA. E. coli carrying this fragment exhibited maltose-inducible production, exposition and specific secretion of pullulanase. Transposon mutagenesis showed that the secretion genes are located on both sides of pulA. Secretion genes located 5' to pulA were transcribed in the opposite orientation to pulA under the control of the previously identified, malT-regulated malX promoter. Thus these secretion genes are part of the maltose regulon and are therefore co-expressed with pulA. Transposon mutagenesis suggested that secretion genes located 3' of pulA are not co-transcribed with pulA, raising the possibility that some secretion functions are not maltose regulated.

Usefulness of multilocus sequence typing for characterization of clinical isolates of Candida albicans.

Molecular characterization of Candida albicans isolates is essential for understanding the epidemiology of nosocomial infections caused by this yeast. Here, we investigated the potential value of multilocus sequence typing (MLST) for characterizing epidemiologically related or unrelated C. albicans strains of various clinical origins. Accordingly, we sequenced the internal regions (loci) of six selected housekeeping genes of 40 C. albicans clinical isolates and 2 reference strains. In all, 68 polymorphic nucleotide sites were identified, of which 65 were found to be heterozygous in at least one isolate. Ten to 24 different genotypes were observed at the different loci, resulting, when combined, in 39 unique genotype combinations or diploid sequence types (DSTs). When MLST was applied to 26 epidemiologically unrelated isolates and the 2 reference strains, it allowed the identification of 27 independent DSTs, thus demonstrating a discriminatory power of 99.7. Using multidimensional scaling together with the minimum spanning tree method to analyze interstrain relationships, we identified six groups of genetically related isolates on the basis of bootstrap values of greater than 900. Application of MLST to 14 epidemiologically related isolates showed that those recovered from patients in the same hospital ward during the same 3 months had specific DSTs, although 73% of these isolates were genetically very close. This suggests that MLST can trace minute variations in the sequences of related isolates. Overall, MLST proved to be a highly discriminatory and stable method for unambiguous characterization of C. albicans.

Pullulanase secretion in Escherichia coli K-12 requires a cytoplasmic protein and a putative polytopic cytoplasmic membrane protein.

The previously uncharacterized third and fourth genes (pulE and pulF) of the pullulanase secretion gene operon of Klebsiella oxytoca strain UNF5023 are, respectively, predicted to encode a 55 kDa polypeptide with a putative nucleotide-binding site, and a highly hydrophobic 44 kDa polypeptide that probably spans the cytoplasmic membrane several times. Expression of pulE in minicells or under the control of a strong bacteriophage T7 promoter resulted in the production of a c. 58 kDa cytoplasmic protein. A representative PulE-beta-galactosidase hybrid protein created by Tnlac mutagenesis was also found mainly in the cytoplasm. These results are in line with the predicted absence from PulE of a region of sufficient hydrophobicity to function as a signal sequence. The PulF polypeptide could not be detected either in minicells or when the gene was transcribed from the T7 promoter, but the acquirement of three pulF-lacZ gene fusions that encoded hybrid proteins with relatively high levels of beta-galactosidase activity indicates that this gene can be transcribed and translated. Gene disruption experiments indicated that both pulE and pulF are required for pullulanase secretion in Escherichia coli K-12. Both proteins exhibit considerable homology throughout their entire lengths with other proteins involved in protein secretion, pilin assembly, conjugation and transformation competence in a variety of bacteria. In addition, PulE protein has consensus sequences found in a wide variety of nucleotide-binding proteins. This study completes the initial characterization of the pullulanase secretion gene operon, which comprises 13 genes that are all essential for the transport of pullulanase across the outer membrane.

Protein secretion by gram-negative bacteria. Characterization of two membrane proteins required for pullulanase secretion by Escherichia coli K-12.

Pullulanase secretion in Escherichia coli depends on the expression of a MalT-regulated operon called pulC. Characterization of the first two genes of this operon showed that they encode, respectively, a 31,000-Da protein (PulC) and a 70,600-Da protein (PulD) which has a putative signal peptide and that these two proteins are required for pullulanase secretion. The analysis of alkaline phosphatase hybrid proteins generated by TnphoA mutagenesis of pulC and pulD showed that both PulC and PulD contain export signals which can direct the alkaline phosphatase segment of the hybrids across the inner membrane. A representative PulC-PhoA hybrid protein fractionated mainly with the inner membrane upon isopycnic sucrose gradient centrifugation of membrane vesicles. This, together with sequencing data, suggests that PulC is an inner membrane protein. Antibodies raised against a purified PulD-PhoA hybrid protein were used to show that PulD was enriched in low density outer membrane vesicles.