Secreted aspartic proteases are not required for invasion of reconstituted human epithelia by Candida albicans

doi:10.1099/mic.0.2008/022525-0

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Secreted aspartic proteases are not required for invasion of reconstituted human epithelia by Candida albicans

Ulrich Lermann and Joachim Morschhäuser

Institut für Molekulare Infektionsbiologie, Universität Würzburg, Röntgenring 11, D-97070 Würzburg, Germany

Correspondence
Joachim Morschhäuser
joachim.morschhaeuser{at}mail.uni-wuerzburg.de

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
ADDENDUM
REFERENCES

A well-known virulence attribute of the human-pathogenic yeastCandida albicans is the secretion of aspartic proteases (Saps),which may contribute to colonization and infection of differenthost niches by degrading tissue barriers, destroying host defencemolecules, or digesting proteins for nutrient supply. The roleof individual Sap isoenzymes, which are encoded by a large genefamily, for the pathogenicity of C. albicans has been investigatedby assessing the virulence of mutants lacking specific SAP genesand by studying the expression pattern of the SAP genes in variousmodels of superficial and systemic infections. We used a recombination-basedgenetic reporter system to detect the induction of the SAP1–SAP6genes during infection of reconstituted human vaginal epithelium.Only SAP5, but none of the other tested SAP genes, was detectablyactivated in this in vitro infection model. To directly addressthe importance of the SAP1–SAP6 genes for invasion ofreconstituted human epithelia (RHE), we constructed a set ofmutants of the wild-type C. albicans model strain SC5314 inwhich either single or multiple SAP genes were specificallydeleted. Even mutants lacking all of the SAP1–SAP3 orthe SAP4–SAP6 genes displayed the same capacity to invadeand damage both oral and vaginal RHE as their wild-type parentalstrain, in contrast to a nonfilamentous efg1 ${Delta}$ mutant that wasavirulent under these conditions. We therefore conclude fromthese results that the secreted aspartic proteases Sap1p–Sap6pare not required for invasion of RHE by C. albicans.

Abbreviations: IVET, in vitro expression technology; LDH, lactate dehydrogenase; MPA, mycophenolic acid; RHE, reconstituted human epithelium/epithelia; Sap, secreted aspartic protease

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
ADDENDUM
REFERENCES

The yeast Candida albicans is a harmless commensal on mucosalsurfaces of the gastrointestinal and urogenital tract in mosthealthy people. However, especially in immunocompromised patients,C. albicans can also invade into the epithelium and cause superficialas well as life-threatening disseminated infections (Odds, 1988).The secretion of aspartic proteases has long been recognizedas a virulence-associated trait of this fungal pathogen (Kwon-Chunget al., 1985; Macdonald & Odds, 1983; Staib, 1969). C. albicanspossesses a gene family encoding secreted aspartic proteases(Saps), which are thought to have different roles during aninfection, e.g. the degradation of tissue barriers during invasion,destruction of host defence molecules, or nutrient supply (Nagliket al., 2003a). The importance of specific Sap isoenzymes forthe pathogenicity of C. albicans has been investigated by comparingthe virulence of mutants deleted for individual or multipleSAP genes with that of a wild-type control strain in differentinfection models. Especially the SAP1–SAP6 genes havebeen studied extensively. Initially it was demonstrated thatsap1 ${Delta}$ , sap2 ${Delta}$ and sap3 ${Delta}$ single mutants as well as triple mutantslacking the highly homologous SAP4–SAP6 genes exhibitedattenuated virulence after intravenous infection of mice, indicatingthat all these genes have important roles for the normal progressionof a systemic infection (Hube et al., 1997; Sanglard et al.,1997). Mutants deleted for either SAP1, SAP2 or SAP3 were alsofound to be less virulent in a rat model of Candida vaginitis,whereas mutants lacking SAP4–SAP6 did not exhibit a detectablevirulence defect under these conditions (De Bernardis et al.,1999). Conversely, only the latter mutants showed reduced virulencein a murine model of Candida peritonitis, while deletion ofSAP1, SAP2 or SAP3 had no significant effect in this infectionmodel (Kretschmar et al., 1999). These and other studies indicatethat the relative importance of specific SAP genes for the pathogenicityof C. albicans depends on the type of infection.

As the various Sap isoenzymes may have partially redundant functions,the analysis of deletion mutants might not reveal a role ofa particular SAP gene under all conditions. The individual membersof the SAP gene family are differentially expressed during invitro growth, depending on the cell type and the growth conditions(Hube et al., 1994; White & Agabian, 1995). For example,SAP2 is specifically induced in media containing proteins asthe sole nitrogen source and is required for growth of C. albicansunder these conditions. SAP1 and SAP3 are phase-specific genesand are specifically expressed in opaque cells, the mating-competentform of C. albicans, while expression of SAP4–SAP6 isusually stimulated under conditions that promote hyphal growth.Assuming that the expression of a specific SAP gene in a certaintissue reflects its role at that stage of an infection, variousinvestigators have studied the expression patterns of the SAPgenes in different types of infections. In an early study, expressionof SAP1 and SAP2 during experimental vaginitis in rats couldbe demonstrated by Northern hybridization analysis (De Bernardiset al., 1995). Expression of SAP1, SAP2 and SAP4–SAP6was detected by RT-PCR during invasion of parenchymal organsafter intraperitoneal infection of mice (Felk et al., 2002).In a mouse model of oroesophageal and gastric candidiasis, allSAP genes were detectably expressed during gastric candidiasis,while SAP1 and SAP3 were only sporadically and weakly expressedat different oral sites of infection (Schofield et al., 2003).Several investigators have also used RT-PCR to analyse the expressionof specific SAP genes during colonization and infection of humans.Schaller et al. (1998) detected SAP1–SAP3 and SAP6 transcriptsin samples from patients with oral candidiasis, whereas no expressionof SAP4 and SAP5 was found. In contrast, Naglik et al. (2003b)found SAP2 and SAP5 to be the most commonly expressed genesin individuals with oral and vaginal Candida carriage or infection,while SAP1 and SAP3 were preferentially expressed in vaginal,rather than oral, infections.

In vitro models using reconstituted human epithelia (RHE) havealso been used to evaluate the importance of specific Sap isoenzymesfor tissue invasion and to investigate the expression patternsof individual SAP genes. On oral RHE, expression of SAP1–SAP3and SAP6, but not SAP4 and SAP5, was detected by RT-PCR andeach of the SAP1–SAP3 genes was also found to be requiredfor wild-type levels of tissue damage in this model (Schalleret al., 1998, 1999). SAP1 and SAP2, but not SAP3–SAP6,were also required for tissue damage during infection of vaginalRHE, although RT-PCR showed almost all of these SAP genes tobe expressed under these conditions (Schaller et al., 2003).A role of the Saps during infection of RHE was also demonstratedby the observation that the extent of tissue damage caused bythe wild-type strain SC5314 was reduced in the presence of asparticprotease inhibitors (Schaller et al., 1999, 2003).

While all of the above studies point to a differential expressionand specific roles of the various SAP genes during colonizationand infection of different host tissues, there are also discrepanciesin the results obtained, which may be related to differencesin the sensitivities of the methods used in various laboratories,intrinsic differences even in apparently similar infection models,and variability among different C. albicans strains.

Our group has previously employed a genetic reporter system,termed in vivo expression technology (IVET), to study the expressionof the SAP1–SAP6 genes in the C. albicans model strainSC5314 during experimental infections. We constructed a setof reporter strains which carry a Candida-adapted FLP gene (ecaFLP),encoding the site-specific recombinase FLP, under control ofthe various SAP gene promoters. The induction of the promoterresults in expression of the FLP recombinase, which in turncatalyses the excision of a mycophenolic acid resistance marker(MPA^R) from the genome, so that even a transient induction ofthe target gene during an infection can be detected in individualcells by the MPA-sensitive phenotype of their progeny afterreisolation from infected tissue (Staib et al., 1999). Usingthis reporter system we could also detect a stage- and tissue-specificexpression pattern of the SAP1–SAP6 genes. We found thatSAP5 was induced at an early stage in all infection models examined(intravenous, intraperitoneal, oral and vaginal infections ofmice), whereas other SAP genes had a more specific expressionpattern. Beside its activation after intravenous infection,SAP6 expression was detected during invasion of the oesophagealmucosa, but not in a mouse model of vaginal candidiasis. Conversely,SAP4 was significantly expressed during vaginal, but not oesophagealinfection. SAP2 expression was usually found at the late stagesof intraperitoneal and systemic infections, although the SAP2-2allele was also induced at earlier time points. No significantexpression of SAP2 or the opaque-specific SAP1 and SAP3 geneswas observed during infection of the oesophageal or vaginaltissue of mice (Staib et al., 2000, 2002a; Taylor et al., 2005).Especially the latter results were in striking contrast to findingsof other researchers, who found SAP1–SAP3 to be expressedduring oral and/or vaginal infections of rats and humans and,in contrast to the SAP4–SAP6 genes, also to be requiredfor invasion of oral and vaginal RHE (see above). Although theresults obtained with the ecaFLP reporter gene in the mousemodel of vaginal candidiasis were fully confirmed using greenfluorescent protein (GFP) as an alternative reporter (Tayloret al., 2005), it remained possible that both reporter systemswere not sensitive enough to detect a low but biologically relevantexpression of the SAP1–SAP3 genes. Alternatively, it seemedpossible that the environment encountered during vaginal infectionin mice is different from that to which C. albicans is exposedduring human and rat vaginitis and also during in vitro infectionof RHE. To address these issues, we used the reportedly highlyreproducible oral and vaginal RHE infection models (Naglik etal., 2003a) to re-examine both the expression pattern and theimportance of the SAP1–SAP6 genes for epithelial invasionand damage by C. albicans.

METHODS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
ADDENDUM
REFERENCES

Strains and growth conditions.
C. albicans strains used in this study and, for clarity, therelevant parent strains are listed in Table 1. All strainswere stored as frozen stocks with 15 % glycerol at –80 °C.The strains were routinely grown in YPD medium [10 g yeastextract, 20 g peptone (BBL Trypticase Peptone, Becton Dickinson)and 20 g glucose per litre] at 30 °C. Reporterstrains were grown in SD medium [6.7 g yeast nitrogen basewithout amino acids (YNB; Bio 101) and 20 g glucose perlitre]. To prepare solid media, 1.5 % agar was added beforeautoclaving. For excision of the SAT1 flipper from nourseothricin-resistanttransformants by FLP-mediated recombination, the strains werecultivated overnight in YPM medium (10 g yeast extract,20 g peptone and 20 g maltose per litre) without selectivepressure to induce the MAL2 promoter. One hundred to two hundredcells were spread on YPD plates containing 20 µgnourseothricin ml^–1 (Werner Bioagents) and grown for 2 daysat 30 °C. Nou^S clones were identified by their smallcolony size and confirmed by restreaking on YPD plates containing100 µg nourseothricin ml^–1 as described previously(Reuß et al., 2004). To test for growth on BSA as thesole nitrogen source, strains were grown at 30 °C or37 °C in YCB-BSA medium [23.4 g yeast carbon base,4 g bovine serum albumin (Fraction V; Gerbu) per litre,pH 4.0].

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Table 1. C. albicans strains

Plasmid constructions.
Plasmid pSAP2MS2, which was used to delete the SAP2 gene, hasbeen described before (Staib et al., 2008

). Analogous constructswere generated for the deletion of SAP1 and SAP3–SAP6.ApaI–SalI fragments containing the upstream sequencesof these genes were obtained from plasmids pSFL13, pSFL33, pSFL43,pSFL53 and pSFL63 (Staib et al., 2000

) and ligated into ApaI/XhoI-digestedpOPT1M3 (Reuß et al., 2004

), resulting in plasmids pSAP1MS1,pSAP3MS1, pSAP4MS1, pSAP5MS1 and pSAP6MS1, respectively. Thedownstream regions of the SAP genes were then amplified usingthe primer pairs SAP1K/SAP1L, SAP3K/SAP3L, SAP4K/SAP4L, SAP5N/SAP5Qand SAP6N/SAP6Q (primer sequences are given in Table 2

).The PCR products were digested at the introduced SacII and SacIsites and ligated between the same sites of the plasmids describedabove, resulting in pSAP1MS2, pSAP3MS2, pSAP4MS2, pSAP5MS2 andpSAP6MS2 (see Fig. 2a and c

, Fig. 3a–c

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Table 2. Primers used in this study

Restriction sites introduced into the primers are underlined.

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Fig. 2. Construction of sap1 ${Delta}$ sap2 ${Delta}$ sap3 ${Delta}$ triple mutants. (a–c) Structure of the deletion cassettes from plasmids pSAP1MS2 (a), pSAP2MS2 (b) and pSAP3MS2 (c), which were used to delete the SAP1, SAP2 and SAP3 alleles, respectively, and genomic structure of the wild-type loci in strain SC5314. The SAP1–SAP3 coding regions are represented by white arrows and the upstream and downstream regions by the solid lines. Details of the SAT1 flipper cassette [grey rectangle bordered by FRT sites (black arrows)] have been presented elsewhere (Reuß et al., 2004

). The 34 bp FRT sites are not drawn to scale. The probes used for Southern hybridization analysis of the mutants are indicated by the black bars. Only relevant restriction sites are given: A, ApaI; Bg, BglII; C, ClaI; H, HindIII; ScI, SacI; ScII, SacII; Sl, SalI; Xh, XhoI. Sites shown in parentheses were destroyed by the cloning procedure. The ClaI site in bold italic is present only in the SAP2-1 allele. (d) Southern hybridizations of ClaI- (for SAP2), BglII- (for SAP1) and XhoI/HindIII- (for SAP3) digested genomic DNA of the parental strain SC5314 and the indicated mutants with the SAP2-specific probe 1 (top), the SAP1-specific probe 1 (middle) and the SAP3-specific probe 1 (bottom). Lane 1, wild-type; lanes 2 and 3, SAP2/sap2 ${Delta}$ ; lanes 4 and 5, sap2 ${Delta}$ /sap2 ${Delta}$ ; lanes 6 and 7, SAP1/sap1 ${Delta}$ sap2 ${Delta}$ /sap2 ${Delta}$ ; lanes 8 and 9, sap1 ${Delta}$ /sap1 ${Delta}$ sap2 ${Delta}$ /sap2 ${Delta}$ ; lanes 10 and 11, sap1 ${Delta}$ /sap1 ${Delta}$ sap2 ${Delta}$ /sap2 ${Delta}$ SAP3/sap3 ${Delta}$ ; lanes 12 and 13, sap1 ${Delta}$ /sap1 ${Delta}$ sap2 ${Delta}$ /sap2 ${Delta}$ sap3 ${Delta}$ /sap3 ${Delta}$ . The sizes of the hybridizing fragments (in kb) are given on the left side of the blots and their identities are indicated on the right.

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Fig. 3. Construction of sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants. (a–c) Structure of the deletion cassettes from plasmids pSAP4MS2 (a), pSAP5MS2 (b) and pSAP6MS2 (c), which were used to delete the SAP4, SAP5 and SAP6 alleles, respectively, and genomic structure of the wild-type loci in strain SC5314. The SAP4–SAP6 coding regions are represented by white arrows and the upstream and downstream regions by the solid lines. Other details are as described in the legend to Fig. 2

. The polymorphic BglII sites are in bold italic. (d) Southern hybridization of BglII-digested genomic DNA of the parental strain SC5314 and the indicated mutants with the SAP6-derived probe 1, which also cross-hybridizes with SAP4 and SAP5. Lane 1, wild-type; lanes 2 and 3, SAP6/sap6 ${Delta}$ ; lanes 4 and 5, sap6 ${Delta}$ /sap6 ${Delta}$ ; lanes 6 and 7, SAP5/sap5 ${Delta}$ sap6 ${Delta}$ /sap6 ${Delta}$ ; lanes 8 and 9, sap5 ${Delta}$ /sap5 ${Delta}$ sap6 ${Delta}$ /sap6 ${Delta}$ ; lanes 10 and 11, SAP4/sap4 ${Delta}$ ; sap5 ${Delta}$ /sap5 ${Delta}$ sap6 ${Delta}$ /sap6 ${Delta}$ ; lanes 12 and 13, sap4 ${Delta}$ /sap4 ${Delta}$ sap5 ${Delta}$ /sap5 ${Delta}$ sap6 ${Delta}$ /sap6 ${Delta}$ . Wild-type alleles are indicated on the left side of the blot and mutated alleles on the right.

C. albicans transformation.
C. albicans strain SC5314 was transformed by electroporation(Köhler et al., 1997

) with the gel-purified ApaI–SacIfragments from plasmids pSAP1MS2, pSAP2MS2, pSAP3MS2, pSAP4MS2,pSAP5MS2 and pSAP6MS2. Nourseothricin-resistant transformantswere selected on YPD agar plates containing 200 µgnourseothricin ml^–1 as described previously (Reußet al., 2004

). Single-copy integration of all constructs wasconfirmed by Southern hybridization.

Isolation of genomic DNA and Southern hybridization.
Genomic DNA from C. albicans strains was isolated as describedpreviously (Millon et al., 1994). A 10 µg sampleof DNA was digested with appropriate restriction enzymes, separatedon a 1 % agarose gel and, after ethidium bromide staining, transferredby vacuum blotting onto a nylon membrane and fixed by UV cross-linking.Southern hybridization with enhanced chemiluminescence-labelledprobes was performed with the Amersham ECL Direct Nucleic AcidLabelling and Detection System (GE Healthcare) according tothe instructions of the manufacturer.

Cultivation of reconstituted human epithelia.
The human epithelia for the in vitro model of oral and vaginalcandidiasis were supplied by SkinEthic Laboratories. Oral andvaginal RHE were obtained by culturing the human cell linesTR146 and A431, respectively, on an inert supporting membrane.According to the guidelines of the supplier, uninfected andinfected RHE were incubated in 1 ml SkinEthic maintenancemedium at 37 °C with 5 % CO₂ at 100 % humidity. After24 h, the culture medium was removed and fresh medium wasadded.

Detection of SAP induction during infection of vaginal RHE.
Reporter strains were grown overnight at 30 °C in SDmedium, washed, and resuspended in PBS at a density of 10⁷ cells ml^–1.Vaginal RHE was infected with 5x10⁵ C. albicans cells. After48 h of incubation, the RHE was lysed by the addition ofsterile distilled water and the C. albicans cells were recoveredand plated at an appropriate density on indicator plates (SDagar containing 1.8 µg MPA ml^–1). The percentageof small colonies was determined after 2 days of growthat 30 °C. C. albicans cells from the precultures werealso plated on the MPA indicator plates to verify that no promoterinduction had occurred before the infection.

Light microscopy.
Oral or vaginal RHE was infected as described above with C.albicans strains grown overnight at 30 °C in YPD medium.In some experiments, pepstatin A (Sigma) was added at a finalconcentration of 15 µM. After 48 h of incubation,the RHE was fixed with 2.5 % glutaraldehyde and 2 % formaldehydein a 0.05 M cacodylate-buffered solution (pH 7.2)at room temperature. After several washing and dehydration stepswith chilled solutions, the tissues were embedded in glycideether. Semi-thin sections (300 nm) of the embedded tissueswere obtained by using an RMC MT 7000 ultramicrotome, stainedwith 0.5 % methylene blue and 0.5 % azur II, and observed bylight microscopy.

Determination of LDH activity.
The release of lactate dehydrogenase (LDH) from infected epithelialcells into the surrounding medium was monitored as a measureof tissue damage. LDH activity was determined with the CytoTox96 non-radioactive cytotoxicity assay (Promega) according tothe instructions of the manufacturer. Controls consisted ofuninfected RHE (target spontaneous) and C. albicans cells grownin culture medium without RHE (effector spontaneous). TotalLDH activity in the epithelial cells was determined after completelysis of an uninfected sample with the lysis buffer providedin the kit (target maximum). After subtracting the absorbancevalues of the culture medium, tissue damage caused by C. albicanswas calculated according to the following formula: % tissuedamage=(experimental–effector spontaneous–targetspontaneous)/(target maximum–target spontaneous).

RESULTS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
ADDENDUM
REFERENCES

Expression pattern of the SAP1–SAP6 genes on reconstituted human vaginal epithelium
To investigate the expression of the SAP1–SAP6 genes duringinfection of vaginal RHE, we used a set of reporter strainsexpressing ecaFLP under control of the respective SAP gene promoters(see Table 1). Vaginal RHE was infected with each of thereporter strains as well as with a similarly constructed controlstrain that does not contain the ecaFLP gene and, therefore,stably retains the MPA^R marker in the genome. C. albicans cellswere recovered after 48 h of infection, appropriately diluted,and spread on MPA-containing indicator plates to determine thepercentage of small colonies, which are generated from cellsthat have lost the MPA^R marker by FLP-mediated recombination.As can be seen in Fig. 1, only the SAP5 promoter was significantlyactivated under these conditions, whereas the other reporterstrains generated only a few small colonies, similar to thecontrol strain, which produced a background of about 3 % smallcolonies due to accidental slower growth, which is in agreementwith previously reported values in other infection models (Staibet al., 1999). The SAP gene expression pattern observed in thisin vitro model of vaginal infection partially corresponds toprevious results obtained with the same set of reporter strainsin a mouse model of vaginal candidiasis, in that no significantexpression of SAP1–SAP3 and SAP6 was detected and SAP5was induced in both models. However, in the in vivo model SAP4was also expressed in addition to SAP5, albeit at lower levels(Taylor et al., 2005), while this was not the case in the invitro model. In addition, while SAP5 expression was detectedin virtually all infecting cells in the mouse model, only about20 % of the cells had detectably activated the SAP5 promoterin the RHE model (see Fig. 1). These results indicatedthat the signals inducing SAP5 (and SAP4) expression duringvaginal infection in mice are stronger than those that resultin SAP5 activation during in vitro infection of the RHE.

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Fig. 1. Induction of the SAP1–SAP6 promoters during invasion of vaginal RHE. Reporter strains expressing the ecaFLP gene under control of the indicated SAP gene promoters were used to infect vaginal RHE. C. albicans cells were recovered after 48 h of incubation and plated on MPA indicator plates. The percentage of small colonies was determined after 2 days of growth at 30 °C. For each SAP gene, two independently constructed reporter strains were used (see Table 1

). Results are the means±SD from two to four experiments, except for the SAP2 reporter strain S2FI7A (second SAP2 column), where the value is from a single experiment because in the other experiments too many cells had lost the MPA^R marker already in the preculture due to basal activity of the SAP2-2 promoter. Strain S2UI1A, which does not contain the ecaFLP gene, was used as a control to estimate the background of small colonies appearing as a result of accidental slow growth instead of excision of the MPA^R marker.

Construction of mutants of the C. albicans wild-type strain SC5314 lacking individual or multiple SAP genes
The SAP gene expression pattern observed during infection ofthe vaginal RHE with our reporter strains is in striking contrastto the results obtained by other researchers, who detected expressionof SAP1, SAP2 and SAP4–6 in the same model by RT-PCR.These researchers also found that tissue damage was drasticallyreduced in mutants lacking either SAP1 or SAP2, implying animportant role of these genes for invasion of the vaginal epithelium(Schaller et al., 2003

). Although we had previously shown thatthe activation of the SAP2 promoter under known inducing conditionsin vitro could easily be detected with the ecaFLP reporter genein all cells of the population (Staib et al., 2000

, 2002a

),we could not exclude the possibility that SAP2 and other SAPgenes are induced during RHE infection at low, but biologicallyrelevant levels that are below the sensitivity limit of thereporter system. We therefore decided to readdress the importanceof each of the SAP1–SAP6 genes for infection of RHE byassessing the virulence of mutants lacking specific SAP genesin these models. The sap mutants used in earlier studies weregenerated from the auxotrophic laboratory strain CAI4 usingthe Ura-blaster protocol (Hube et al., 1997

; Sanglard et al.,1997

). As the use of the URA3 marker for mutant constructionin C. albicans can sometimes cause problems in the interpretationof mutant phenotypes (Bain et al., 2001

; Brand et al., 2004

;Cheng et al., 2003

; Lay et al., 1998

; Sharkey et al., 2005

),we constructed a new set of sap mutants from the prototrophicwild-type model strain SC5314 using the SAT1-flipping strategy(Reuß et al., 2004

). For each of the SAP1–SAP6 genes,two independent series of homozygous deletion mutants were generated.In addition, within the SAP1–SAP3 and SAP4–SAP6subgroups, we constructed two series of all possible doubleand triple mutants, starting from two independent single mutants.The generation of each mutant from its progenitors can be followedin Table 1

, in which all strains are described, and theconstruction of the triple mutants is illustrated and documentedin Figs 2

and 3

. After each round of insertion and FLP-mediatedexcision of the SAT1 flipper cassette the resulting strainswere analysed by Southern hybridization with upstream and downstreamprobes of the target genes to confirm their specific inactivationand to exclude, as far as possible, undesired recombinationevents involving the previously inactivated loci. The absenceof the target genes from the genome of the mutants was alsoconfirmed by hybridization with the corresponding ORFs (datanot shown). Apart from the deletion of the SAP genes, the finalmutants should therefore be identical with the wild-type parentalstrain SC5314.

SAP2, but not SAP4–SAP6, is required for utilization of protein as a nitrogen source
A well-known and easily testable function of the Saps is thedegradation of proteins for use as a nitrogen source (Staib,1965). In YCB-BSA medium, which contains BSA as the sole nitrogensource, expression of the SAP2 gene is specifically inducedand allows growth of C. albicans. No significant expressionof other SAP genes occurs under these conditions and sap2 ${Delta}$ mutantsare unable to grow in this medium, but forced expression ofmost other SAP genes from an inducible promoter can fully orpartially rescue the growth defect of sap2 ${Delta}$ mutants (Hube etal., 1994, 1997; Staib et al., 2002b, 2008). Interestingly,the sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants used in previous studies havebeen reported to have a similar growth defect as sap2 ${Delta}$ mutantsin this medium, and it was concluded that Sap4p, Sap5p or Sap6pis required for the induction of SAP2 expression (Sanglard etal., 1997). We therefore tested the capacity of our sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants to grow in YCB-BSA. As can be seen in Fig. 4,mutants lacking the SAP4–SAP6 genes grew as well as thewild-type parental strain SC5314, both at 30 °C, whichis used as the standard condition in our laboratory, and at37 °C, which was used in the experiments in which agrowth defect of sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants was observedby other researchers (Sanglard et al., 1997). In contrast, thesap2 ${Delta}$ mutants failed to grow in YCB-BSA at both temperatures,in line with previous observations (Hube et al., 1997; Staibet al., 2002a, 2008). When the supernatants of the cultureswere analysed by SDS-PAGE, we found that the BSA in the mediumwas degraded by the sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants and comparableampounts of Sap2p were produced by these mutants and the wild-typestrain both at 30 °C and at 37 °C (Fig. 5).These results demonstrate that SAP2, but not any of the SAP4–SAP6genes, is required for growth of C. albicans on BSA as the solenitrogen source and Sap2p is normally expressed in the absenceof SAP4–SAP6. Apparently, there are differences in thephenotypes of sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ mutants constructed previouslyfrom strain CAI4 and those generated in the present study fromthe wild-type strain SC5314.

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Fig. 4. Only SAP2 is required for growth of C. albicans on proteins as the sole nitrogen source. YPD precultures of the wild-type strain SC5314, sap2 ${Delta}$ single, and sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants were diluted 10^–2 into YCB-BSA medium and incubated at 30 °C (top) or 37 °C (bottom). Growth was monitored by measuring the optical density of the cultures. Two independently constructed mutants were used in each case.

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Fig. 5. Secretion of Sap2p by the wild-type strain SC5314 (lane 1) and the sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants SAP456MS4A (lane 2) and SAP456MS4B (lane 3) grown for 48 h at 30 °C (top) or 72 h at 37 °C (bottom) in YCB-BSA. The culture supernatants of the strains were analysed by SDS-PAGE. Supernatants of the sap2 ${Delta}$ mutants SAP2MS4A (lane 4) and SAP2MS4B (lane 5) were included for comparison. The bands corresponding to BSA and Sap2p are labelled by arrows. M, molecular size markers.

SAP1–SAP6 are not required for invasion and damage of reconstituted human epithelia
We then tested the capacity of our mutants to invade and damageepithelial tissue during in vitro infection. In an initial setof experiments, all single mutants lacking one of the SAP1–SAP6genes were used for infection of RHE; however, we did not observea virulence defect of any of these mutants (data not shown).As other SAP genes might be upregulated and compensate for theloss of individual Sap isoenzymes, we then used the triple mutantslacking all of SAP1–SAP3 or SAP4–SAP6 in furtherinfection experiments. In addition to the wild-type controlstrain SC5314, a nonfilamentous efg1 ${Delta}$ mutant, which has beenreported to be noninvasive in a similar epithelial infectionmodel (Dieterich et al., 2002

), was included for comparison.As shown in Fig. 6

, no differences between the wild-typeand either of the triple mutants in their capacity to invadeand damage vaginal RHE could be observed. In each case, yeastand hyphal cells could be seen penetrating throughout the epitheliumto the supporting filter. In contrast, the efg1 ${Delta}$ mutant was unableto invade and damage the epithelium and only yeast cells werefound at the surface of the epithelium. These results suggestedthat none of the SAP1–SAP6 genes is required for invasionof vaginal RHE, a conclusion that was further corroborated bythe fact that, in our hands, the addition of the aspartic proteaseinhibitor pepstatin A did not affect the ability of the wild-typestrain SC5314 to invade the vaginal RHE (Fig. 6

). Similarresults were obtained in experiments in which oral RHE was infected(data not shown).

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Fig. 6. Invasion of vaginal RHE by the C. albicans wild-type strain SC5314, the sap1 ${Delta}$ sap2 ${Delta}$ sap3 ${Delta}$ triple mutants SAP123MS4C and SAP123MS4D, the sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants SAP456MS4A and SAP456MS4B, and the efg1 ${Delta}$ mutant Can33. The independently constructed series of sap mutants behaved identically and only one of them is shown in each case. Infection by the wild-type strain was also performed in the presence of the aspartic protease inhibitor pepstatin A. An uninfected control sample is shown for comparison. After 48 h of infection, the tissue was processed for microscopy as described in Methods.

Fungal invasion and tissue damage did not occur evenly withinthe whole RHE samples. To better compare and quantify the tissuedamage caused by the various strains, we determined the LDHreleased from the epithelial cells after infection with C. albicans,as previously described (Schaller et al., 2003

). Fig. 7

shows that there were no appreciable differences in the tissuedamage caused by the wild-type and the sap mutants, and pepstatinA also did not reduce the tissue damage caused by the wild-type.Only the efg1 ${Delta}$ mutant was unable to cause significant tissuedamage. Similar results were obtained in both vaginal (Fig. 7a

)and oral (Fig. 7b

) RHE infection models. We conclude fromthese experiments that Saps are not required for invasion ofRHE by C. albicans.

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Fig. 7. Epithelial damage caused by the C. albicans wild-type strain SC5314 and sap1 ${Delta}$ sap2 ${Delta}$ sap3 ${Delta}$ and sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants. Vaginal (a) or oral (b) RHE was infected with the indicated C. albicans strains. Infections with the wild-type strain SC5314 were also performed in the presence of pepstatin A (+pep). Tissue damage was determined by measuring the LDH activity in the supernatant after 24 h and 48 h as described in Methods. Values are the means±SD from three replicate measurements. Two independently constructed sap1 ${Delta}$ sap2 ${Delta}$ sap3 ${Delta}$ triple mutants (strains SAP123MS4C and SAP123MS4D) and sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants (strains SAP456MS4A and SAP456MS4B) were used in these experiments. Infection of the oral RHE (b) was performed in duplicate for all sap mutants, as indicated by the suffix.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION ADDENDUM REFERENCES

The role of the Saps of C. albicans in the pathogenicity ofthe fungus has been investigated in numerous studies (for acomprehensive review, see Naglik et al., 2003a

). Various laboratorieshave analysed the gene expression pattern of the SAP gene familyduring infection, as it might provide clues about the role ofindividual Sap isoenzymes in the host–pathogen interaction.The recombination-based IVET is highly useful for the detectionof even a transient in vivo induction of genes that, like SAP1–SAP6,are not significantly expressed under standard growth conditionsin vitro. An additional advantage of this reporter system isthat the activation of a target gene promoter can be observedat the level of single cells. However, a limitation of the systemis that only a yes or no answer is obtained for each cell recoveredfrom infected tissue and, as previously noted, it may not besensitive enough for genes that are expressed only at low levels(Staib et al., 1999

, 2000

, 2002b

; Taylor et al., 2005

). Thesensitivity of the ecaFLP reporter gene was similar to thatof the more frequently used GFP reporter gene when correspondingreporter strains were compared under identical conditions. Bothreporter systems detected the induction of the SAP2 promoterin YCB-BSA medium in all cells of the population and also theactivation of the SAP4 and SAP5 promoters during vaginal infectionof mice, whereas no expression of the SAP1–SAP3 geneswas observed in the latter model with either of the two reportergenes (Morschhäuser et al., 1998

; Staib et al., 2000

; Tayloret al., 2005

). The expression of the phase-specific SAP1 genewas also easily detected in opaque cells of strain WO-1 usingGFP as a reporter (Strauß et al., 2001

). While our failureto detect expression of the SAP1 and SAP2 genes during infectionof vaginal RHE may therefore be due to a limited sensitivityof the FLP-based IVET, the expression levels of these genesin this infection model seem to be considerably below theirfully induced state. Nevertheless, the importance of SAP1 andSAP2 for invasion and damage of vaginal RHE and of SAP1–SAP3for infection of oral RHE has been demonstrated by the reducedvirulence of mutants lacking the corresponding genes in thesein vitro infection models (Schaller et al., 1998

, 1999

, 2003

).In contrast, we were unable to confirm a role of any of theSAP1–SAP6 genes in the same infection models. Apart froma possible compensatory upregulation of other SAP genes in oursap1 ${Delta}$ sap2 ${Delta}$ sap3 ${Delta}$ triple mutants, there are several possible explanationsfor the discrepancies in the results obtained in our presentwork and those of previous studies by other researchers. Althoughthe RHE models have been reported to be highly reproducible(Naglik et al., 2003a

), it seems that variabilities may neverthelessarise when they are used in different laboratories. Schalleret al. (1999)

reported that the damage to oral RHE caused byinfection with the wild-type strain SC5314 was reduced in thepresence of the aspartic protease inhibitor pepstatin A, butwe did not see such an effect in our present study. PepstatinA completely inhibits Sap-dependent growth in YCB-BSA mediumat even lower concentrations than those used in the infectionassays (Staib et al., 2008

); therefore, a contribution of theSaps to tissue damage should have been detected, although wecan not exclude the possibility that pepstatin A did not fullyinhibit Sap activity under the conditions used in the RHE infectionexperiments. These results indicate that the differences observedin this and previous studies with respect to the role of theSaps for invasion of RHE can not solely be attributed to phenotypicdifferences of the constructed deletion mutants. Differencesin the experimental setup may therefore cause invasion of RHEto be protease-dependent or not. In contrast to the sap mutants,an efg1 ${Delta}$ mutant that had previously been reported to be noninvasivein a similar epithelial invasion model (Dieterich et al., 2002

)was also unable to invade and damage vaginal and oral RHE inour hands. An alternative possible explanation for the differencesin the effect of pepstatin A on the ability of the wild-typestrain SC5314 to damage RHE is that the stocks of this strainmaintained in various laboratories are not identical and mayvary in their dependence on Sap activity for epithelial invasion.

Apart from these considerations, there also seem to be differencesbetween the sap mutants constructed previously from the auxotrophiclaboratory strain CAI4 and those generated in the present studyfrom its prototrophic parental strain SC5314. In agreement withthe gene expression pattern, we found that only SAP2, but noneof the other SAP genes tested, was required for growth of C.albicans in YCB-BSA medium, i.e. when proteins are the onlyavailable nitrogen source. In contrast, Sanglard et al. (1997)found that a mutant lacking the SAP4–SAP6 genes also failedto grow in this medium and they concluded that one of the correspondingproteases is required for SAP2 expression. They did not reportwhether mutants lacking only one or two of the SAP4–SAP6genes exhibited the same growth defect and if reintroductionof any of the genes into the triple mutant rescued the growthdefect. The sap4 ${Delta}$ sap5 ${Delta}$ sap6 ${Delta}$ triple mutants constructed in ourpresent study secreted wild-type levels of Sap2p (see Fig. 5),demonstrating that SAP2 expression does not depend on any ofthose other proteases.

The importance of Saps for tissue invasion and damage seemsto depend on the infection model used. For example, when theinteraction of mutants lacking one of the SAP1–SAP3 geneswith endothelial cells was investigated, only Sap2p, but notSap1p or Sap3p, was found to contribute to the ability of C.albicans to damage endothelial cells (Ibrahim et al., 1998).Other researchers found that proteases mediate invasion of C.albicans into human oral mucosa by degrading E-cadherin, asE-cadherin degradation was completely inhibited in the presenceof protease inhibitors (Villar et al., 2007). In this case,Sap5p was implicated in tissue invasion, as forced overexpressionof SAP5 rescued the invasion defect of a rim101 mutant, in whichexpression of the SAP4–SAP6 genes was severely reduced.On the other hand, C. albicans can also invade epithelial andendothelial cells by inducing its own endocytosis (Phan et al.,2007). These studies and our present work indicate that theimportance of the Saps in general, and of individual Sap isoenzymes,for the virulence of C. albicans varies strongly, dependingon the infection model, with even minor differences in the experimentalsetup having a significant impact on the dependence on proteaseactivity for successful invasion and establishment in varioushost niches. New and more sophisticated animal models of superficialand disseminated Candida infections have been established inthe past years and continue to be developed (de Repentigny,2004). The set of mutants generated in this study from the wild-typemodel strain SC5314, which lack single or multiple SAP genes,will be a valuable tool to study the role of these enzymes inthe host–pathogen interaction in more detail.

ADDENDUM

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
ADDENDUM
REFERENCES

In a related paper in this issue of Microbiology, Naglik etal. (2008), using quantitative real-time RT-PCR, now also reportthat only SAP5, but not the other SAP genes, is significantlyupregulated during infection of RHE and that the SAP1–SAP6genes are not required for invasion of RHE, which is in contrastto their previous results and completely supports our findings.However, they observe a partial inhibition of RHE invasion anddamage by C. albicans in the presence of the aspartic proteaseinhibitor pepstatin A.

ACKNOWLEDGEMENTS

We thank Steffen Rupp for providing the efg1 ${Delta}$ mutant Can33 andPeter Staib for critical reading of the manuscript. Sequencedata for C. albicans were obtained from the Candida Genome Database(http://www.candidagenome.org/). This study was supported bythe Deutsche Forschungsgemeinschaft (DFG grant MO 846/1 andSFB630).

Edited by: J. G. Berman

REFERENCES

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METHODS
RESULTS
DISCUSSION
ADDENDUM
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Received 22 July 2008; revised 4 August 2008; accepted 11 August 2008.

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				J. R. Naglik, D. Moyes, J. Makwana, P. Kanzaria, E. Tsichlaki, G. Weindl, A. R. Tappuni, C. A. Rodgers, A. J. Woodman, S. J. Challacombe, et al. Quantitative expression of the Candida albicans secreted aspartyl proteinase gene family in human oral and vaginal candidiasis Microbiology, November 1, 2008; 154(11): 3266 - 3280. [Abstract] [Full Text] [PDF]