Superoxide dismutases and glutaredoxins have a distinct role in the response of Candida albicans to oxidative stress generated by the chemical compounds menadione and diamide

Chaves, Guilherme Maranhão; Silva, Walicyranison Plinio da

doi:10.1590/S0074-02762012000800006

Abstract

To cope with oxidative stress, Candida albicans possesses several enzymes involved in a number of biological processes, including superoxide dismutases (Sods) and glutaredoxins (Grxs). The resistance of C. albicans to reactive oxygen species is thought to act as a virulence factor. Genes such as SOD1 and GRX2, which encode for a Sod and Grx, respectively, in C. albicans are widely recognised to be important for pathogenesis. We generated a double mutant, Δgrx2/sod1, for both genes. This strain is very defective in hyphae formation and is susceptible to killing by neutrophils. When exposed to two compounds that generate reactive oxygen species, the double null mutant was susceptible to menadione and resistant to diamide. The reintegration of the SOD1 gene in the null mutant led to recovery in resistance to menadione, whereas reintegration of the GRX2 gene made the null mutant sensitive to diamide. Despite having two different roles in the responses to oxidative stress generated by chemical compounds, GRX2 and SOD1 are important for C. albicans pathogenesis because the double mutant Δgrx2/sod1 was very susceptible to neutrophil killing and was defective in hyphae formation in addition to having a lower virulence in an animal model of systemic infection.

Candida albicans; superoxide dismutases; glutaredoxins; phagocytosis; virulence

ARTICLES

Superoxide dismutases and glutaredoxins have a distinct role in the response of Candida albicans to oxidative stress generated by the chemical compounds menadione and diamide

Guilherme Maranhão Chaves⁺ + Corresponding author: guilherme.chaves@ufrnet.br ; Walicyranison Plinio da Silva

Laboratório de Micologia Médica e Molecular, Departamento de Análises Clínicas e Toxicológicas, Centro de Ciências da Saúde, Universidade Federal do Rio Grande do Norte, Natal, RN, Brasil

ABSTRACT

To cope with oxidative stress, Candida albicans possesses several enzymes involved in a number of biological processes, including superoxide dismutases (Sods) and glutaredoxins (Grxs). The resistance of C. albicans to reactive oxygen species is thought to act as a virulence factor. Genes such as SOD1 and GRX2, which encode for a Sod and Grx, respectively, in C. albicans are widely recognised to be important for pathogenesis. We generated a double mutant, Δgrx2/sod1, for both genes. This strain is very defective in hyphae formation and is susceptible to killing by neutrophils. When exposed to two compounds that generate reactive oxygen species, the double null mutant was susceptible to menadione and resistant to diamide. The reintegration of the SOD1 gene in the null mutant led to recovery in resistance to menadione, whereas reintegration of the GRX2 gene made the null mutant sensitive to diamide. Despite having two different roles in the responses to oxidative stress generated by chemical compounds, GRX2 and SOD1 are important for C. albicans pathogenesis because the double mutant Δgrx2/sod1 was very susceptible to neutrophil killing and was defective in hyphae formation in addition to having a lower virulence in an animal model of systemic infection.

Key words:Candida albicans - superoxide dismutases - glutaredoxins - phagocytosis - virulence

Candida albicans is a diploid yeast belonging to the human normal microbiota and may occur as a commensal organism of the oral cavity, gastrointestinal tract and vagina of healthy individuals (Colombo et al. 2007, Southern et al. 2008, Chaves et al. 2012). Several factors may trigger its transition from commensalism to infection. As a consequence, this harmless yeast may become pathogenic, predominantly depending on the host's immune status. Immunocompromised hosts, diabetic patients and pregnant women are the populations that are the most susceptible to candidiasis (Colombo et al. 2007).

Despite the fact that the human host plays the major role in the establishment of successful candidiasis, the fungus also possesses attributes of virulence. For C. albicans, its widely advocated virulence traits include the ability to adhere to host epithelial cells, which is the first step in the acquisition and maintenance of a stable yeast population in the oral cavity, the secretion of hydrolytic enzymes (proteinases and phospholipases), the ability to grow with different morphologies (blastoconidia, pseudo hyphae and true hyphae), i.e., because filamentation appears to be related to tissue invasion, biofilm formation and its resistance to the oxidative burst generated inside phagocytic cells (Karkowska-Kuleta et al. 2009, Chaves et al. 2012).

In addition to combating reactive oxygen species (ROS) from their own metabolism, pathogenic organisms also react against the primary oxidative burst generated by macrophages and polymorphonuclear neutrophils (PMNs), which utilise the nicotinamide adenine dinucleotide phosphate oxidase present in the membrane to produce the superoxide anion (O₂^-) (Battistoni et al. 1998, Lamarre et al. 2001)^.

The role of the innate immune response in C. albicans is related to its recognition by dendritic cells, macrophages and neutrophils. This process is mediated by pattern recognition receptors involved in phagocytosis and the clearance of the pathogen (Gow et al. 2007, Taylor et al. 2007), such as Toll-like receptors and lectin receptors. These receptors recognise the pathogen-associated molecular patterns that are commonly found in a wide range of pathogens, but not in the mammalian host (Nicola et al. 2008). In response to ROS produced by phagocytic cells, C. albicans possesses several enzymes involved in a number of biological processes, such as superoxide dismutases (Sods), catalases (Cats), thioredoxin (Trx) peroxidases (Prxs) and glutaredoxins (Grxs) (Chaves et al. 2007, Tosello et al. 2007).

Several genes involved in the oxidative stress response in C. albicans have been recognised as virulence factors. For example, the disruption of the CAT1 gene in this yeast led to an increased sensitivity to hydrogen peroxide (H₂O₂) and an attenuation of virulence in an animal model (Wysong et al. 1998).

In addition, C. albicans possesses six different genes that encode for Sods. These enzymes possess antioxidant properties that catalyse the dismutation of O₂^- into molecular oxygen and H₂O₂, which can then be detoxified by Cat (Chaves et al. 2007), thereby scavenging the toxic effects of O₂ (Frohner et al. 2009). These Sods include cytoplasmic Sod1 and Sod3, mitochondrial Sod2 and the cell surface GP-anchored Sod4, Sod5 and Sod6 (Martchenko et al. 2004, Frohner et al. 2009, Bink et al. 2011).

The cytosolic Cu/Zn SOD encoded by SOD1 is important for virulence in C. albicans. The C. albicans Δsod1 mutant has been shown to be attenuated in virulence in an animal model of systemic infection (Hwang et al. 2002, Chaves et al. 2007) and more susceptible to macrophage (Hwang et al. 2002) and PMN killing (Chaves et al. 2007). The mitochondrial Sod2 of C. albicans has been ruled out as a putative virulence factor, but the Δsod2 mutant is more sensitive to heating, ethanol and high concentrations of salts, indicating no direct role in virulence, but a function in different environmental stresses (Hwang et al. 2003).

SOD5 expression is increased in C. albicans yeast cells exposed to PMNs (Fradin et al. 2005) and during morphological change from yeasts to hyphae (Nantel et al. 2002). However, while sod1Δ is hypersensitive to killing by a macrophage cell line in vitro (Hwang et al. 2002), the same was not observed for sod5Δ (Martchenko et al. 2004), indicating that the virulence role of Sod5 may be due to a resistance to different phagocytic cells.

Frohner et al. (2009) recently demonstrated that the Sod4 and Sod5 produced by innate immune response cells are extremely important as ROS scavengers. When both the SOD4 and SOD5 genes were disrupted in C. albicans, the double mutant generated (Δsod4/sod5) was extremely susceptible to in vitro macrophage killing (Frohner et al. 2009).

Grx are cytosolic enzymes that act as thiol oxidoreductases and are responsible for the reduction of protein disulphides or glutathione (GSH)-protein mixed disulphides. This reaction also involves cysteine residues from the enzyme's active site (Herrero et al. 2008). Chaves et al. (2007) demonstrated that a mutant lacking the GRX2 gene, which encodes a Grx in C. albicans, was deficient in hyphae formation and more susceptible to PMN killing. This Δgrx2 mutant was also attenuated in virulence in a murine model of systemic infection and susceptible to menadione, but resistant to diamide.

Srinivasa et al. (2012) recently characterised a Prx in C. albicans that reduces both H₂O₂ and tert-butyl hydroperoxide (t-BOOH). The deletion of the PRX gene led to a mutant that was virtually insensitive to H₂O₂, diamide and menadione, but susceptible to low concentrations of t-BOOH, indicating different roles for genes related to oxidative stress and induced by chemical compounds.

Some genes related to oxidative stress are also regulated during hyphae formation and appear to be somehow related to C. albicans morphogenesis (Hwang et al. 2002, Nantel et al. 2002, Martchenko et al. 2004, Chaves et al. 2007). In addition, Schroter et al. (2000) analysed the amount of ROS produced when cells were incubated in 10% serum. Those authors found that ROS were produced in large amounts in a strain that formed true hyphae. Recently, it has been demonstrated that hyphal differentiation is induced by a subtoxic concentration of exogenous H₂O₂ in C. albicans (Nasution et al. 2008).

Younes et al. (2011) reported that the HWP2 gene, which is involved in morphogenesis, adherence and biofilm formation in C. albicans, is also required to tolerate oxidative stress because the mutant Δhwp2 is susceptible to H₂O₂ compared with the wild-type strain.

As mentioned, previous studies have demonstrated that the SOD1 gene and GRX2 gene play a role in the virulence of C. albicans (Hwang et al. 2002, Chaves et al. 2007). When separately disrupted, these genes led to an attenuation of virulence in an animal model of systemic infection. Furthermore, the disruption of these genes, particularly the GRX2 gene, appears to influence morphogenetic development. Other phenotypic changes were found between the single mutants Δsod1 and Δgrx2, such as different responses to oxidative stress induced by menadione and diamide induction. We hypothesised that the disruption of two of the oxidative stress genes would alter virulence and/or interfere with other C. albicans phenotypic properties. Therefore, we generated the double mutant Δsod1/grx2 and re-integrated each of these genes separately, creating the Δsod1/grx2+GRX2 and Δsod1/grx2+SOD1 reintegrant strains.

MATERIALS AND METHODS

Strains, media and culture conditions - All C. albicans strains used and constructed in this study are listed in Table I. These strains were stored at -80ºC in 20% (v:v) glycerol and later subcultured on Sabouraud agar. The following media were routinely used to grow the fungi: nutrient broth + glucose + YE (NGY) broth: 1 g/L neopeptone (Difco, Detroit, MI, USA), 4 g/L glucose and 1 g/L yeast extract; yeast extract-peptone-dextrose (YPD) broth: 10 g/L yeast extract, 20 g/L glucose and 20 g/L mycological peptone (Oxoid, Basingstoke, UK); SD medium: 6.7 g/L yeast nitrogen base with ammonium sulphate and without amino acids (Difco) and 20 g/L glucose, with 25 µg/mL uridine added as required.

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Construction of the grx2Δ null mutant and reintegrant strain - All primers used in this study are listed in Table II. To make the double mutant strains, the GRX2 and SOD1 genes were disrupted using the ura-blaster method (Fonzi & Irwin 1993). To achieve this objective, the GRX2 gene was disrupted in the Δsod1 mutant. The Ura-Δsod1 mutant was kindly provided by Dr Sa-Ouk Kang (Laboratory of Biophysics, Seoul National University, Republic of Korea). The GRX2 disruption cassette pGC4, which was previously generated (Chaves et al. 2007), was released by digestion with HindIII and BanII and GRX2 was disrupted by sequential rounds of transformation into strain Δsod1. The URA3 marker was recycled by selection on SD medium plus 5-fluoroorotic acid (1 mg/mL) and uridine (50 µg/mL). Gene disruption was confirmed by polymerase chain reaction (PCR). To avoid potential problems associated with ectopic expression of URA3 (Brand et al. 2004), the Ura-Δsod1/grx2 mutant was transformed with StuI-digested CIp10 plasmid (Murad et al. 2000), thus ensuring URA3 expression at the neutral RPS1 locus (orf19.3002).

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As a control, each of these genes was then individually reintegrated. The Δsod1/grx2+GRX2 mutant was constructed by transforming the Δsod1/grx2 mutant with the reintegrant cassette pGC6, which was previously generated (Chaves et al. 2007). The pGC6 plasmid insert was subcloned into the NotI site of CIp10. The resulting plasmid was digested with StuI and then transformed into the Ura-Δsod1/grx2 null mutant. To generate the Δsod1/grx2+SOD1 mutant, a new reintegrant cassette, pGC8, was created. Therefore, the SOD1 open-reading frame plus 938 bp of its promoter and 404 bp of its terminator was amplified by PCR (primers SOD1SF and SOD14 rev) and the product was cloned into pGEM-T Easy (Promega Ltd, Southampton, UK). The plasmid insert was subcloned into the NotI site of CIp10 and the resulting plasmid was digested with StuI and transformed into the Ura-Δsod1/grx2 null mutant.

C. albicans growth rate determination - Growth rates were measured in duplicate. A volume from an overnight culture in NGY was transferred to YPD broth or RPMI-1640 (Gibco, Paisley, UK) to give an initial optical density (OD)₆₀₀ nm = 0.05 and the culture was incubated at 37ºC with rotation at 200 rpm in a gyratory shaker. Growth was measured using the OD₆₀₀ nm vs. a medium blank. Maximum growth rates were determined from the logarithms of values taken in the exponential phase.

Tests for hyphal formation - For the induction of hyphal formation on solid media, the cells were grown in NGY, centrifuged and washed three times in water. From a suspension adjusted to 10⁹ cells/mL, 5 µL was spotted on the surface of Spider (Liu et al. 1994) and GlcNAc agars (20 g/L N-acetyl-D-glucosamine, 6.7 g/L yeast nitrogen base, 16 g/L micro agar) in triplicate. The plates were incubated for seven days at 30ºC.

For tests in liquid media, an adaptation of Odds et al. (2000) was used. Therefore, the cells were grown, washed and standardised to an initial concentration of 10⁶ cells/mL in 10% foetal calf serum (FCS), YPD + 10% FCS and GlcNAc pre-warmed to 37ºC and incubated at the same temperature with gyratory shaking (9,200 rpm). After 1 and 3-h incubation periods, culture samples were mixed with an equal volume of 10% formaldehyde to arrest further development. The 1-h sample was examined microscopically to determine the percentage of cells bearing evaginations. The 3-h sample was examined to approximate the mean morphology index (MI) (Merson-Davies & Odds 1989), in which a value close to 1 indicates a population of spheroidal yeast cells and value close to 4 indicates a population of true hyphal cells. Values between 1-4 indicate mixed or pseudohyphal morphologies (Chaves et al. 2007).

Sensitivity of C. albicans to oxidative stress inducers - The method of Izawa et al. (1995) was used with some modifications to determine the sensitivity of C. albicans to oxidative stress inducers. Yeast cells grown in NGY were standardised to 2 × 10⁷ cells/mL. Five-microlitres volumes of a 10-fold dilution series prepared from this suspension were spotted on the surface of YPD agar plates containing concentrations (from 0.5-2.5 mM) of menadione and diamide. The plates were incubated for 48 h at 30ºC. Alternatively, 50-µL volumes of NGY-grown yeast cells were transferred to 5-mL YPD broth with and without the addition of menadione or diamide (0.5-2.0 mM) and incubated in a rotator wheel for 16 h at 30ºC. The OD₆₀₀ nm was determined for the control and test tubes. Sensitivity to the compounds was measured by examining growth in the presence of compounds as a percentage of control growth.

The susceptibility of C. albicans killing by PMN - PMN freshly isolated from blood samples of healthy volunteers on the day of the experiment (Fradin et al. 2005) was suspended in Eagle's minimal essential medium + 20 mM HEPES (pH 7.2) and standardised to 8 × 10⁵ PMN/mL. C. albicans cells grown overnight in NGY were centrifuged, washed three times in saline and resuspended at 5 × 10⁶ yeast cells/mL in HEPES-buffered Eagle's minimal essential medium containing one-tenth of a volume of fresh human plasma. Equal volumes of PMN and yeast cell suspensions were mixed and incubated at 37ºC for 1 h with rotation at 50 rpm. Control suspensions contained C. albicans without PMN. The suspensions were centrifuged and the pellets were resuspended in water to lyse the PMN. After three cycles of washing and resuspension, viable C. albicans cell counts were determined by plating a 10-fold dilution series on YPD agar. Yeast cell susceptibility was determined as the mean difference between viable counts in the presence and absence of PMN. The assays were performed in triplicate (Chaves et al. 2007).

Virulence of C. albicans in the murine IV challenge model - Immunocompetent female BALB/c mice with a weight range from 17-23 g were supplied with food and water ad libitum. The mice were intravenously inoculated with C. albicans strains that had been grown overnight in NGY, washed and resuspended in saline. The inoculum was standardised to allow for an injection of 2-3 × 10⁴ colony-forming unit/g mouse body weight. The mice were examined daily. Animals that displayed a loss of body weight > 20% or signs of serious illness were humanely terminated and survival curves were performed.

Statistical analysis - Means ± standard deviations were determined from the results of at least three independent experiments. Differences between values for phenotypic tests were analysed using Student's t test. Animal survival data were compared with Kaplan-Meier/LogRank statistics. p < 0.05 were considered significant for all comparisons.

RESULTS

Gene disruptions and reintegrations - The Δ sod1/grx2 mutant (GCY 213) was successfully generated by deleting 1,583 bp from the central region of the GRX2 gene in the Δ sod1 mutant (GCY 200) using the "Ura-blasting" technique (Fonzi & Irwin 1993) (Fig. 1A). The URA3 gene was reintegrated at the neutral RPS1 locus to avoid ectopic URA3 expression problems (Brand et al. 2004), creating the mutant GCY 214. The GRX2 gene and URA3 were integrated at the RPS1 locus of the Δ sod1/grx2 null mutant to generate the Δ sod1/grx2 + GRX2 reintegrant (GCY 215) (Fig. 1B). In the same manner, the SOD1 gene and URA3 were integrated at the RPS1 locus of the Δ sod1/grx2 null mutant to generate the Δ sod1/grx2 + SOD1 reintegrant (GCY 216) (Fig. 1C).

Virulence phenotypic properties of the mutants in vitro - The growth rates of the yeast cell null double mutant GCY 214 and the GRX2 and SOD1 reintegrant strains (GCY 215 and GCY 216, respectively) were similar to that of the wild-type, NGY 152.

Hyphae formation of the mutants on solid and liquid media - The colony morphologies on Spider, YPD + 20% serum and GlcNAc agars were slightly different for the double mutant compared with NGY 152. Specifically on the Spider medium, the mutants formed a more wrinkled and less filamentous form (Fig. 2). During the first hour of incubation, the double mutant Δsod1/grx2 (GCY 214) and double mutant reintegrant strains Δsod1/grx2+GRX2 and Δsod1/grx2+SOD1 (GCY 215 and GCY 216, respectively) demonstrated an even more noticeable delay in their ability to evaginate than the single mutants Δsod1 and Δgrx2 (previously generated) (Chaves et al. 2007). The heterozygote for the double mutant Δsod1/grx2/GRX2 (GCY 211), double mutant GCY 214 and reintegrant strains GCY 215 and GCY 216 did not evaginate during the first hour of incubation in the YPD + 10% serum. When grown in 10% serum in water (the most potent germ tube inducer), all of the strains had fewer than 20% evaginating cells, a very different result compared with the control strain NGY 152, in which nearly 100% of the cells evaginated during the first hour of incubation. Evagination in GlcNAc was also less evident in the double mutant strain series than the single mutants and both had fewer cells evaginating than the control strain NGY 152. The disruption of both genes appeared to have a stronger effect on early germ tube formation compared with when only one gene of each was disrupted (Fig. 3).

After 3 h of incubation, the MI showed noticeable differences for the double mutant strain series. The mean MI was less than 2.0 for all strains in the YPD + 10% serum and the double mutant GCY 214 had an MI close to 1.0, indicating a lack of ability to form hyphae under this condition. All of the mean MIs were significantly lower than the control strain NGY 152 (p < 0.05). In addition, the MI was lower for the double mutant strain series compared with NGY than the single mutants when the cells were induced to form hyphae in the presence of 10% serum (Chaves et al. 2007). The double mutant strain series formed fewer true hyphae, with a mean MI in the range of 3.5-3.7. Although this difference was not large, it was still statistically significant (p < 0.05). When cells were grown in GlcNac, the mean MI was approximately 2.0 or below for all of the double mutant strain series (Fig. 4).

Sensitivity to oxidative stress inducers - The heterozygous GCY 211, double mutant GCY 214 and GRX2 reintegrant GCY 215 were sensitive to menadione. The reintroduction of the SOD1 gene restored resistance to this chemical compound in the SOD1 reintegrant strain, GCY 216 (Fig. 5). Disruption of one copy of the GRX2 gene in the single Δsod1 mutant (GCY200) did not lead to any difference because the heterozygous strain Δsod1/grx2/GRX2 (GCY 211) was still sensitive to 2.5 mM diamide. Following the same trend, as previously observed (Chaves et al. 2007), the knockout of both copies of the GRX2 gene (generating GCY 214) led to a phenotype resistant to diamide. The reintroduction of one copy of GRX2 (generating GCY 215; Δsod1/grx2+GRX2) led this double mutant reintegrant to become sensitive again, similar to the heterozygous Δsod1/grx2/GRX2 (GCY 211). In the same manner, the introduction of the SOD1 gene, creating Δsod1/grx2+SOD1 (GCY 2160), maintained the same diamide-resistant phenotype when both copies of the GRX2 genes were disrupted (Fig. 6). We reproduced the same results obtained for the tests in liquid media by using agar plates with different concentrations of menadione and diamide (Fig. 7).

PMN killing assays of the mutants - Interactions with human peripheral PMNs revealed that the double mutant strain series was more susceptible to killing than the control strain NGY 152. After an incubation period of 1 h at 37ºC in the presence (test) or absence of PMNs (control) and incubating the C. albicans cells at 30ºC on YPD agar plates, the heterozygous double mutant strain Δsod1/grx2/GRX2 (GCY 211), double mutant null Δsod1/grx2 (GCY 214) and Δsod1/grx2+SOD1 (GCY 216) reintegrant strains were more susceptible to PMN killing (p < 0.05). However, only the Δsod1/grx2+GRX2 (GCY 215) mutant cells were less efficiently killed by the PMNs after 1 h (Fig. 8). This number is closer to the findings for the single mutant killings (Chaves et al. 2007).

Virulence of the mutants in an animal model of systemic infection - The virulence of the double mutant strain series did demonstrate some degree of attenuation by disruption of the two genes related to oxidative stress in C. albicans. Survival curves demonstrated that the double null mutant Δsod1/grx2 (GCY 214) and reintegrant strain Δsod1/grx2+SOD1 (GCY 216) were the most attenuated in virulence (40% and 50% survivors at the end of the experiment, respectively; p < 0.05). The reintegrant strain Δsod1/grx2+GRX2 (GCY 215) had a survival curve comparable to the control strain NGY152, demonstrating some degree of regaining virulence when the GRX2 gene was reintegrated (Fig. 9).

DISCUSSION

In the present study, we evaluated the role of two different genes related to oxidative stress in C. albicans. The first, the GRX2 gene, encodes a Grx and the other, the SOD gene, encodes a copper and zinc-containing SOD. We hypothesised that the disruption of two genes involved in oxidative stress would lead to a strain with an increased attenuation in virulence and higher degree of susceptibility to chemical compounds that induce oxidative stress.

The ability to combat ROS is vital for microbial pathogenesis to either cope with ROS generated as a consequence of their own metabolism or escape from human phagocytic cells (Cabiscol et al. 2000, Lamarre et al. 2001, Hwang et al. 2002, 2003, Martchenko et al. 2004, Gonzalez-Parraga et al. 2005). Some chemical compounds have been used to induce oxidative stress in microorganisms, such as menadione and diamide.

Oxidative stress may be generated by the addition of menadione (2-methylnaphthalene-1,4-dione), a polycyclic aromatic ketone commonly used in yeast studies (Grant 2001, Osorio et al. 2003), which accepts an electron from a respiratory carrier and transfers it to molecular oxygen (a redox cycling agent), stimulating superoxide formation without inhibiting the respiratory chain (Halliwell & Gutteridge 2007). Diamide is a thiol-specific oxidant that can readily oxidise GSH, leading to molecular cross-linking (Hwang et al. 2003, Herrero et al. 2008).

As previously observed by Hwang et al. (2002) and then by Chaves et al. (2007), the Δsod1 mutant is sensitive to menadione. The Δgrx2 mutant is less sensitive to this chemical compound than the mutant Δsod1 and very resistant to diamide (Chaves et al. 2007). The idea of specific roles for oxidative stress genes in C. albicans was further reinforced when the double mutant strain series was tested for susceptibility to oxidative stress generators in the present study. When one copy of GRX2 was disrupted in the Δsod1 background, generating the heterozygous strain Δsod1/grx2/GRX2 (GCY 211), this strain remained sensitive to menadione. When both copies of GRX2 were disrupted, generating the double mutant Δsod1/grx2 (GCY 214), the phenotype remained the same. Furthermore, the reintegration of one copy of GRX2, generating the Δsod1/grx2+GRX2 (GCY 215) mutant, had no effect, confirming that the response of GRX2 is minimal when the stress generated is due to the generation of intracellular O₂^- (menadione). This hypothesis was conclusive because the reintegration of only one copy of SOD1 (generating the Δsod1/grx2+SOD1 mutant) conferred resistance to menadione.

Another completely different response was observed in the double mutant strain series when they were grown with diamide. The deletion of one copy of GRX2 in the Δsod1 background (generating the Δsod1/grx2/GRX2 mutant) was insufficient to lead to resistance to diamide. The deletion of two copies of the gene, generating the double mutant Δsod1/grx2 (GCY 214), led to resistance, as was observed for the Δgrx2 mutant (Chaves et al. 2007). This result confirms that SOD1 plays no role in combating the oxidative stress generated by diamide because the reintroduction of GRX2 (generating the Δsod1/grx2+GRX2 mutant) again rendered this mutant strain sensitive to diamide. The Δsod1/grx2+SOD1 mutant was resistant to diamide, indicating that the reintroduction of SOD1 did not have an effect, confirming again that GRX2 and not SOD1 is involved in the resistance to the oxidative stress generated by diamide. Distinct roles for menadione and diamide in generating oxidative stress have also been observed with Aspergillus nidulans (Pocsi et al. 2005).

Herrero et al. (2008) demonstrated that Sods are particularly related to ROS detoxification and Grx in the control of the redox state of protein sulfhydryl groups in Saccharomyces cerevisiae. Furthermore, the Candida genome database (candidagenome.org/) currently describes four Grx (GRX1, GRX2, GRX3 and GRX5) and two thioredoxins (TRX1 and TRX2) for this species, further reinforcing that resistance to diamide is related to a compensatory mechanism for other Grx (or even thioredoxins) in C. albicans because these other genes might be up-regulated to act as thiol oxidoreductases responsible for reducing the protein disulphides or GSH-protein mixed disulphides generated during diamide-induced oxidative stress. Conversely, Luikenhuis et al. (1998) found different functions for defences against diamide in S. cerevisiae that were dependent on the growth phase. In exponential phase cells, the lack of both Grx resulted in a resistance to diamide, whereas in stationary phase cells, the deletion of GRX1 alone led to resistance, suggesting that a complexity of mechanisms for different Grx in C. albicans may exist.

Regarding hyphae formation, the double mutant Δsod1/grx2 had a markedly lower mean MI when grown in YPD + 10% serum, 10% serum and GlcNac. Gonzales-Parraga et al. (2005) investigated a possible relationship between levels of GSH and oxidised GSH (GSSH) and germ tube formation induced by serum in C. albicans, specifically during the first hour of incubation. The levels of GSH decreased, while the levels of GSSH remained unmodified. Grx are responsible for reducing GSSH to GSH. Therefore, the lack of Grx (due to GRX2 disruption) and GSSH accumulation may partially explain the inability to form hyphae in the double mutant, i.e., due to ROS accumulation. SOD5 has been demonstrated to relate to hyphae formation by transcript profiling; i.e., this gene is up-regulated during the process of hyphae formation (Nantel et al. 2002) Furthermore, Martchenko et al. (2004) demonstrated with Northern analysis that SOD5 expression during hyphae formation is due to the presence of serum. SOD1 is also transcribed in the presence of serum (Lamarre et al. 2001), which could explain why a double mutant for two oxidative stress genes (GRX2 and SOD1) is defective in hyphae formation.

We also observed that our double mutant Δsod1/grx2 is very susceptible to PMN killing. Conversely, both genes were up-regulated in the presence of PMNs (Fradin et al. 2005). However, in addition to SOD1 and GRX2 appearing to play different and specific roles in response to the oxidative stress generated by the chemical inducers menadione and diamide, GRX2 also appears to play a major role in surviving PMN killing.

The double mutant strain series was unexpectedly not more attenuated in mouse virulence than the single mutants generated by Chaves et al. (2007). However, the double null mutant Δsod1/grx2 and the Δsod1/grx2+SOD1 reintegrant were still attenuated in virulence, confirming the importance of oxidative stress genes for virulence in mice. Surprisingly, Δsod1/grx2+GRX2, which was also more resistant to PMN killing, regained some degree of virulence in mice, reinforcing the role of this gene in C. albicans pathogenesis.

The double mutant generated here, Δsod1/grx2, had a defect in hyphae formation and was susceptible to PMN killing, corroborating the hypothesis that both genes are important for C. albicans virulence. Further studies are required to elucidate the specific role of the importance of this complex antioxidant system and its relation to C. albicans virulence.

Received 1 May 2012

Accepted 26 October 2012

Financial support: CAPES

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Colombo AL, Guimaraes T, Silva LR, de Almeida Monfardini LP, Cunha Ak, Rady P, Alves T, Rosas RC 2007. Prospective observational study of candidemia in São Paulo, Brazil: incidence rate, epidemiology, and predictors of mortality. Infect Control Hosp Epidemiol 28: 570-576.
Fonzi WA, Irwin MY 1993. Isogenic strain construction and gene mapping in Candida albicans Genetics 134: 717-728.
Fradin CP, De Groot P, Maccallum D, Schaller M, Klis F, Odds FC, Hube B 2005. Granulocytes govern the transcriptional response, morphology and proliferation of Candida albicans in human blood. Mol Microbiol 56: 397-415.
Frohner IE, Bourgeois C, Yaysyk K, Majer O, Kuchler K 2009. Candida albicans cell surface superoxide dismutases degrade host-derived reactive oxygen species to escape innate immune surveillance. Mol Microbiol 71: 240-252.
Gonzalez-Parraga P, Marin FR, Aguelles JC, Hernandez JA 2005. Correlation between the intracellular content of glutathione and the formation of germ-tubes induced by human serum in Candida albicans Biochim Biophys Acta 1722: 324-330.
Gow NA, Netea MG, Munro CA, Ferwerda G, Bates S, Mora-Montes HM, Walker L, Jansen T, Jacobs L, Tsoni V, Brown GD, Odds FC, Van der Meer JW, Brown AJ, Kullberg BJ 2007. Immune recognition of Candida albicans beta-glucan by dectin-1. J Infect Dis 196: 1565-1571.
Grant CM 2001. Role of the glutathione/glutaredoxin and thioredoxin systems in yeast growth and response to stress conditions. Mol Microbiol 39: 533-541.
Halliwell B, Gutteridge JMC 2007. Free radicals in biology and medicine, 4th ed., University Press, Oxford, 851 pp.
Herrero E, Ros J, Belli G, Cabiscol E 2008. Redox control and oxidative stress in yeast cells. Biochim Biophys Acta 1780: 1217-1235.
Hwang CS, Baek YU, Yim HS, Kang SO 2003. Protective roles of mitochondrial manganese-containing superoxide dismutase against various stresses in Candida albicans Yeast 20: 929-941.
Hwang CS, Rhie GE, Oh JH, Huh WK, Yim HS, Kang SO 2002. Copper-and zinc-containing superoxide dismutase (Cu/ZnSOD) is required for the protection of Candida albicans against oxidative stresses and the expression of its full virulence. Microbiology 148: 3705-3713.
Izawa S, Inoue Y, Kimura A 1995. Oxidative stress response in yeast: effect of glutathione on adaptation to hydrogen peroxide stress in Saccharomyces cerevisiae FEBS Lett 368: 73-76.
Karkowska-Kuleta J, Rapala-Kozik M, Kozok A 2009. Fungi pathogenic to humans: molecular bases of virulence of Candida albicans, Cryptococcus neoformans and Aspergillus fumigatus Acta Biochim Pol 56: 211-224.
Lamarre C, LeMay JD, Deslauries N, Bourbonnai Y 2001. Candida albicans expresses an unusual cytoplasmic manganese-containing superoxide dismutase (SOD3 gene product) upon the entry and during the stationary phase. J Biol Chem 276: 43784-43791.
Liu H, Kohler J, Fink GR 1994. Suppression of hyphal formation in Candida albicans by mutation of a STE12 homolog. Science 266: 1723-1726.
Luikenhuis S, Perrone G, Dawes IW, Grant CM 1998. The yeast Saccharomyces cerevisiae contains two glutaredoxin genes that are required for protection against reactive oxygen species. Mol Biol Cell 9: 1081-1091.
Martchenko M, Alarco AM, Harcus D, Whiteway M 2004. Superoxide dismutases in Candida albicans: transcriptional regulation and functional characterization of the hyphal-induced SOD5 gene. Mol Biol Cell 15: 456-467.
Merson-Davies LA, Odds FC 1989. A morphology index for characterization of cell shape in Candida albicans J Gen Microbiol 135: 3143-3152.
Murad AM, Lee PR, Broadbent ID, Barelle CJ, Brown AJ 2000. CIp10, an efficient and convenient integrating vector for Candida albicans Yeast 16: 325-327.
Nantel A, Dignard D, Bachewich C, Harcus D, Marcil A, Bouin AP, Sensen CW, Hogues H, van het Hoog M, Gordon P, Rigby T, Benoit F, Tessier DC, Thomas DY, Whiteway M 2002. Transcription profiling of Candida albicans cells undergoing the yeast-to-hyphal transition. Mol Biol Cell 13: 3452-3465.
Nasution O, Srinivasa K, Kim M, Kim YJ, Kim W, Jeong W, Choi W 2008. Hydrogen peroxide induces hyphal differentiation in Candida albicans Eukaryot Cell 7: 2008-2011.
Nicola AM, Casadevall A, Goldman DL 2008. Fungal killing by mammalian phagocytic cells. Curr Opin Microbiol 11: 313-317.
Odds FC, Van Nuffel L, Gow NA 2000. Survival in experimental Candida albicans infections depends on inoculum growth conditions as well as animal host. Microbiology 146: 1881-1889.
Osorio H, Carvalho E, del Valle M, Gunther Sillero MA, Moradas-Ferreira P, Sillero A 2003. H2O2, but not menadione, provokes a decrease in the ATP and an increase in the inosine levels in Saccharomyces cerevisiae An experimental and theoretical approach. Eur J Biochem 270: 1578-1589.
Pocsi I, Miskei M, Karanyi Z, Emri T, Ayoubi P, Pusztahelyi T, Balla G, Prade RA 2005. Comparison of gene expression signatures of diamide, H2O2 and menadione exposed Aspergillus nidulans cultures-linking genome-wide transcriptional changes to cellular physiology. BMC Genomics 6: 182.
Schroter C, Hipler UC, Wilmer A, Kunkel W, Wollina U 2000. Generation of reactive oxygen species by Candida albicans in relation to morphogenesis. Arch Dermatol Res 292: 260-264.
Southern P, Horbul J, Maher D, Davis DA 2008. C. albicans colonization of human mucosal surfaces. PLoS ONE 3: e2067.
Srinivasa K, Kim J, Yee S, Kim W, Choi W 2012. A MAP kinase pathway is implicated in the pseudohyphal induction by hydrogen peroxide in Candica albicans Mol Cells 33: 183-193.
Taylor PR, Tsoni SV, Willment JA, Dennehy KM, Rosas M, Findon H, Haynes K, Steele C, Botto M, Gordon S, Brown GD 2007. Dectin-1 is required for beta-glucan recognition and control of fungal infection. Nat Immunol 8: 31-38.
Tosello ME, Biasoli MS, Luque AG, Magaro HM, Krapp AR 2007. Oxidative stress response involving induction of protective enzymes in Candida dubliniensis Med Mycol 45: 535-540.
Wysong DR, Christin L, Sugar AM, Robbins PW, Diamond RD 1998. Cloning and sequencing of a Candida albicans catalase gene and effects of disruption of this gene. Infect Immun 66: 1953-1961.
Younes S, Bahnan W, Dimassi HI, Khalaf RA 2011. The Candida albicans Hwp2 is necessary for proper adhesion, biofilm formation and oxidative stress tolerance. Microbiol Res 166: 430-436.

+

Corresponding author:

guilherme.chaves@ufrnet.br

Publication Dates

Publication in this collection
03 Jan 2013
Date of issue
Dec 2012

History

Received
01 May 2012
Accepted
26 Oct 2012

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Battistoni AG, Donnarumma, Greco R, Valenti P, Rotilio G 1998. Overexpression of a hydrogen peroxide-resistant periplasmic Cu, Zn superoxide dismutase protects Escherichia coli from macrophage killing. Biochem Biophys Res Commun 243: 804-807.

[2] Bink A, Vandenbosch D, Coenye T, Nelis H, Cammue BP, Thevissen K 2011. Superoxide dismutases are involved in Candida albicans biofilm persistence against miconazole. Antimicrob Agents Chemother 55: 4033-4037.

[3] Brand A, MacCallum DM, Brown AJ, Gow NA, Odds FC 2004. Ectopic expression of URA3 can influence the virulence phenotypes and proteome of Candida albicans but can be overcome by targeted reintegration of URA3 at the RPS10 locus Eukaryot Cell 3: 900-909.

[4] Cabiscol, Tamarit EJ, Ros J 2000. Oxidative stress in bacteria and protein damage by reactive oxygen species. Int Microbiol 3: 3-8.

[5] Chaves GM, Bates S, Maccallum DM, Odds FC 2007. Candida albicans GRX2, encoding a putative glutaredoxin, is required for virulence in a murine model. Genet Mol Res 6: 1051-1063.

[6] Chaves GM, Santos FP, Colombo AL 2012. The persistence of multifocal colonisation by a single ABC genotype of Candida albicans may predict the transition from commensalism to infection. Mem Inst Oswaldo Cruz 107: 198-204.

[7] Colombo AL, Guimaraes T, Silva LR, de Almeida Monfardini LP, Cunha Ak, Rady P, Alves T, Rosas RC 2007. Prospective observational study of candidemia in São Paulo, Brazil: incidence rate, epidemiology, and predictors of mortality. Infect Control Hosp Epidemiol 28: 570-576.

[8] Fonzi WA, Irwin MY 1993. Isogenic strain construction and gene mapping in Candida albicans Genetics 134: 717-728.

[9] Fradin CP, De Groot P, Maccallum D, Schaller M, Klis F, Odds FC, Hube B 2005. Granulocytes govern the transcriptional response, morphology and proliferation of Candida albicans in human blood. Mol Microbiol 56: 397-415.

[10] Frohner IE, Bourgeois C, Yaysyk K, Majer O, Kuchler K 2009. Candida albicans cell surface superoxide dismutases degrade host-derived reactive oxygen species to escape innate immune surveillance. Mol Microbiol 71: 240-252.

[11] Gonzalez-Parraga P, Marin FR, Aguelles JC, Hernandez JA 2005. Correlation between the intracellular content of glutathione and the formation of germ-tubes induced by human serum in Candida albicans Biochim Biophys Acta 1722: 324-330.

[12] Gow NA, Netea MG, Munro CA, Ferwerda G, Bates S, Mora-Montes HM, Walker L, Jansen T, Jacobs L, Tsoni V, Brown GD, Odds FC, Van der Meer JW, Brown AJ, Kullberg BJ 2007. Immune recognition of Candida albicans beta-glucan by dectin-1. J Infect Dis 196: 1565-1571.

[13] Grant CM 2001. Role of the glutathione/glutaredoxin and thioredoxin systems in yeast growth and response to stress conditions. Mol Microbiol 39: 533-541.

[14] Halliwell B, Gutteridge JMC 2007. Free radicals in biology and medicine, 4th ed., University Press, Oxford, 851 pp.

[15] Herrero E, Ros J, Belli G, Cabiscol E 2008. Redox control and oxidative stress in yeast cells. Biochim Biophys Acta 1780: 1217-1235.

[16] Hwang CS, Baek YU, Yim HS, Kang SO 2003. Protective roles of mitochondrial manganese-containing superoxide dismutase against various stresses in Candida albicans Yeast 20: 929-941.

[17] Hwang CS, Rhie GE, Oh JH, Huh WK, Yim HS, Kang SO 2002. Copper-and zinc-containing superoxide dismutase (Cu/ZnSOD) is required for the protection of Candida albicans against oxidative stresses and the expression of its full virulence. Microbiology 148: 3705-3713.

[18] Izawa S, Inoue Y, Kimura A 1995. Oxidative stress response in yeast: effect of glutathione on adaptation to hydrogen peroxide stress in Saccharomyces cerevisiae FEBS Lett 368: 73-76.

[19] Karkowska-Kuleta J, Rapala-Kozik M, Kozok A 2009. Fungi pathogenic to humans: molecular bases of virulence of Candida albicans, Cryptococcus neoformans and Aspergillus fumigatus Acta Biochim Pol 56: 211-224.

[20] Lamarre C, LeMay JD, Deslauries N, Bourbonnai Y 2001. Candida albicans expresses an unusual cytoplasmic manganese-containing superoxide dismutase (SOD3 gene product) upon the entry and during the stationary phase. J Biol Chem 276: 43784-43791.

[21] Liu H, Kohler J, Fink GR 1994. Suppression of hyphal formation in Candida albicans by mutation of a STE12 homolog. Science 266: 1723-1726.

[22] Luikenhuis S, Perrone G, Dawes IW, Grant CM 1998. The yeast Saccharomyces cerevisiae contains two glutaredoxin genes that are required for protection against reactive oxygen species. Mol Biol Cell 9: 1081-1091.

[23] Martchenko M, Alarco AM, Harcus D, Whiteway M 2004. Superoxide dismutases in Candida albicans: transcriptional regulation and functional characterization of the hyphal-induced SOD5 gene. Mol Biol Cell 15: 456-467.

[24] Merson-Davies LA, Odds FC 1989. A morphology index for characterization of cell shape in Candida albicans J Gen Microbiol 135: 3143-3152.

[25] Murad AM, Lee PR, Broadbent ID, Barelle CJ, Brown AJ 2000. CIp10, an efficient and convenient integrating vector for Candida albicans Yeast 16: 325-327.

[26] Nantel A, Dignard D, Bachewich C, Harcus D, Marcil A, Bouin AP, Sensen CW, Hogues H, van het Hoog M, Gordon P, Rigby T, Benoit F, Tessier DC, Thomas DY, Whiteway M 2002. Transcription profiling of Candida albicans cells undergoing the yeast-to-hyphal transition. Mol Biol Cell 13: 3452-3465.

[27] Nasution O, Srinivasa K, Kim M, Kim YJ, Kim W, Jeong W, Choi W 2008. Hydrogen peroxide induces hyphal differentiation in Candida albicans Eukaryot Cell 7: 2008-2011.

[28] Nicola AM, Casadevall A, Goldman DL 2008. Fungal killing by mammalian phagocytic cells. Curr Opin Microbiol 11: 313-317.

[29] Odds FC, Van Nuffel L, Gow NA 2000. Survival in experimental Candida albicans infections depends on inoculum growth conditions as well as animal host. Microbiology 146: 1881-1889.

[30] Osorio H, Carvalho E, del Valle M, Gunther Sillero MA, Moradas-Ferreira P, Sillero A 2003. H2O2, but not menadione, provokes a decrease in the ATP and an increase in the inosine levels in Saccharomyces cerevisiae An experimental and theoretical approach. Eur J Biochem 270: 1578-1589.

[31] Pocsi I, Miskei M, Karanyi Z, Emri T, Ayoubi P, Pusztahelyi T, Balla G, Prade RA 2005. Comparison of gene expression signatures of diamide, H2O2 and menadione exposed Aspergillus nidulans cultures-linking genome-wide transcriptional changes to cellular physiology. BMC Genomics 6: 182.

[32] Schroter C, Hipler UC, Wilmer A, Kunkel W, Wollina U 2000. Generation of reactive oxygen species by Candida albicans in relation to morphogenesis. Arch Dermatol Res 292: 260-264.

[33] Southern P, Horbul J, Maher D, Davis DA 2008. C. albicans colonization of human mucosal surfaces. PLoS ONE 3: e2067.

[34] Srinivasa K, Kim J, Yee S, Kim W, Choi W 2012. A MAP kinase pathway is implicated in the pseudohyphal induction by hydrogen peroxide in Candica albicans Mol Cells 33: 183-193.

[35] Taylor PR, Tsoni SV, Willment JA, Dennehy KM, Rosas M, Findon H, Haynes K, Steele C, Botto M, Gordon S, Brown GD 2007. Dectin-1 is required for beta-glucan recognition and control of fungal infection. Nat Immunol 8: 31-38.

[36] Tosello ME, Biasoli MS, Luque AG, Magaro HM, Krapp AR 2007. Oxidative stress response involving induction of protective enzymes in Candida dubliniensis Med Mycol 45: 535-540.

[37] Wysong DR, Christin L, Sugar AM, Robbins PW, Diamond RD 1998. Cloning and sequencing of a Candida albicans catalase gene and effects of disruption of this gene. Infect Immun 66: 1953-1961.

[38] Younes S, Bahnan W, Dimassi HI, Khalaf RA 2011. The Candida albicans Hwp2 is necessary for proper adhesion, biofilm formation and oxidative stress tolerance. Microbiol Res 166: 430-436.