Evaluation of the V404I and V509M amino acid substitutions of <Emphasis Type="Italic">ERG11</Emphasis> gene in <Emphasis Type="Italic">Candida albicans</Emphasis> isolates by pyrosequencing

The molecular mechanisms underlying fluconazole resistance in C. albicans involve mutations and the overexpression of the ERG11 gene and membrane transport proteins. We examined the relationship between the reduced fluconazole susceptibility of C. albicans and mutations of V404I and V509M in the ERG11 gene in 182 C. albicans clinical isolates using the Pyrosequencing™ method. DNAs from these clinical isolates with different levels of in-vitro fluconazole susceptibility — one resistant, five susceptible dose-dependent (SDD), four trailer, and 172 susceptible — were analyzed. None of the fluconazole-susceptible, SDD, trailer or resistant isolates had mutations of V404I or V509M. Our results showed that no correlation can be found between the V404I or V509M mutation and fluconazole susceptibility in C. albicans.     

The new mutation L321F in Candida albicans ERG11 gene may be associated with fluconazole resistance

BackgroundFor many years fluconazole has been commonly used to treat Candida infections. However, the indiscriminate use of this antimycotic therapy has favored the emergence of resistant isolates. Mutations in the ERG11 gene have been described as one of the primary mechanisms of resistance in Candida species.AimsIn this study we investigated missense mutations in ERG11 genes of Candida albicans, Candida glabrata and Candida tropicalis isolates previously evaluated by susceptibility testing to fluconazole.MethodsScreening for these mutations was performed on 19 Candida clinical isolates (eight C. albicans, five C. glabrata and six C. tropicalis) resistant and susceptible to fluconazole. The ERG11 gene was amplified by PCR with specific primers for each Candida species and analyzed by automated sequencing.ResultsWe identified 14 different missense mutations, five of which had not been described previously. Among them, a new mutation L321F was identified in a fluconazole resistant C. albicans isolate and it was analyzed by a theoretical three-dimensional structure of the ERG11p.ConclusionThe L321F mutation in C. albicans ERG11 gene may be associated with fluconazole resistance.     

Amino acid substitutions at the major insertion loop of Candida albicans sterol 14alpha-demethylase are involved in fluconazole resistance

Background

In the fungal pathogen Candida albicans, amino acid substitutions of 14alpha-demethylase (CaErg11p, CaCYP51) are associated with azole antifungals resistance. This is an area of research which is very dynamic, since the stakes concern the screening of new antifungals which circumvent resistance. The impact of amino acid substitutions on azole interaction has been postulated by homology modeling in comparison to the crystal structure of Mycobacterium tuberculosis (MT-CYP51). Modeling of amino acid residues situated between positions 428 to 459 remains difficult to explain to date, because they are in a major insertion loop specifically present in fungal species.

Methodology/Principal Finding

Fluconazole resistance of clinical isolates displaying Y447H and V456I novel CaErg11p substitutions confirmed in vivo in a murine model of disseminated candidiasis. Y447H and V456I implication into fluconazole resistance was then studied by site-directed mutagenesis of wild-type CaErg11p and by heterogeneously expression into the Pichia pastoris model. CLSI modified tests showed that V447H and V456I are responsible for an 8-fold increase in fluconazole MICs of P. pastoris mutants compared to the wild-type controls. Moreover, mutants showed a sustained capacity for producing ergosterol, even in the presence of fluconazole. Based on these biological results, we are the first to propose a hybrid homology structure-function model of Ca-CYP51 using 3 different homology modeling programs. The variable position of the protein insertion loop, using different liganded or non-liganded templates of recently solved CYP51 structures, suggests its inherent flexibility. Mapping of recognized azole-resistant substitutions indicated that the flexibility of this region is probably enhanced by the relatively high glycine content of the consensus.

Conclusions/Significance

The results highlight the potential role of the insertion loop in azole resistance in the human pathogen C. albicans. This new data should be taken into consideration for future studies aimed at designing new antifungal agents, which circumvent azole resistance.     

The <Emphasis Type="Italic">in vitro</Emphasis> and <Emphasis Type="Italic">in vivo</Emphasis> efficacy of fluconazole in combination with farnesol against <Emphasis Type="Italic">Candida albicans</Emphasis> isolates using a murine vulvovaginitis model

Farnesol is a quorum-sensing molecule that inhibits biofilm formation in Candida albicans. Previous in vitro data suggest that, in combination with certain antifungals, farnesol may have an adjuvant anti-biofilm agent. However, the in vivo efficacy of farnesol is very questionable. Therefore, the in vitro and in vivo activity of fluconazole combined with farnesol was evaluated against C. albicans biofilms using fractional inhibitory concentration index (FICI) determination, time-kill experiments and a murine vulvovaginitis model. The median biofilm MICs of fluconazole-sensitive C. albicans isolates ranged between 4 -> 512 mg/L and 150–300 μM for fluconazole and farnesol, respectively. These values were 512 -> 512 mg/L and > 300 μM for fluconazole-resistant clinical isolates. Farnesol decreased the median MICs of fluconazole by 2-64-fold for biofilms. Based on FICI, synergistic interaction was observed only in the case of the sessile SC5314 reference strain (FICIs: 0.16–0.27). In time-kill studies, only the 512 mg/L fluconazole and 512 mg/L fluconazole + 75 μM farnesol reduced biofilm mass significantly at each time point in the case of all isolates. The combination reduced the metabolic activity of biofilms for all isolates in a concentration- and time-dependent manner. Our findings revealed that farnesol alone was not protective in a murine vulvovaginitis model. Farnesol was not beneficial in combination with fluconazole for fluconazole-susceptible isolates, but partially increased fluconazole activity against one fluconazole-resistant isolate, but not the other one.     

Expression Patterns of ABC Transporter Genes in Fluconazole-Resistant <Emphasis Type="Italic">Candida glabrata</Emphasis>

Clinical management of fungal diseases is compromised by the emergence of antifungal drug resistance in fungi, which leads to elimination of available drug classes as treatment options. An understanding of antifungal resistance at molecular level is, therefore, essential for the development of strategies to combat the resistance. This study presents the assessment of molecular mechanisms associated with fluconazole resistance in clinical Candida glabrata isolates originated from Iran. Taking seven distinct fluconazole-resistant C. glabrata isolates, real-time PCRs were performed to evaluate the alternations in the regulation of the genes involved in drug efflux including CgCDR1, CgCDR2, CgSNQ2, and CgERG11. Gain-of-function (GOF) mutations in CgPDR1 alleles were determined by DNA sequencing. Cross-resistance to fluconazole, itraconazole, and voriconazole was observed in 2.5 % of the isolates. In the present study, six amino acid substitutions were identified in CgPdr1, among which W297R, T588A, and F575L were previously reported, whereas D243N, H576Y, and P915R are novel. CgCDR1 overexpression was observed in 57.1 % of resistant isolates. However, CgCDR2 was not co-expressed with CgCDR1. CgSNQ2 was upregulated in 71.4 % of the cases. CgERG11 overexpression does not seem to be associated with azole resistance, except for isolates that exhibited azole cross-resistance. The pattern of efflux pump gene upregulation was associated with GOF mutations observed in CgPDR1. These results showed that drug efflux mediated by adenosine-5-triphosphate (ATP)-binding cassette transporters, especially CgSNQ2 and CgCDR1, is the predominant mechanism of fluconazole resistance in Iranian isolates of C. glabrata. Since some novel GOF mutations were found here, this study also calls for research aimed at investigating other new GOF mutations to reveal the comprehensive understanding about efflux-mediated resistance to azole antifungal agents.     

Targeted amplification and MinION nanopore sequencing of key azole and echinocandin resistance determinants of clinically relevant Candida spp. from blood culture bottles

The objective of the study was to evaluate the use of targeted multiplex Nanopore MinION amplicon re-sequencing of key Candida spp. from blood culture bottles to identify azole and echinocandin resistance associated SNPs. Targeted PCR amplification of azole (ERG11 and ERG3) and echinocandin (FKS) resistance-associated loci was performed on positive blood culture media. Sequencing was performed using MinION nanopore device with R9.4.1 Flow Cells. Twenty-eight spiked blood cultures (ATCC strains and clinical isolates) and 12 prospectively collected positive blood cultures with candidaemia were included. Isolate species included Candida albicans, Candida glabrata, Candida krusei, Candida parapsilosis, Candida tropicalis and Candida auris. SNPs that were identified on ERG and FKS genes using Snippy tool and CLC Genomic Workbench were correlated with phenotypic testing by broth microdilution (YeastOne™ Sensititre). Illumina whole-genome-sequencing and Sanger-sequencing were also performed as confirmatory testing of the mutations identified from nanopore sequencing data. There was a perfect agreement of the resistance-associated mutations detected by MinION-nanopore-sequencing compared to phenotypic testing for acquired resistance (16 with azole resistance; 3 with echinocandin resistance), and perfect concordance of the nanopore sequence mutations to Illumina and Sanger data. Mutations with no known association with phenotypic drug resistance and novel mutations were also detected.     

ABC transporters coupled with the elevated ergosterol contents contribute to the azole resistance and amphotericin B susceptibility

Most screening approaches produce compounds that target survival genes and are likely to generate resistance over time. Simply having more drugs does not address the potential emergence of resistance caused by target mutation, drug efflux pumps over-expression, and so on. There is a great need to explore new strategies to treat fungal infections caused by drug-resistant pathogens. In this study, we found that azole-resistant Candida albicans with CaCDR1 and CaCDR2 over-expression is hypersensitive against amphotericin B (AmB) by our high throughput synergy screening (HTSS). In contrast, Δcdr1 and Δcdr2 knockout strains were resistant to AmB. Moreover, clinical isolates with increased expression of CaCDR1 and CaCDR2 demonstrated susceptibility to AmB, which can also synergize with the efflux pumps inducer fluphenazine (FPZ). Finally, the increased drug susceptibility to AmB in azole-resistant C. albicans with drug efflux pumps over-expression was consistent with the elevated expression of CaERG11 and its associated ergosterols in clinical isolates. Our data implies that the level of ergosterol contents determines the susceptibility to azoles and AmB in C. albicans. Deep understanding of the above mechanisms would offer new hope to treat drug-resistant C. albicans.     

牛源近平滑念珠菌对氟康唑耐药性研究

以牛源近平滑念珠菌（Candida parapsilosis）为试验菌株,采用微量稀释法进行药物敏感性试验,PCR扩增测序检测ERG11基因突变,Realtime PCR检测ERG11、CDR1、MDR1、MRR1基因的mRNA表达量,探讨耐药相关基因在牛源近平滑念珠菌耐唑类药物中的作用,为牛源近平滑念珠菌的耐药研究提供参考。结果表明,近平滑念珠菌对5-氟胞嘧啶、两性霉素Ｂ的敏感率均高于75%,对唑类药物的耐药率均高于50%,其中对氟康唑的耐药率最高,达58.3%;所有菌株的ERG11基因中均检测出错义突变A395T,耐氟康唑和剂量依赖菌株的ERG11基因中检测出同义突变T591C;氟康唑耐药组ERG11、CDR1、 MDR1、MRR1基因表达水平均显著高于敏感组（P<0.05）。牛源近平滑念珠菌对唑类抗真菌药物的耐药率较高且具有多重耐药性。牛源近平滑念珠菌ERG11基因中的T591C突变以及ERG11、CDR1、MDR1、MRR1基因的高表达都可能在其对氟康唑耐药性的产生中起到一定的作用。     

Diversity-oriented synthesis of pyrazoles derivatives from flavones and isoflavones leads to the discovery of promising reversal agents of fluconazole resistance in Candida albicans

Diversity-oriented synthesis of derivatives of natural products is an important approach for the discovery of novel drugs. In this paper, a series of novel 3,4-diaryl-1H-pyrazoles and 3,5-diaryl-1H-pyrazoles derivatives were synthesized through the one-pot reaction of flavones and isoflavones with the hydrazine hydrate and substituted hydrazine hydrate. Some of these novel compounds exhibited antifungal effects against Candida albicans SC5314, and displayed more potent inhibitory activities against the efflux-pump-deficient strain DSY654. In addition, compounds 25, 28 and 32a displayed outstanding reversal activity of azole resistance against clinical azole-resistant Candida albicans in combination with fluconazole (FLC), with FICI values ranging from 0.012 to 0.141. The preliminary structure-activity relationship (SAR) of these compounds was also discussed. In conclusion, this study provides several novel agents that displayed potent antifungal activities alone or together with fluconazole, which makes progress for development of antifungal drugs.     

A Case Report of Penile Infection Caused by Fluconazole- and Terbinafine-Resistant <Emphasis Type="Italic">Candida albicans</Emphasis>

Candida albicans is the most common pathogen that causes balanoposthitis. It often causes recurrence of symptoms probably due to its antifungal resistance. A significant number of balanitis Candida albicans isolates are resistant to azole and terbinafine antifungal agents in vitro. However, balanoposthitis caused by fluconazole- and terbinafine-resistant Candida albicans has rarely been reported. Here, we describe a case of a recurrent penile infection caused by fluconazole- and terbinafine-resistant Candida albicans, as well as the treatments administered to this patient. The isolate from the patient was tested for drug susceptibility in vitro. It was sensitive to itraconazole, voriconazole, clotrimazole and amphotericin B, but not to terbinafine and fluconazole. Thus, oral itraconazole was administrated to this patient with resistant Candida albicans penile infection. The symptoms were improved, and mycological examination result was negative. Follow-up treatment of this patient for 3 months showed no recurrence.     

Possible Environmental Origin of Resistance of Aspergillus fumigatus to Medical Triazoles

We reported the emergence of resistance to medical triazoles of Aspergillus fumigatus isolates from patients with invasive aspergillosis. A dominant resistance mechanism was found, and we hypothesized that azole resistance might develop through azole exposure in the environment rather than in azole-treated patients. We investigated if A. fumigatus isolates resistant to medical triazoles are present in our environment by sampling the hospital indoor environment and soil from the outdoor environment. Antifungal susceptibility, resistance mechanisms, and genetic relatedness were compared with those of azole-resistant clinical isolates collected in a previous study. Itraconazole-resistant A. fumigatus (five isolates) was cultured from the indoor hospital environment as well as from soil obtained from flower beds in proximity to the hospital (six isolates) but never from natural soil. Additional samples of commercial compost, leaves, and seeds obtained from a garden center and a plant nursery were also positive (four isolates). Cross-resistance was observed for voriconazole, posaconazole, and the azole fungicides metconazole and tebuconazole. Molecular analysis showed the presence of the dominant resistance mechanism, which was identical to that found in clinical isolates, in 13 of 15 environmental isolates, and it showed that environmental and clinical isolates were genetically clustered apart from nonresistant isolates. Patients with azole-resistant aspergillosis might have been colonized with azole-resistant isolates from the environment.Invasive aspergillosis is a fungal disease caused by Aspergillus species that primarily affects immunocompromised patients, such as those treated for hematological malignancy. Patients may become infected by inhalation of ambient air that contains fungal spores. The Aspergillus conidia can penetrate into the alveoli and if not effectively removed, may germinate, proliferate, and cause invasive aspergillosis. Mortality and morbidity due to invasive aspergillosis remain a significant problem.Triazoles, such as itraconazole (ITZ), voriconazole, and posaconazole, are used increasingly in the management of patients with this disease. Although the risk of resistance due to the increased use of triazoles is considered low (11), we recently observed ITZ resistance rapidly emerging in clinical Aspergillus fumigatus isolates (19, 22, 24, 25). Azole resistance was observed in up to 6% of patients in our hospital and in up to 14.5% of isolates sent to our laboratory from other hospitals in The Netherlands, which were obtained from patients with aspergillus disease (19). Furthermore, azole resistance has been reported in other European countries (3, 13, 19). The ITZ-resistant isolates also showed significantly reduced susceptibility to the other mold-active medical triazoles voriconazole and posaconazole (19). A substitution of leucine for histidine at codon 98 (L98H), combined with a 34-bp tandem repeat (designated TR) in the promoter region of the cyp51A gene (TR/L98H), which is the target for antifungal azoles, was found in 94% of isolates (14, 19, 24).Azole resistance can develop through the exposure of the fungus to azole compounds, which may occur in azole-treated patients or through the use of azole compounds in the environment. The dominance of a single resistance mechanism is difficult to explain by resistance development in individual azole-treated patients, as one would expect multiple resistance mechanisms to develop. Also, spread by person-to-person transmission of any Aspergillus isolate is highly unlikely. As inhalation of airborne aspergillus spores is the common route of infection for aspergillus diseases, we hypothesized that the dominance of a single resistance mechanism in clinical ITZ-resistant isolates was more consistent with acquisition from a common environmental source (19). If azole-resistant A. fumigatus is present in our environment, patients could inhale resistant spores and subsequently develop azole-resistant disease. Indeed, azole-resistant aspergillosis was reported in azole-naïve patients, indicating that resistance does not exclusively develop during azole therapy (24).Favorable conditions for resistance development are exposure to azole compounds and the presence of reproducing fungus (1). A. fumigatus is abundantly present in our environment as saprophytic, reproducing fungi, most notably in soil and compost. Furthermore, azoles are commonly used for plant protection as well as material preservation. Therefore, it appears that resistance development in A. fumigatus is feasible in the environment, and isolates that develop resistance to fungicides might be cross-resistant to medical triazoles.We investigated if A. fumigatus isolates that are present in our environment are resistant to medical triazoles and if they are cross-resistant to azole fungicides. Furthermore, we characterized the isolates by microsatellite typing in order to determine if they were genetically related to clinical A. fumigatus isolates previously obtained from patients cared for in our University Medical Center.     

Correlation between broth microdilution and disk diffusion methods for antifungal susceptibility testing of caspofungin, voriconazole, amphotericin B, itraconazole and fluconazole against Candida glabrata

Candida glabrata is one of the most frequent organisms isolated from superficial and invasive fungal infections, after Candida albicans. This organism also exhibits intrinsically low susceptibility to azole antifungals and treatment often fails. The microdilution method is not very practical for use in routine susceptibility testing in the clinical laboratory, thus necessitating the use of other methods. In this study, we compared the in vitro activity of five antifungal agents in three different groups (echinocandin, polyene and azole) against 50 C. glabrata isolates by broth microdilution and disk diffusion methods recommended by Clinical Laboratory Standards Institute CLSI M27-A3 and CLSI M44-A, respectively. All the isolates were susceptible to amphotericin B (100%) and 98% of the isolates were susceptible to caspofungin by the broth microdilution method. Within the azole group drugs, voriconazole was the most active followed by fluconazole and itraconazole in vitro. The highest rate of resistance was obtained against itraconazole with a high number of isolates defined as susceptible-dose dependent or resistant. Although the disk diffusion method is easy to use in clinical laboratories, it shows very poor agreement with the reference method for fluconazole and itraconazole against C. glabrata (8% and 14%, respectively).     

RTA2, a novel gene involved in azole resistance in Candida albicans

Widespread and repeated use of azoles, particularly fluconazole, has led to the rapid development of azole resistance in Candida albicans. Overexpression of CDR1, CDR2, and CaMDR1 has been reported contributing to azole resistance in C. albicans. In this study, hyper-resistant C. albicans mutant, with the above three genes deleted, was obtained by exposure to fluconazole and fluphenezine for 28 passages. Thirty-five differentially expressed genes were identified in the hyper-resistant mutant by microarray analysis; among the 13 up-regulated genes, we successfully constructed the rta2 and ipf14030 null mutants in C. albicans strain with deletions of CDR1, CDR2 and CaMDR1. Using spot dilution assay, we demonstrated that the disruption of RTA2 increased the susceptibility of C. albicans to azoles while the disruption of IPF14030 did not influence the sensitivity of C. albicans to azoles. Meanwhile, we found that ectopic overexpression of RTA2 in C. albicans strain with deletions of CDR1, CDR2 and CaMDR1 conferred resistance to azoles. RTA2 expression was found elevated in clinical azole-resistant isolates of C. albicans. In conclusion, our findings suggest that RTA2 is involved in the development of azole resistance in C. albicans.     

Novel point mutations in the ERG11 gene in clinical isolates of azole resistant Candida species

The azoles are the class of medications most commonly used to fight infections caused by Candida sp. Typically, resistance can be attributed to mutations in ERG11 gene (CYP51) which encodes the cytochrome P450 14α-demethylase, the primary target for the activity of azoles. The objective of this study was to identify mutations in the coding region of theERG11 gene in clinical isolates of Candidaspecies known to be resistant to azoles. We identified three new synonymous mutations in the ERG11 gene in the isolates of Candida glabrata (C108G, C423T and A1581G) and two new nonsynonymous mutations in the isolates of Candida krusei - A497C (Y166S) and G1570A (G524R). The functional consequence of these nonsynonymous mutations was predicted using evolutionary conservation scores. The G524R mutation did not have effect on 14α-demethylase functionality, while the Y166S mutation was found to affect the enzyme. This observation suggests a possible link between the mutation and dose-dependent sensitivity to voriconazole in the clinical isolate of C. krusei. Although the presence of the Y166S in phenotype of reduced azole sensitivity observed in isolate C. kruseidemands investigation, it might contribute to the search of new therapeutic agents against resistant Candida isolates.     

Specific interactions between the Candida albicans ABC transporter Cdr1p ectodomain and a d-octapeptide derivative inhibitor

Overexpression of the Candida albicans ATP‐binding cassette transporter CaCdr1p causes clinically significant resistance to azole drugs including fluconazole (FLC). Screening of a ～ 1.89 × 10⁶ member d ‐octapeptide combinatorial library that concentrates library members at the yeast cell surface identified RC21v3, a 4‐methoxy‐2,3,6‐trimethylbenzenesulphonyl derivative of the d ‐octapeptide d ‐NH₂‐FFKWQRRR‐CONH₂, as a potent and stereospecific inhibitor of CaCdr1p. RC21v3 chemosensitized Saccharomyces cerevisiae strains overexpressing CaCdr1p but not other fungal ABC transporters, the C. albicans MFS transporter CaMdr1p or the azole target enzyme CaErg11p, to FLC. RC21v3 also chemosensitized clinical C. albicans isolates overexpressing CaCDR1 to FLC, even when CaCDR2 was overexpressed. Specific targeting of CaCdr1p by RC21v3 was confirmed by spontaneous RC21v3 chemosensitization‐resistant suppressor mutants of S. cerevisiae expressing CaCdr1p. The suppressor mutations introduced a positive charge beside, or within, extracellular loops 1, 3, 4 and 6 of CaCdr1p or an aromatic residue near the extracytoplasmic end of transmembrane segment 5. The mutations did not affect CaCdr1p localization or CaCdr1p ATPase activity but some increased susceptibility to the CaCdr1p substrates FLC, rhodamine 6G, rhodamine 123 and cycloheximide. The suppressor mutations showed that the drug‐like CaCdr1p inhibitors FK506, enniatin, milbemycin α11 and milbemycin β9 have modes of action similar to RC21v3.     

Inhibition of fungal ABC transporters by unnarmicin A and unnarmicin C, novel cyclic peptides from marine bacterium

Novel inhibitors of fungal ATP-binding cassette transporters were obtained by screening compounds and crude extracts from marine-derived fungi and bacteria using disk diffusion assays of Saccharomyces cerevisiae strains overexpressing a variety of fungal multi-drug efflux pumps. The cyclodepsipeptides unnarmicin A and unnarmicin C were able to sensitize cells overexpressing azole drug pumps ScPdr5p, CaCdr1p, CgCdr1p, and CgPdh1p to sub-MIC concentrations of fluconazole without affecting the growth of CaCdr2p and CaMdr1p overexpressing cells. Unnarmicin A and unnarmicin C were potent inhibitors of rhodamine 6G efflux of CaCdr1p expressing cells with IC₅₀ values of 3.61 and 5.65 μM, respectively. They inhibited the in vitro CaCdr1p ATPase activity at IC₅₀ values of 0.495 and 0.688 μM, respectively. And most importantly, they were able to sensitize azole-resistant Candida albicans clinical isolates to fluconazole. Unnarmicin A and unnarmicin C are candidate efflux pump inhibitors with the potential to be used as adjuvants for antifungal chemotherapy.