Novel Non-Hot Spot Modification in Fks1 of Candida auris Confers Echinocandin Resistance.

We determined the echinocandin susceptibility and FKS1 genotypes of 13 clinical isolates of Candida auris that were recovered from 4 patients at a tertiary care center in Salvador, Brazil. Three isolates were categorized as echinocandin-resistant, and they harbored a novel FKS1 mutation that led to an amino acid change W691L located downstream from hot spot 1. When introduced to echinocandin-susceptible C. auris strains by CRISPR/Cas9, Fks1 W691L induced elevated MIC values to all echinocandins (anidulafungin, 16 to 32×; caspofungin, >64×; micafungin, >64×).

The impact of COVID on bacterial sepsis.

PURPOSE: To identify the predictors of morbidity and mortality in matched COVID-19 positive and negative patients who were septic with Gram positive or Gram negative infections. METHODS: We conducted a retrospective review, from March to October 2020, of matched septic patients at five Hackensack Meridian Health hospitals who had bacteremia with Staphylococcus aureus, Klebsiella pneumoniae or Escherichia coli with and without COVID-19. We extracted patient demographics, comorbidities and clinical outcomes data using ICD-10 codes. Bacterial isolates were compared by whole genome sequencing analysis. Multivariate logistic regression was used to analyze independent predictors of morbidity and mortality. RESULTS: A total of 208 patients were grouped by positive bloodstream infection (BSI) with COVID-19 (n = 104) and without COVID-19 (n = 104). Most patients were over age 50 (90% vs. 89%) and Caucasian (78% vs. 86%). Inpatient mortality was higher in patients with COVID-19 for both GP (35% vs. 8%, p < 0.05) and GN (28% vs. 10%, p < 0.05) BSIs. Patients with Gram positive (GP) BSIs had a significant increase in mortality risk (OR 4.5, CI 1.4-14.5, p < 0.05) in contrast to those with Gram negative (GN) infections (OR 0.4, CI 0.4-4.0, p = 0.4). CONCLUSION: Concurrent COVID-19 infection is associated with a significant increase in morbidity and mortality in patients with GP and GN BSIs. Patients with S. aureus BSIs with COVID-19 are more likely to develop shock and respiratory failure and have higher rates and odds of mortality than those without COVID-19. These findings provide an essential insight into the care of these patients, especially those co-infected with Staphylococcus aureus.

Impact of Erg11 Amino Acid Substitutions Identified in Candida auris Clade III Isolates on Triazole Drug Susceptibility.

ERG11 sequencing of 28 Candida auris clade III isolates revealed the presence of concomitant V125A and F126L substitutions. Heterologous expression of Erg11-V125A/F126L in Saccharomyces cerevisiae led to reduced fluconazole and voriconazole susceptibilities. Generation of single substitution gene variants through site-directed mutagenesis uncovered that F126L primarily contributes to the elevated triazole MICs. A similar yet diminished pattern of reduced susceptibility was observed with the long-tailed triazoles posaconazole and itraconazole for the V125A/F126L, F126L, Y132F, and K143R alleles.

Detection of Candida auris antifungal drug resistance markers directly from clinical skin swabs.

Accurate and rapid assessment of Candida auris antifungal drug resistance is crucial for effective infection prevention and control actions, and patient management. Here, performance of a molecular diagnostic platform, enabling rapid identification of FKS1 and ERG11 mutations conferring echinocandin and azole resistance, respectively, was evaluated on a panel of clinical skin swabs. Gene sequencing and antifungal susceptibility testing were used as "gold standard". All swabs were correctly categorized as harboring wild-type or mutant C. auris.

Rapid Detection of ERG11-Associated Azole Resistance and FKS-Associated Echinocandin Resistance in Candida auris.

Candida auris is an emerging multidrug-resistant yeast that can cause serious invasive infections. The accurate and rapid assessment of antifungal resistance is important for effective patient management. A novel and highly accurate diagnostic platform was established for the rapid identification of ERG11 mutations conferring azole resistance and FKS1 mutations associated with echinocandin resistance in C. auris Using allele-specific molecular beacons and DNA melting curve analysis following asymmetric PCR, a duplex ERG11 assay and a simplex FKS1 HS1 assay were developed to identify the most prominent resistance-associated mutations (Y132F and K143R in ERG11; S639F in FKS1 HS1) within 2 h. Assays were validated by testing a panel of 94 C. auris clinical isolates in a blind manner. The molecular diagnostic results from the assays were 100% concordant with DNA sequencing results. This platform has the potential to overcome the deficiencies of existing in vitro susceptibility-based assays to identify azole- and/or echinocandin-resistant C. auris, and thus, it holds promise as a surrogate diagnostic method to direct antifungal therapy more effectively.

Spontaneous Mutational Frequency and FKS Mutation Rates Vary by Echinocandin Agent against Candida glabrata.

Echinocandins are front-line agents for treatment of invasive candidiasis. There are no reported agent-specific differences in Candida mutational frequency of resistance or propensity to develop FKS mutations. The objective of this study was to measure spontaneous and FKS mutation rates among Candida glabrata strains. Twenty bloodstream isolates from patients with or without prior echinocandin exposure were included. Minimum inhibitory concentrations (MICs), minimum fungicidal concentrations (MFCs), and mutation prevention concentrations were higher for caspofungin than for anidulafungin (P < 0.0001) and micafungin (P < 0.0001). Mutational frequencies of resistance at 3× the baseline MIC were highest for caspofungin and lowest for micafungin. A total of 247 isolates were recovered at or above the MFC for caspofungin (n = 159), anidulafungin (n = 74), or micafungin (n = 14). Agent-specific MIC increases were noted for anidulafungin and caspofungin, but not micafungin. Thirty-three percent of isolates harbored hot spot mutations in FKS1 (n = 6) or FKS2 (n = 76). Mutations at the Ser629 (Fks1) or Ser663 (Fks2) loci were more common after selection with anidulafungin or micafungin than with caspofungin (P = 0.003). Four isolates demonstrated >4-fold increases in MICs without FKS hot spot mutations; three of these harbored Fks2 mutations upstream of hot spot 1. The final isolate was FKS1 and FKS2 wild-type, but the 50% inhibitory concentrations of caspofungin and micafungin were increased 2.7- and 8-fold, respectively. In conclusion, micafungin may be superior in vitro to the other agents in limiting the emergence of resistance among C. glabrata Caspofungin exposure may be most likely to promote resistance development. These data provide a foundation for future investigations of newly developed echinocandin agents.

PCR-RFLP assays for species-specific identification of fungi belonging to Scopulariopsis and related genera.

Fungi of the Scopulariopsis genus, commonly found in the environment, are opportunistic pathogens that can cause various types of human infections. So far, no efficient molecular method has been developed for species differentiation among Scopulariopsis and related genera. In order to advance this field, we have evaluated performance of polymerase chain reaction restriction fragment length polymorphism (PCR-RFLP) assays, based on cytochrome c oxidase subunit 1 and ß-tubulin genes. The assays resulted in 2-10 restriction patterns, depending on the gene amplified and restriction enzyme applied. Pooled analysis of the patterns allowed to propose an algorithm, that can be successfully used for an accurate species-specific identification of 21 species of the Scopulariopsis-like fungi.

FKS2 and FKS3 Genes of Opportunistic Human Pathogen Candida albicans Influence Echinocandin Susceptibility.

Candida albicans, a prevailing opportunistic fungal pathogen of humans, has a diploid genome containing three homologous FKS genes that are evolutionarily conserved. One of these, the essential gene FKS1, encodes the catalytic subunit of glucan synthase, which is the target of echinocandin drugs and also serves as a site of drug resistance. The other two glucan synthase-encoding genes, FKS2 and FKS3, are also expressed, but their roles in resistance are considered unimportant. However, we report here that expression of FKS1 is upregulated in strains lacking either FKS2 or FKS3 Furthermore, in contrast to what is observed in heterozygous FKS1 deletion strains, cells lacking FKS2 or FKS3 contain increased amounts of cell wall glucan, are more resistant to echinocandin drugs, and consistently are tolerant to cell wall-damaging agents. Our data indicate that C. albicansFKS2 and FKS3 can act as negative regulators of FKS1, thereby influencing echinocandin susceptibility.

Understanding Echinocandin Resistance in the Emerging Pathogen Candida auris.

Candida auris has simultaneously emerged on five continents as a fungal pathogen causing nosocomial outbreaks. The challenges in the treatment of C. auris infections are the variable antifungal susceptibility profiles among clinical isolates and the development of resistance to single or multiple classes of available antifungal drugs. Here, the in vitro susceptibility to echinocandin antifungal drugs was determined and FKS1 sequencing was performed on 106 C. auris clinical isolates. Four isolates were identified to be resistant to all tested echinocandins (MIC ≥ 4 mg/liter) and harbored an S639F mutation in FKS1 hot spot region 1. All remaining isolates were FKS1 wild type (WT) and echinocandin susceptible, with micafungin being the most potent echinocandin (MIC50 = 0.125 mg/liter). Antifungal susceptibility testing with caspofungin was challenging due to the fact that all FKS1 WT isolates exhibited an Eagle effect (also known as the paradoxical growth effect), which occurred at various intensities. To assess whether the Eagle effect resulted in pharmacodynamic resistance, 8 representative isolates were evaluated for their in vivo drug response in a murine model of invasive candidiasis. All isolates were susceptible to caspofungin at a human therapeutic dose, except for those harboring the S639F mutation. The data suggest that only isolates carrying mutations in FKS1 are echinocandin resistant and that routine in vitro testing of C. auris isolates for susceptibility to caspofungin by the broth microdilution method should be viewed cautiously or avoided.

Limited ERG11 Mutations Identified in Isolates of Candida auris Directly Contribute to Reduced Azole Susceptibility.

Multiple Erg11 amino acid substitutions were identified in clinical isolates of Candida auris originating from India and Colombia. Elevated azole MICs were detected in Saccharomyces cerevisiae upon heterologous expression of C. aurisERG11 alleles that encoded for Y132F or K143R substitutions; however, expression of alleles encoding I466M, Y501H, or other clade-defined amino acid differences yielded susceptible MICs. Similar to other Candida species, specific C. aurisERG11 mutations resulted directly in reduced azole susceptibility.

Direct Detection of Emergent Fungal Pathogen Candida auris in Clinical Skin Swabs by SYBR Green-Based Quantitative PCR Assay.

The recent emergence of the multidrug-resistant and pathogenic yeast Candida auris continues to cause public health concern worldwide. C. auris is alarming because it causes health care-associated outbreaks and can establish invasive infections with high mortality rates. Transmission between patients is facilitated by the ability of C. auris to persistently colonize multiple body sites, including the skin, and survive for weeks on surfaces in health care settings. Rapid identification of colonized patients is needed to implement timely infection control measures. Currently, CDC laboratories use an enrichment culture-based approach that can take up to 2 weeks to identify C. auris from composite swabs from the bilateral axillae and groin. A rapid SYBR green quantitative PCR (qPCR) assay that can identify C. auris in a single day was recently described. In this study, we developed the SYBR green qPCR assay further by incorporating a DNA extraction procedure for skin swabs and by including an internal amplification control based on the distinguishable melt curve of a lambda DNA amplicon. The assay was conducted using 103 clinical axilla/groin skin swab samples. Using the enrichment culture-based approach as a gold standard, we determined that the SYBR green C. auris qPCR has a sensitivity of 0.93 and specificity of 0.96. Overall, we found that the SYBR green C. auris qPCR assay can be successfully applied for rapid and accurate detection of C. auris in patient skin swabs, thereby increasing diagnostic options for this emerging pathogen.

A multicentre study of antifungal susceptibility patterns among 350 Candida auris isolates (2009-17) in India: role of the ERG11 and FKS1 genes in azole and echinocandin resistance.

Background: Candida auris has emerged globally as an MDR nosocomial pathogen in ICU patients. Objectives: We studied the antifungal susceptibility of C. auris isolates (n = 350) from 10 hospitals in India collected over a period of 8 years. To investigate azole resistance, ERG11 gene sequencing and expression profiling was conducted. In addition, echinocandin resistance linked to mutations in the C. auris FKS1 gene was analysed. Methods: CLSI antifungal susceptibility testing of six azoles, amphotericin B, three echinocandins, terbinafine, 5-flucytosine and nystatin was conducted. Screening for amino acid substitutions in ERG11 and FKS1 was performed. Results: Overall, 90% of C. auris were fluconazole resistant (MICs 32 to ≥64 mg/L) and 2% and 8% were resistant to echinocandins (≥8 mg/L) and amphotericin B (≥2 mg/L), respectively. ERG11 sequences of C. auris exhibited amino acid substitutions Y132 and K143 in 77% (n = 34/44) of strains that were fluconazole resistant whereas WT genotypes, i.e. without substitutions at these positions, were observed in isolates with low fluconazole MICs (1-2 mg/L) suggesting that these substitutions confer a phenotype of resistance to fluconazole similar to that described for Candida albicans. No significant expression of ERG11 was observed, although expression was inducible in vitro with fluconazole exposure. Echinocandin resistance was linked to a novel mutation S639F in FKS1 hot spot region I. Conclusions: Overall, 25% and 13% of isolates were MDR and multi-azole resistant, respectively. The most common resistance combination was azoles and 5-flucytosine in 14% followed by azoles and amphotericin B in 7% and azoles and echinocandins in 2% of isolates.

The Gastrointestinal Tract Is a Major Source of Echinocandin Drug Resistance in a Murine Model of Candida glabrata Colonization and Systemic Dissemination.

Candida species are a part of the human microbiome and can cause systemic infection upon immune suppression. Candida glabrata infections are increasing and have greater rates of antifungal resistance than other species. Here, we present a C. glabrata gastrointestinal (GI) colonization model to explore whether colonized yeast exposed to caspofungin, an echinocandin antifungal, develop characteristic resistance mutations and, upon immunosuppression, breakthrough causing systemic infection. Daily therapeutic dosing (5 mg/kg of body weight) of caspofungin resulted in no reduction in fecal burdens, organ breakthrough rates similar to control groups, and resistance rates (0 to 10%) similar to those reported clinically. Treatment with 20 mg/kg caspofungin initially reduced burdens, but a rebound following 5 to 9 days of treatment was accompanied by high levels of resistance (FKS1/FKS2 mutants). Although breakthrough rates decreased in this group, the same FKS mutants were recovered from organs. In an attempt to negate drug tolerance that is critical for resistance development, we cotreated mice with daily caspofungin and the chitin synthase inhibitor nikkomycin Z. The largest reduction (3 log) in GI burdens was obtained within 3 to 5 days of 20 mg/kg caspofungin plus nikkomycin treatment. Yet, echinocandin resistance, characterized by a novel Fks1-L630R substitution, was identified following 5 to 7 days of treatment. Therapeutic caspofungin plus nikkomycin treatment left GI burdens unchanged but significantly reduced organ breakthrough rates (20%; P < 0.05). Single-dose pharmacokinetics demonstrated low levels of drug penetration into the GI lumen posttreatment with caspofungin. Overall, we show that C. glabrata echinocandin resistance can arise within the GI tract and that resistant mutants can readily disseminate upon immunosuppression.

Rapid and Accurate Molecular Identification of the Emerging Multidrug-Resistant Pathogen Candida auris.

Candida auris is an emerging multidrug-resistant fungal pathogen causing nosocomial and invasive infections associated with high mortality. C. auris is commonly misidentified as several different yeast species by commercially available phenotypic identification platforms. Thus, there is an urgent need for a reliable diagnostic method. In this paper, we present fast, robust, easy-to-perform and interpret PCR and real-time PCR assays to identify C. auris and related species: Candida duobushaemulonii, Candida haemulonii, and Candida lusitaniae Targeting rDNA region nucleotide sequences, primers specific for C. auris only or C. auris and related species were designed. A panel of 140 clinical fungal isolates was used in both PCR and real-time PCR assays followed by electrophoresis or melting temperature analysis, respectively. The identification results from the assays were 100% concordant with DNA sequencing results. These molecular assays overcome the deficiencies of existing phenotypic tests to identify C. auris and related species.

Rapid Detection of FKS-Associated Echinocandin Resistance in Candida glabrata.

A novel and highly accurate diagnostic assay platform was established for rapid identification of FKS mutations associated with echinocandin resistance in Candida glabrata The assay platform uses allele-specific molecular beacon and DNA melt analysis following asymmetric PCR. A dual assay for FKS1 and FKS2 was developed to identify within 3 h the most common and clinically relevant resistance-associated mutations, including 8 FKS1 HS1 (wild type [WT], S629P, F625S, D632Y, D632E [T1896G], D632E [T1896A], I634V, and F625F) and 7 FKS2 HS1 (WT, F659del, F659S, F659V, F659L, S663P, and S663F) genotypes. A blinded panel of 188 C. glabrata clinical isolates was tested by both assays. The molecular diagnostic results from the dual assay were 100% concordant with data obtained from DNA sequencing. This platform has the potential to overcome the deficiencies of existing in vitro susceptibility-based assays to identify echinocandin-resistant C. glabrata and holds promise as a surrogate diagnostic method to better direct echinocandin therapy.

Rapid Assays for Specific Detection of Fungi of Scopulariopsis and Microascus Genera and Scopulariopsis brevicaulis Species.

PURPOSE: Fungi of Scopulariopsis and Microascus genera cause a wide range of infections, with S. brevicaulis being the most prevalent aetiological agent of mould onychomycosis. Proper identification of these pathogens requires sporulating culture, which considerably delays the diagnosis. So far, sequencing of rDNA regions of clinical isolates has produced ambiguous results due to the lack of reference sequences in publicly available databases. Thus, there is a clear need for the development of new molecular methods that would provide simple, rapid and highly specific identification of Scopulariopsis and Microascus species. The objective of this study was to develop simple and fast assays based on PCR and real-time PCR for specific detection of fungi from Scopulariopsis and Microascus genera, and separately, S. brevicaulis species. METHODS: On the basis of alignment of ß-tubulin gene sequences, Microascus/Scopulariopsis-specific primers were designed and S. brevicaulis-specific primers were reevaluated. DNA from cultured fungal isolates, extracted in a two-step procedure, was used in Microascus/Scopulariopsis-specific and S. brevicaulis-specific PCR and real-time PCR followed by electrophoresis or melting temperature analysis, respectively. RESULTS: The specificity of the assays was confirmed, as positive results were obtained only for Scopulariopsis spp. and Microascus spp. isolates tested in Microascus/Scopulariopsis-specific assay, and only for S. brevicaulis and S. koningii (syn. S. brevicaulis) isolates in a S. brevicaulis-specific assay, respectively, and no positive results were obtained neither for other moulds, dermatophytes, yeast-like fungi, nor for human DNA. CONCLUSIONS: The developed assays enable fast and unambiguous identification of Microascus spp. and Scopulariopsis spp. pathogens.

PCR Detection of Scopulariopsis brevicaulis.

Scopulariopsis brevicaulis is known as the most common etiological factor of the mould toenail infections. There are also reports indicating that S. brevicaulis could cause organ and disseminated infections. Nowadays microscopic observations from the direct sample and culture are crucial for the appropriate recognition of the infection. In this paper a PCR-based method for S. brevicaulis detection is presented. The specificity of the reaction was confirmed, as positive results were obtained only for tested S. brevicaulis isolates and no positive results were obtained for other moulds, dermatophytes, yeast-like fungi, and human DNA.

CYP3A4 overexpression enhances the cytotoxicity of the antitumor triazoloacridinone derivative C-1305 in CHO cells.

AIM: To examine how the higher expression level of CYP3A4 isoenzyme influenced the cytotoxicity of the antitumor triazoloacridinone derivative C-1305 in Chinese hamster ovary (CHO) cells. METHODS: Three CHO cell lines were examined: wild-type CHO cells; CHO-HR cells with overexpression of human cytochrome P450 reductase (CPR); and CHO-HR-3A4 cells with coexpression of human CYP3A4 and CPR. Cellular responses caused by C-1305 were monitored using DAPI staining, cell cycle analysis, phosphatydilserine externalization analysis and SA-ß-galactosidase expression analysis. Cell viability was assessed with simultaneous FDA and PI staining. RESULTS: Treatment with C-1305 for 72 h exhibited different levels of cytotoxicity in the 3 cell lines, and the values of IC80 in CHO, CHO-HR and CHO-HR-3A4 cells were 0.087±0.005, 0.032±0.0001, and 0.064±0.0095 µmol/L, respectively. The cell cycle analysis revealed that both CHO and CHO-HR cells underwent transient G(2)/M arrest, whereas CHO-HR-3A4 cells did not accumulate in this phase. Prolonged exposure up to 120 h caused time-dependent increase in the sub-G(1) fraction in all the 3 cell lines. Treatment with C-1305 caused cell death through apoptosis and necrosis. However, these processes were more pronounced in the transfected CHO cells than in the wild-type cells. The cells surviving after C-1305 exposure underwent senescence. CONCLUSION: CYP3A4 overexpression potently enhances the cellular responses (apoptosis, necrosis and senescence) caused by C-1305 in CHO cells.

Deciphering Candida auris Paradoxical Growth Effect (Eagle Effect) in Response to Echinocandins.

The paradoxical growth effect (PGE; also known as Eagle effect) is an in vitro phenomenon observed during antifungal susceptibility testing (AFST). In PGE, some fungal isolates grow in medium containing high concentrations of an echinocandin, above the minimal inhibitory concentration (MIC), despite being fully susceptible at lower concentrations. The presence of PGE complicates the assignment of isolates to susceptible or resistant category, especially in the case of newly emerged pathogens like Candida auris, for which susceptibility breakpoints are not established.Here we describe a protocol aiding in the determination of whether a given C. auris isolate is echinocandin-resistant or echinocandin-susceptible but exhibiting paradoxical growth.