Comparison of amphotericin B lipid complex, deoxycholate amphotericin B, fluconazole, and anidulafungin activity against Candida albicans biofilm isolated from breakthrough candidemia / Comparación de la actividad del complejo lipídico de anfotericina B, anfotericina B desoxicolato, fluconazol y anidulafungina frente al biofilrm de Candida albicans aisladas de candidemia de brecha

Introduction: Biofilm formation causes virulence and resistance in Candida albicans. However, little is known about breakthrough candidemia isolates. We evaluated the antifungal activity of fluconazole, anidulafungin, deoxycholate amphotericin B (dAMB), and amphotericin B lipid complex (ABLC) against biofilms of C. albicans isolated from patients with breakthrough candidemia. Methods: The present study used strains of C. albicans isolated from breakthrough and non-breakthrough candidemia patients (control group). The susceptibility of planktonic cells to amphotericin B, anidulafungin, and fluconazole was determined by broth microdilution. Antifungal activity in sessile cells was evaluated using the minimum biofilm eradication concentration (MBEC), metabolic activity was estimated by reducing MTT, and biomass was estimated using crystal violet retention. Results: The planktonic strains were susceptible to amphotericin B, anidulafungin, and fluconazole, with minimum inhibitory concentrations of 1, ≤0.03, and 2mg/L, respectively. However, fluconazole and anidulafungin did not exert an antifungal effect on biofilms. Additionally, dAMB and ABCL reduced the metabolic activity and biomass. However, eradication was only achieved using 16mg/L dAMB. C. albicans isolates of breakthrough candidemia exhibited strong biofilm production, and the in vitro activity of available therapeutic options was poor. Conclusion: In the present study, only dAMB and ABCL exhibited antibiofilm effects against sessile breakthrough candidemia isolates.(AU)

Introducción: La formación de biofilm se asocia con la virulencia y la resistencia al tratamiento de Candida albicans (C. albicans) sin embargo, son poco conocidas las características de los aislamientos procedentes de pacientes con candidemias de brecha. Evaluamos la actividad antifúngica de fluconazol, anidulafungina, anfotericina B desoxicolato (dAMB) y el complejo lipídico de la anfotericina B (ABLC) frente a biofilms de C. albicans aisladas de pacientes con candidemia de brecha. Métodos: Se utilizaron cepas de C. albicans aisladas de candidemias de brecha y de otras candidemias (grupo control). La sensibilidad de las células planctónicas a la anfotericina B, la anidulafungina y el fluconazol se determinó mediante el método de microdilución en caldo. En células sésiles, la actividad antifúngica se evaluó mediante la concentración miníma de erradicación de biofilm (MBEC), la actividad metabólica se estimó mediante la reducción de MTT y la biomasa mediante la retención de cristal violeta. Resultados: Las cepas en forma planctónica fueron sensibles a la anfotericina B, anidulafungina y fluconazol, con CMI de 1 mg/L, ≤ 0,03 y 2 mg/L, respectivamente; sin embargo, no se observó efecto antifúngico sobre los biofilms con fluconazol o anidulafungina. Con dAMB y ABCL se observó una reducción de la actividad metabólica y de la biomasa, pero la erradicación solo se consiguió con 16 mg/L de dAMB. Las cepas de C. albicans que causan candidemia de brecha producen abundante biofilm y las opciones terapéuticas disponibles no son activas in vitro frente a ellas. Conclusión: Solo dAMB y ABCL exhibieron efecto antibiofilm frente a los aislamientos de C. albicans sésiles y planctónicos.(AU)

In vitro combination of antifungal drugs with tacrolimus (FK506) holds promise against clinical Candida species, including Candida auris.

In vitro interactions between tacrolimus, a calcineurin inhibitor, and fluconazole, itraconazole, caspofungin, or anidulafungin were evaluated against Candida auris, C. albicans, C. parapsilosis, and C. glabrata (each five strains). Tacrolimus-itraconazole, tacrolimus-caspofungin, and tacrolimus-fluconazole combinations resulted in synergistic interactions against 95%, 90%, and 60% of Candida isolates, respectively. However, tacrolimus-anidulafungin resulted in only a 35% synergistic effect. A combination of tacrolimus and itraconazole was most potent with synergy against 100% of C. auris, C. parapsilosis, and C. glabrata isolates. Of note, no antagonistic interaction was found.

Polypharmacological repurposing approach identifies approved drugs as potential inhibitors of Mycobacterium tuberculosis.

Mycobacterium tuberculosis (M. tb), the causative pathogen of tuberculosis (TB) remains the leading cause of death from single infectious agent. Furthermore, its evolution to multi-drug resistant (MDR) and extremely drug-resistant (XDR) strains necessitate de novo identification of drug-targets/candidates or to repurpose existing drugs against known targets through drug repurposing. Repurposing of drugs has gained traction recently where orphan drugs are exploited for new indications. In the current study, we have combined drug repurposing with polypharmacological targeting approach to modulate structure-function of multiple proteins in M. tb. Based on previously established essentiality of genes in M. tb, four proteins implicated in acceleration of protein folding (PpiB), chaperone assisted protein folding (MoxR1), microbial replication (RipA) and host immune modulation (S-adenosyl dependent methyltransferase, sMTase) were selected. Genetic diversity analyses in target proteins showed accumulation of mutations outside respective substrate/drug binding sites. Using a composite receptor-template based screening method followed by molecular dynamics simulations, we have identified potential candidates from FDA approved drugs database; Anidulafungin (anti-fungal), Azilsartan (anti-hypertensive) and Degarelix (anti-cancer). Isothermal titration calorimetric analyses showed that the drugs can bind with high affinity to target proteins and interfere with known protein-protein interaction of MoxR1 and RipA. Cell based inhibitory assays of these drugs against M. tb (H37Ra) culture indicates their potential to interfere with pathogen growth and replication. Topographic assessment of drug-treated bacteria showed induction of morphological aberrations in M. tb. The approved candidates may also serve as scaffolds for optimization to future anti-mycobacterial agents which can target MDR strains of M. tb.

Heightened Efficacy of Anidulafungin When Used in Combination with Manogepix or 5-Flucytosine against Candida auris In Vitro.

Candida auris is an emerging, multidrug-resistant fungal pathogen that causes refractory colonization and life-threatening, invasive nosocomial infections. The high proportion of C. auris isolates that display antifungal resistance severely limits treatment options. Combination therapies provide a possible strategy by which to enhance antifungal efficacy and prevent the emergence of further resistance. Therefore, we examined drug combinations using antifungals that are already in clinical use or are undergoing clinical trials. Using checkerboard assays, we screened combinations of 5-flucytosine and manogepix (the active form of the novel antifungal drug fosmanogepix) with anidulafungin, amphotericin B, or voriconazole against drug resistant and susceptible C. auris isolates from clades I and III. Fractional inhibitory concentration indices (FICI values) of 0.28 to 0.75 and 0.36 to 1.02 were observed for combinations of anidulafungin with manogepix or 5-flucytosine, respectively, indicating synergistic activity. The high potency of these anidulafungin combinations was confirmed using live-cell microfluidics-assisted imaging of the fungal growth. In summary, combinations of anidulafungin with manogepix or 5-flucytosine show great potential against both resistant and susceptible C. auris isolates.

Identification and susceptibility testing of oral candidiasis in advanced cancer patients.

BACKGROUND: Patients with advanced cancer are prone to develop different opportunistic oral infection due to anti-cancer treatment or the malignancies themselves. Studies of oral fungal samples show an increased prevalence of non-Candida albicans species in mixed oral infections with Candida albicans. Non-C. albicans and C. albicans are associated with varying degrees of resistance to azoles, which may have implications for treatment. This study aimed to assess the diversity and antifungal susceptibility of Candida species detected in the oral cavity. METHODS: An observational study with microbiological analysis was conducted. Clinical fungal isolates were collected from patients in a hospice unit in 2014-2016. Isolates were re-grown on chromID® Candida plates in 2020. Single colony of each species was re-cultivated and prepared for biochemical identification with a VITEK2® system and verified by gene sequencing. Etest was performed on RPMI agar, and the antifungals fluconazole, amphotericin B, anidulafungin and nystatin were applied. RESULTS: Fifty-six isolates from 45 patients were identified. Seven different Candida species and one Saccharomyces species were detected. The results of biochemical identification were confirmed with sequencing analysis. Thirty-six patients had mono infection, and nine out of 45 patients had 2-3 different species detected. Of C. albicans strains, 39 out of 40 were susceptible to fluconazole. Two non-C. albicans species were resistant to fluconazole, one to amphotericin B and three to anidulafungin. CONCLUSION: C. albicans was the predominant species, with a high susceptibility to antifungal agents. Different Candida species occur in both mono and mixed infections. Identification and susceptibility testing may therefore lead to more effective treatment and may prevent the development of resistance among patients with advanced cancer. TRAIL REGISTRATION: The study Oral Health in Advanced Cancer was registered at ClinicalTrials.gov (#NCT02067572) in 20/02/2014.

Comparison of amphotericin B lipid complex, deoxycholate amphotericin B, fluconazole, and anidulafungin activity against Candida albicans biofilm isolated from breakthrough candidemia.

INTRODUCTION: Biofilm formation causes virulence and resistance in Candida albicans. However, little is known about breakthrough candidemia isolates. We evaluated the antifungal activity of fluconazole, anidulafungin, deoxycholate amphotericin B (dAMB), and amphotericin B lipid complex (ABLC) against biofilms of C. albicans isolated from patients with breakthrough candidemia. METHODS: The present study used strains of C. albicans isolated from breakthrough and non-breakthrough candidemia patients (control group). The susceptibility of planktonic cells to amphotericin B, anidulafungin, and fluconazole was determined by broth microdilution. Antifungal activity in sessile cells was evaluated using the minimum biofilm eradication concentration (MBEC), metabolic activity was estimated by reducing MTT, and biomass was estimated using crystal violet retention. RESULTS: The planktonic strains were susceptible to amphotericin B, anidulafungin, and fluconazole, with minimum inhibitory concentrations of 1, ≤0.03, and 2mg/L, respectively. However, fluconazole and anidulafungin did not exert an antifungal effect on biofilms. Additionally, dAMB and ABCL reduced the metabolic activity and biomass. However, eradication was only achieved using 16mg/L dAMB. C. albicans isolates of breakthrough candidemia exhibited strong biofilm production, and the in vitro activity of available therapeutic options was poor. CONCLUSION: In the present study, only dAMB and ABCL exhibited antibiofilm effects against sessile breakthrough candidemia isolates.

The In Vitro Activity of Fluconazole, Amphotericin B and Echinocandins Against Cyberlindnera fabianii Planktonic Cells and Biofilms.

Until recently, little was known about the susceptibility pattern of Cyberlindnera fabianii (Cy. fabianii) planktonic cells and biofilms regarding the most frequently administered systemic antifungals, despite the high mortality rate and its potential role in catheter-related infections. In the current study, the activity of fluconazole, amphotericin B and echinocandins (anidulafungin, caspofungin and micafungin) was determined against planktonic and sessile cells of Cy. fabianii clinical isolates (n = 8). Planktonic minimum inhibitory concentrations (MICs) ranged from 1 to 2, from 0.25 to 1, from 0.015 to 0.06, from 0.03 to 0.12 and from 0.25 to 0.5 mg/l for fluconazole, amphotericin B, anidulafungin, caspofungin and micafungin, respectively. One-day-old biofilms were highly resistant to fluconazole (MIC ranged from 512 to > 512) compared to planktonic counterparts, but not to amphotericin B (MIC ranged from 0.25 to 2 mg/l) and echinocandins (MIC ranged from 0.06 to 2 mg/l). Based on the calculated planktonic killing rates, the highest activity was observed in the case of anidulafungin (k values ranged from 0.37 to 2.09), while micafungin, caspofungin, amphotericin B and fluconazole exerted 0.46-1.47, 0.14-0.86, -0.03 to 2.08 and -0.15 to 0.09 killing rate value ranges, respectively. The obtained in vitro planktonic and sessile susceptibility patterns suggest that echinocandins and amphotericin B may be the most reliable treatment option for the treatment of Cy. fabianii infections.

Antiviral activity and mechanism of the antifungal drug, anidulafungin, suggesting its potential to promote treatment of viral diseases.

BACKGROUND: The severe fever with thrombocytopenia syndrome disease (SFTS), caused by the novel tick-borne SFTS virus (SFTSV), was listed among the top 10 priority infectious disease by World Health Organization due to the high fatality rate of 5-30% and the lack of effective antiviral drugs and vaccines and therefore raised the urgent need to develop effective anti-SFTSV drugs to improve disease treatment. METHODS: The antiviral drugs to inhibit SFTSV infection were identified by screening the library containing 1340 FDA-approved drugs using the SFTSV infection assays in vitro. The inhibitory effect on virus entry and the process of clathrin-mediated endocytosis under different drug doses was evaluated based on infection assays by qRT-PCR to determine intracellular viral copies, by Western blot to characterize viral protein expression in cells, and by immunofluorescence assays (IFAs) to determine virus infection efficiencies. The therapeutic effect was investigated in type I interferon receptor defective A129 mice in vivo with SFTSV infection, from which lesions and infection in tissues caused by SFTSV infection were assessed by H&E staining and immunohistochemical analysis. RESULTS: Six drugs were identified as exerting inhibitory effects against SFTSV infection, of which anidulafungin, an antifungal drug of the echinocandin family, has a strong inhibitory effect on SFTSV entry. It suppresses SFTSV internalization by impairing the late endosome maturation and decreasing virus fusion with the membrane. SFTSV-infected A129 mice had relieving symptoms, reduced tissue lesions, and improved disease outcomes following anidulafungin treatment. Moreover, anidulafungin exerts an antiviral effect in inhibiting the entry of other viruses including SARS-CoV-2, SFTSV-related Guertu virus and Heartland virus, Crimean-Congo hemorrhagic fever virus, Zika virus, and Herpes simplex virus 1. CONCLUSIONS: The results demonstrated that the antifungal drug, anidulafungin, could effectively inhibit virus infection by interfering with virus entry, suggesting it may be utilized for the clinical treatment of infectious viral diseases, in addition to its FDA-approved use as an antifungal. The findings also suggested to further evaluate the anti-viral effects of echinocandins and their clinical importance for patients with infection of viruses, which may promote therapeutic strategies as well as treatments and improve outcomes pertaining to various viral and fungal diseases.

Activities of Manogepix and Comparators against 1,435 Recent Fungal Isolates Collected during an International Surveillance Program (2020).

We evaluated the in vitro activity of manogepix and comparator agents against 1,435 contemporary fungal isolates collected worldwide from 73 medical centers in North America, Europe, the Asia-Pacific region, and Latin America during 2020. Of the isolates tested, 74.7% were Candida spp.; 3.7% were non-Candida yeasts, including 27 Cryptococcus neoformans var. grubii (1.9%); 17.1% were Aspergillus spp.; and 4.5% were other molds. All fungal isolates were tested by reference broth microdilution according to CLSI methods. Based on MIC90 values, manogepix (MIC50/MIC90, 0.008/0.06 mg/liter) was 16- to 64-fold more active than anidulafungin, micafungin, and fluconazole against Candida spp. isolates and the most active agent tested. Similarly, manogepix (MIC50/MIC90, 0.5/1 mg/liter) was ≥8-fold more active than anidulafungin, micafungin, and fluconazole against C. neoformans var. grubii. Based on minimum effective concentration for 90% of the isolates tested (MEC90) and MIC90 values, manogepix (MEC90, 0.03 mg/liter) was 16- to 64-fold more potent than itraconazole, posaconazole, and voriconazole (MIC90s, 0.5 to 2 mg/liter) against 246 Aspergillus spp. isolates. Aspergillus fumigatus isolates exhibited a wild-type (WT) phenotype for the mold-active triazoles, including itraconazole (87.0% WT) and voriconazole (96.4% WT). Manogepix was highly active against uncommon species of Candida, non-Candida yeasts, and rare molds, including 11 isolates of Candida auris (MIC50/MIC90, 0.004/0.015 mg/liter) and 12 isolates of Scedosporium spp. (MEC50/MEC90, 0.06/0.12 mg/liter). Additional studies are in progress to evaluate the clinical utility of the manogepix prodrug fosmanogepix in difficult-to-treat resistant fungal infections.

[One-Year Candida Data of the Central Mycology Laboratory: Which Sample, Which Species, How Resistant?] / Merkez Mikoloji Laboratuvarinin Bir Yillik Candida Verileri: Hangi Örnek, Hangi Tür, Ne Kadar Dirençli?

The incidence of fungal infections particularly Candida species, is increasing gradually as a result of the increased life expectancy associated with the advances in the diagnosis and treatment of diseases, and increased number of patients in the risk group over the years. In addition, the incidence of fungal infection types that are resistant to antifungal drugs has been increasing, and rare fungal species have been reported to be isolated more frequently. For this reason, it is indicated that identification to the species level will contribute to the early initiation of an accurate and effective treatment. In this study, it was aimed to define the Candida species isolated from various clinical specimens and to document the performance of antifungal sensitivity tests. The Candida isolates sent to the central mycology laboratory in 2019 for identification and antifungal susceptibility tests were included in the study. The definition of the fungi to the species level was carried out using matrix-assisted laser desorption ionization-time of fl ight mass spectrometry (MALDI-TOF MS) and conventional methods. In vitro antifungal drug susceptibilities were analyzed using the The Clinical and Laboratory Standarts Institute (CLSI, M27-A3) reference broth microdilution method. The minimum inhibitory concentration (MIC) results were interpreted in accordance with the species-specific clinical breakpoints (CBPs) cited in the CLSI-M60 guidelines, and according to the epidemiological cut-off value (ECV) when no CBP was mentioned. The distribution of the species of the total 813 Candida isolates included in the study were as follows: Candida albicans (n= 312 ), Candida parapsilosis (n= 202), Candida tropicalis (n= 92), Candida glabrata (n= 71), Candida dubliniensis (n=28), Candida lusitaniae (n= 26), Candida kefyr (n= 22), Candida utilis (n= 17), Candida krusei (n= 14), Candida orthopsilosis (n= 7), Candida inconspicua (n= 7), Candida guilliermondii (n= 5), Candida metapsilosis (n= 4), Candida norvegensis (n= 4), Candida lambica (n= 1) and Candida lipolytica (n= 1). The evaluation of the results of the antifungal susceptibility tests according to the CBPs revealed that one C.albicans isolate and 60 C.parapsilosis (29.7%) isolates were resistant, and seven C.parapsilosis (3.5%) isolates were dose-dependent susceptible to fluconazole; 32 C.parapsilosis (15.8%) isolates were intermediately susceptible to voriconazole; one C.parapsilosis (0.5%) was resistant and one C.krusei (7.1%) was intermediately susceptible to anidulafungin; and one C.parapsilosis (0.5%) was resistant and one C.krusei (7.1%) isolate was intermediately susceptible to micafungin. In terms of ECVs, one C.lusitaniae isolate for fluconazole and one of each C.lusitaniae and C.kefyr isolates were evaluated as a non-wild type. In the present study, 61 of 813 isolates were found to be resistant to fluconazole and seven were dose dependently susceptible, 32 were intermediately susceptible to voriconazole, one was resistant to anidulafungin, one was intermediately susceptible, and one was resistant to micafungin and one was intermediately susceptible to micafungin. In conclusion, the increased number of non- albicans Candida species and increased levels of resistance to antifungal drugs further establish the importance of early diagnosis at a species level alongside antifungal susceptibility tests.

Evaluation of Inoculum Preparation for Etest and EUCAST Broth Dilution to Detect Anidulafungin Polyresistance in Candida glabrata.

The influence of inoculum preparation in EUCAST broth dilution and Etest to detect the coexistence of resistant and susceptible Candida subpopulations (defined as polyresistance [PR]) was evaluated. Cocultures of two echinocandin-resistant and susceptible clinical C. glabrata strains were used to simulate the occurrence of mixed populations in clinical samples, and antifungal susceptibility testing was performed with standard and modified approaches of inoculum preparation. Polyresistant results manifested as microcolonies or double ellipses in Etest and in single reduced optical density (OD) values (dip in OD) in microdilution. The strict inclusion of five distinct colonies of 1:5 and 1:10 resistant and susceptible cocultures led to higher rates of PR and R results compared to including one to two colonies in inoculum preparation (30% and 26% for Etest and broth dilution, respectively). Modifying the inoculum preparation by increasing the turbidity from a 2 to a 4 McFarland standard before redilution to a 0.5 McFarland standard reliably enabled the detection of resistance, with better identification of PR by Etest than by broth dilution (82% versus 32%, respectively) and of resistant minimum inhibitory concentration (MIC) values in 18% of Etests and 67% of microdilutions. The highest identification of PR succeeded with Etest and a modified 3 McFarland standard approach of inoculum preparation. Our data demonstrate that inoculum preparation as recommended and practiced does not reliably identify resistant subpopulations in polyresistant Candida cultures. By increasing the inoculum size for Etest assays from a 2 to a 4 McFarland standard with subsequent redilution, we propose a simple adaptation to increase reliability.

ΔF659 and F659S substitutions at the HS1 of FKS2 gene, along with E655A and W715L upstream and downstream substitutions, correlate with high ibrexafungerp MICs against Candidaglabrata.

OBJECTIVES: Ibrexafungerp is a new inhibitor of Candida spp glucan synthase. We previously set the ibrexafungerp wild-type upper limit (wtUL) against Candida glabrata. We here assessed which FKS2 gene substitutions confer an ibrexafungerp non-wild-type phenotype in C. glabrata isolates. METHODS: We studied a set of C. glabrata (n = 34) isolates showing resistance to micafungin and anidulafungin (n = 28) or only to anidulafungin (n = 6) and harbouring 10 different FKS2 gene substitutions. Antifungal susceptibility to ibrexafungerp was tested according to European Committee on Antimicrobial Susceptibility Testing (EUCAST) E.Def 7.3.2 procedure and isolates were considered ibrexafungerp non-wild type according to the statistical wtUL (minimum inhibitory concentration [MIC] ≥2) or visual wtUL (MIC ≥4). RESULTS: Ibrexafungerp MICs against the isolates ranged from 0.06 to 4 mg/L. Four FKS2 gene substitutions (ΔF659, F659S, E655A, and W715L) were exclusively found in isolates showing an ibrexafungerp MIC above the statistical wtUL (≥2 mg/L) whereas isolates harbouring other substitutions were found to be ibrexafungerp wild type. The use of the visual wtUL (MIC ≥4 mg/L) bisected the population of isolates harbouring such substitutions. DISCUSSION: C. glabrata isolates showing an ibrexafungerp MIC ≥2 mg/L may be considered non-wild type and are prone to harbour ΔF659, F659S, E655A, and W715L substitutions at the FKS2 gene. It is worth noting that substitutions ΔF659 and F659S were located at the beginning of the HS1 of FKS2 gene of C. glabrata. The role of other substitutions on conferring a non-wild-type phenotype to ibrexafungerp is not well elucidated.

Echinocandins Susceptibility Patterns of 2,787 Yeast Isolates: Importance of the Thresholds for the Detection of FKS Mutations.

Since echinocandins are recommended as first line therapy for invasive candidiasis, detection of resistance, mainly due to alteration in FKS protein, is of main interest. EUCAST AFST recommends testing both MIC of anidulafungin and micafungin, and breakpoints (BPs) have been proposed to detect echinocandin-resistant isolates. We analyzed MIC distribution for all three available echinocandins of 2,787 clinical yeast isolates corresponding to 5 common and 16 rare yeast species, using the standardized EUCAST method for anidulafungin and modified for caspofungin and micafungin (AM3-MIC). In our database, 64 isolates of common pathogenic species were resistant to anidulafungin, according to the EUCAST BP, and/or to caspofungin, using our previously published threshold (AM3-MIC ≥ 0.5 mg/L). Among these 64 isolates, 50 exhibited 21 different FKS mutations. We analyzed the capacity of caspofungin AM3-MIC and anidulafungin MIC determination in detecting isolates with FKS mutation. They were always identified using caspofungin AM3-MIC and the local threshold while some isolates were misclassified using anidulafungin MIC and EUCAST threshold. However, both methods misclassified four wild-type C. glabrata as resistant. Based on a large data set from a single center, the use of AM3-MIC testing for caspofungin looks promising in identifying non-wild-type C. albicans, C. tropicalis and P. kudiravzevii isolates, but additional multicenter comparison is mandatory to conclude on the possible superiority of AM3-MIC testing compared to the EUCAST method.

Early phenotypic detection of fluconazole- and anidulafungin-resistant Candida glabrata isolates.

BACKGROUND: Increased fluconazole and echinocandin resistance in Candida glabrata requires prompt detection in routine settings. A phenotypic test based on the EUCAST E.DEF 7.3.2 protocol was developed for the detection of fluconazole- and anidulafungin-resistant isolates utilizing the colorimetric dye XTT. METHODS: Thirty-one clinical C. glabrata isolates, 11 anidulafungin resistant and 14 fluconazole resistant, were tested. After optimization studies, 0.5-2.5 × 105 cfu/mL of each isolate in RPMI 1640 + 2% d-glucose medium containing 100 mg/L XTT + 0.78 µΜ menadione and 0.06 mg/L anidulafungin (S breakpoint) or 16 mg/L fluconazole (I breakpoint) in 96-well flat-bottom microtitration plates were incubated at 37°C for 18 h; we also included drug-free wells. XTT absorbance was measured at 450 nm every 15 min. Differences between the drug-free and the drug-treated wells were assessed using Student's t-test at different timepoints. ROC curves were used in order to identify the best timepoint and cut-off. RESULTS: The XTT absorbance differences between fluconazole-containing and drug-free wells were significantly lower for the resistant isolates compared with susceptible increased exposure isolates (0.08 ±â€Š0.05 versus 0.25 ±â€Š0.06, respectively, P = 0.005) at 7.5 h, with a difference of <0.157 corresponding to 100% sensitivity and 94% specificity for detection of resistance. The XTT absorbance differences between anidulafungin-containing and drug-free wells were significantly lower for the resistant isolates compared with susceptible isolates (0.08 ±â€Š0.07 versus 0.200 ±â€Š0.03, respectively, P < 0.001) at 5 h, with a difference of <0.145 corresponding to 91% sensitivity and 100% specificity, irrespective of underlying mutations. CONCLUSIONS: A simple, cheap and fast phenotypic test was developed for detection of fluconazole- and anidulafungin-resistant C. glabrata isolates.

Antifungal susceptibility profile of invasive Candida glabrata isolates (2009-2020) from a tertiary care hospital laboratory in Pakistan.

Introduction. Invasive infections with Candida glabrata are a global concern due to poor clinical outcomes and propensity to acquire resistance to antifungal agents. Hypothesis/Gap Statement. Monitoring emerging resistance and trends in Candida glabrata, an important agent of candidemia in Pakistan, is critical for patient management; data that is missing from Pakistan. Aim. Thus, this study evaluated antifungal resistance and MICs) distribution in invasive C. glabrata isolates from Pakistan. Methods. This cross-sectional and retrospective study was conducted from January 2009 to March 2020 at a clinical laboratory in Pakistan that has a nation-wide network. Antifungal susceptibility data of 277 candidemia, deep organ and soft tissue (invasive) C. glabrata sensu lato isolates against fluconazole, itraconazole, voriconazole, posaconazole, anidulafungin, micafungin, caspofungin and amphotericin B was retrieved. Susceptibility testing was performed using colorimetric broth microdilution and interpreted using CLSI criteria. Demographics, clinical history and outcome were studied. Chi-square test was used to demonstrate association between antifungal resistance and clinical characteristics of the patients. Results. We identified 277 patients with invasive C. glabrata infection. Of which 48 (18.4%) isolates were resistant to fluconazole (MIC ≥64 mg l-1), one isolate each was resistant to amphotericin (MIC=2 mg l-1), anidulafungin (MIC=1 mg l-1) and micafungin (MIC=0.5 mg l-1). MIC90 for fluconazole was 64 mg l-1 and other triazoles 2 mg l-1, caspofungin 0.12 mg l-1, anidulafungin 0.06 mg l-1, micafungin 0.03 mg l-1 and amphotericin 0.5 mg l-1. Fluconazole MIC ≥64 mg l-1, caspofungin MIC >0.06 mg l-1 and amphotericin MIC >0.25 mg l-1 (above MIC50) were significantly associated with patient being alive at the time of reporting, no use of healthcare devices, nor infection with other fungi. Fluconazole resistance was significantly associated with prior antifungal use by the patient. Conclusion. Surveillance data of antifungal resistance among common Candida species should be monitored closely for identification of resistant strains.

Synergistic in-vitro antiviral effects of combination treatment using anidulafungin and T-1105 against Zika virus infection.

Zika virus (ZIKV) has been the cause of some epidemics since 2007. The correlations of microcephaly and Guillain-Barré syndrome with ZIKV have been noticed. Unfortunately, researchers have yet to develop an effective vaccine or drug approved for ZIKV infection. Anidulafungin is a member of echinocandins that is used to treat candida infections. This study assessed the antiviral capability of anidulafungin against ZIKV. Anidulafungin was shown to significantly decrease viral RNA levels, protein expression levels, viral yields, and the rate of infection. In time of addition assays, anidulafungin exhibited inhibitory activities in the early stages of ZIKV infection. In binding and entry assays, administering anidulafungin did not lead to a corresponding decrease in quantity of viral RNA, but a significant decrease in ZIKV infectivity was observed in virucidal assays. This indicated that anidulafungin interferes directly with virions. T-1105 is a viral polymerase inhibitor, which functions in the late stage of ZIKV infection. When anidulafungin was administered in combination with T-1105, an obvious synergistic effect was observed, resulting in a combination index (CI) value of 0.85 ± 0.13. Finally, we evaluated the effects of echinocandins in terms of half-maximal inhibitory concentration (IC50), calculation of cytotoxicity concentration 50% (CC50), selectivity index (SI), and Patchdock score. Among the tests, anidulafungin bears the lowest IC50 and highest Patchdock score. Although anidulafungin is classified as a pregnancy category C agent; however, combination therapy of anidulafungin with a viral RNA replication inhibitor could expand treatment options for ZIKV infection.

Narrow mutational signatures drive acquisition of multidrug resistance in the fungal pathogen Candida glabrata.

Fungal infections are a growing medical concern, in part due to increased resistance to one or multiple antifungal drugs. However, the evolutionary processes underpinning the acquisition of antifungal drug resistance are poorly understood. Here, we used experimental microevolution to study the adaptation of the yeast pathogen Candida glabrata to fluconazole and anidulafungin, two widely used antifungal drugs with different modes of action. Our results show widespread ability of rapid adaptation to one or both drugs. Resistance, including multidrug resistance, is often acquired at moderate fitness costs and mediated by mutations in a limited set of genes that are recurrently and specifically mutated in strains adapted to each of the drugs. Importantly, we uncover a dual role of ERG3 mutations in resistance to anidulafungin and cross-resistance to fluconazole in a subset of anidulafungin-adapted strains. Our results shed light on the mutational paths leading to resistance and cross-resistance to antifungal drugs.

Antifungal activity of nitroxoline against Candida auris isolates.

OBJECTIVES: To investigate the in vitro activity of nitroxoline against a molecularly characterized collection of clinical Candida auris isolates. METHODS: Thirty-five clinical isolates of C. auris from diverse sources representing all five different C. auris clades were included in the study. Nitroxoline activity was assessed using broth microdilution. Additionally, susceptibility testing by disc diffusion was assessed on RPMI-1640 and Müller-Hinton agar plates. Minimal inhibitory concentrations of the antifungals fluconazole, voriconazole, amphotericin B and anidulafungin were determined. RESULTS: Nitroxoline MICs ranged from 0.125 to 1 mg/L (MIC50/90 0.25/0.5 mg/L). Compared with amphotericin B (MIC >1 mg/L in 4/35 isolates), anidulafungin (MIC >0.06 mg/L in 26/35 isolates) and fluconazole (MIC >4 mg/L in 31/35 isolates), in vitro activity of nitroxoline was high. Isolates belonging to clade I had marginally lower nitroxoline MICs (range 0.125-0.5 mg/L, mean MIC 0.375 mg/L) compared with clade III (range 0.5-1 mg/L, mean MIC 0.7 mg/L; p = 0.0094). The correlation of MIC and inhibition zones by disc diffusion was good when using RPMI-agar for disc diffusion, with a Pearson's correlation coefficient of -0.74 (95% CI -0.86 to -0.54). CONCLUSIONS: Nitroxoline has excellent in vitro activity against C. auris isolates, with MICs of 0.125-1 mg/L (for comparison, the EUCAST breakpoint for uncomplicated urinary tract infection with Escherichia coli is ≤ 16 mg/L). It is an approved, well-tolerated antimicrobial that achieves high urinary concentrations after oral administration and could be a useful treatment option in C. auris candiduria.

Antifungal drugs work together to treat germs causing fungal infections.

Life-threatening infections can be caused by a fungus called Candida auris (shortened to C. auris) that is found in the hospital environment. This study looked at how well different drugs could treat C. auris infection. Samples were collected from 36 people who had C. auris infection. The samples were treated with single drugs and in combination. We found that the main drug types did not work on most samples. Genetic differences we found in the C. auris samples could explain why the main drugs did not work. However, a drug called isavuconazole worked on almost all samples. We also found that a drug called anidulafungin worked better against C. auris when it was combined with either isavuconazole or another drug called voriconazole. To read the full Plain Language Summary of this article, click on the View Article button above and download the PDF.