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Inicio Revista Iberoamericana de Micología In vitro activity of juglone (5-hydroxy-1,4-naphthoquinone) against both flucona...
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Vol. 39. Issue 2.
Pages 50-53 (April - June 2022)
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Vol. 39. Issue 2.
Pages 50-53 (April - June 2022)
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In vitro activity of juglone (5-hydroxy-1,4-naphthoquinone) against both fluconazole-resistant and susceptible Candida isolates
Actividad in vitro de juglona (5-hidroxi-1,4-naftoquinona) contra aislamientos de Candida resistentes y sensibles a fluconazol
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Afsane Vaezia, Masoud Moghadaszadehb, Elahe Nasric, Shima Gharibid, Kambiz Dibae, Adam Matkowskif, Hamed Fakhime,g,
Corresponding author
Fakhiim.hamed@gmail.com

Corresponding author.
a Department of Medical Laboratory Science, School of Allied Medical Sciences, Iran University of Medical Sciences, Tehran, Iran
b Biotechnology Research Center, Tabriz University of Medical Sciences, Tabriz, Iran
c Nosocomial Infection Research Center, Isfahan University of Medical Sciences, Isfahan, Iran
d Core Research Facilities, Isfahan University of Medical Sciences, Isfahan, Iran
e Department of Medical Parasitology and Mycology, Faculty of Medicine, Urmia University of Medical Sciences, Urmia, Iran
f Department of Pharmaceutical Biology and Botanical Garden of Medicinal Plants, Wroclaw Medical University, Wrocław, Poland
g Infectious Diseases and Tropical Medicine Research Center, Isfahan University of Medical Sciences, Isfahan, Iran
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Abstract
Background

The rise in antifungal resistance and drug class limitations are causing higher morbidity and mortality rates all over the world. This issue highlights the urgent need for new and improved antifungal drugs with a novel target.

Aims

In order to evaluate whether juglone can be served as an alternative antifungal to cure drug-resistant Candida infections, we studied the in vitro susceptibility of juglone against fluconazole-susceptible and -resistance Candida isolates, alone and in combination.

Methods

Antifungal susceptibility testing was performed according to the CLSI (Clinical and Laboratory Standards Institute) guidelines.

Results

Juglone exhibited the highest minimal inhibitory concentration (MIC) values, followed by fluconazole and nystatin. Voriconazole showed significantly better antifungal activity than juglone, fluconazole, and nystatin, with MIC50 and MIC90 of 0.031 and 0.5μg/mL. There were significant differences in MICs of fluconazole (p<0.001) and juglone (p<0.0003) between Candidaalbicans and the rest of the species. Combination of juglone with fluconazole revealed insignificant effects against fluconazole-susceptible and -resistant Candida isolates. Juglone increased the antifungal activity of fluconazole; however, no synergism effects were observed for any combination, and only an insignificant effect was found against all tested Candida species.

Conclusions

Although obtaining new antifungal drugs is a critical point, a completely novel approach should be implemented.

Keywords:
Juglone
5-Hydroxy-1,4-naphthoquinone
Susceptibility
Fluconazole resistance
Candida
Resumen
Antecedentes

El aumento de la resistencia a los antifúngicos y las limitaciones propias de los fármacos son responsables de mayores tasas de morbimortalidad en todo el mundo. Este trabajo destaca la urgente necesidad de nuevos y mejorados fármacos antimicóticos contra una nueva diana.

Objetivos

Con el fin de evaluar si la juglona puede servir como un antifúngico alternativo para curar las infecciones por Candida resistentes a los fármacos antifúngicos, hemos estudiado la sensibilidad in vitro a la juglona de aislamientos de Candida sensibles y resistentes al fluconazol, solo y en combinación.

Métodos

La prueba de sensibilidad a los antifúngicos se realizó de acuerdo con las guías del Clinical and Laboratory Standards Institute (CLSI).

Resultados

La juglona mostró los valores de concentración mínima inhibitoria (CMI) más altos, seguida por el fluconazol y la nistatina. El voriconazol mostró una actividad antifúngica significativamente mejor que la juglona, el fluconazol y la nistatina, con valores de CMI50 y CMI90 de 0,031 y 0,5μg/mL. Hubo diferencias significativas en las CMI del fluconazol (p<0,001) y la juglona (p<0,0003) entre los aislamientos de Candida albicans y aquellos de otras especies. La combinación de juglona con fluconazol reveló efectos insignificantes contra cepas de Candida sensibles y resistentes al fluconazol. La juglona aumentó la actividad antifúngica del fluconazol; sin embargo, no se observaron efectos de sinergia para ninguna combinación y solo se encontró un efecto insignificante contra todas las especies de Candida ensayadas.

Conclusiones

Aunque el diseño o el descubrimiento de nuevos fármacos antimicóticos es una tarea crítica, es necesario planificar un abordaje completamente novedoso.

Palabras clave:
Juglona
5-Hidroxi-1,4-naftoquinona
Sensibilidad
Resistencia al fluconazol
Candida
Full Text

The antifungal resistance phenomenon, which is increasing, is the cause of serious and life-threatening infections in immunosuppressed patients.1,11 It is important to note that no new antifungals that might fight against drug-resistant fungal pathogens have been developed in the recent past.12 New and improved antifungal drugs with a novel target and a new molecular structure are necessary to prevent cross-resistance. Juglone, 5-hydroxy-1,4-naphthoquinone, is an allelochemical from trees of the Juglans genus (walnut), that may be active against Candida species.9 Juglone has shown inhibitory activity on the tricarboxylic acid cycle of Staphylococcus aureus, as well as on the synthesis of deoxyribonucleic acid, ribonucleic acid, and proteins by this microorganism.13 However, to the best of our knowledge, there is limited evidence on the efficacy of juglone as an antifungal agent. To assess the potential use of juglone as an alternative antimycotic drug to cure Candida-resistant infections, we checked the in vitro activity of juglone against a collection of fluconazole-susceptible and -resistant Candida isolates, and the results were compared with those obtained with fluconazole, as well as those from the combination of juglone and fluconazole.

The strains consisted of fluconazole-resistant (n=14) and -susceptible (n=26) Candida isolates (according to non-species-specific Candida breakpoints of ≥4μg/mL for fluconazole-resistant isolates), including Candida albicans (n=11), Candidaglabrata (n=6), Candida tropicalis (n=5), Candida parapsilosis (n=5), Candida krusei (n=5), Candida kefyr (n=4), Candida haemulonii (n=3) and Candida auris (n=1) from urine (n=15), biopsy (n=9), peritoneal fluid (n=6), blood (n=6), and vagina (n=4).6,7,5,8 All isolates had been identified by conventional and molecular methods (i.e., sequencing of the Internal Transcribed Spacer region of ribosomal DNA using specific primers) in our previous studies.6,7,5,8 Antifungal susceptibility testing was performed according to the guidelines provided by the Clinical and Laboratory Standards Institute (CLSI).3 Antifungal agents were dispensed into microdilution trays at final concentration ranges of 0.016–16μg/mL for amphotericin B (Sigma, St. Louis, MO, USA), nystatin (Sigma, St. Louis, MO, USA), itraconazole (Janssen Research Foundation, Beerse, Belgium), and voriconazole (Pfizer Central Research, Sandwich, UK); 0.063–64μg/mL for fluconazole (Pfizer, Groton, CT, USA) and juglone (Sigma, St. Louis, MO, USA); and 0.008–8μg/mL for micafungin (Astellas Pharma, Ibaraki, Japan) and anidulafungin (Pfizer, Central Research, Sandwich, United Kingdom). The in vitro interaction of fluconazole and juglone against 20 Candida isolates from eight different species was assessed by using a checkerboard method based on the microdilution broth reference technique of the CLSI, as described previously.10 Concentrations ranged from 0.125 to 64μg/mL for fluconazole and juglone. The fractional inhibitory concentration index (FICI) was calculated and the interaction was interpreted as synergistic for FICI0.5, indifferent for FICI=0.54, and antagonistic for FICI>4.10 The Students t-test was used to find out a statistical significance difference between juglone and fluconazole MICs in C.albicans and non-C. albicans Candida isolates, using the SPSS statistical package (version 7.0; SPSS Inc., Chicago, IL). The p-values lower than 0.05 were considered statistically significant.

The in vitro activities of juglone and other antifungals against 40 fluconazole-resistant and -susceptible clinical Candida isolates are summarized in Table 1. Juglone exhibited the highest MICs (MIC range, 0.5–>64μg/mL; MIC90, 16μg/mL), followed by fluconazole (MIC range, 0.125–>64μg/mL; MIC90, 8μg/mL), nystatin and amphotericin B. Candida albicans isolates were more sensitive to juglone (MIC range, 0.52μg/mL; MIC90, 2μg/mL) than non-C. albicansCandida isolates (MIC range, 0.5–>64μg/mL; MIC90, 16μg/mL). There were significant differences in the MICs of fluconazole (p<0.001) and juglone (p<0.0003) between C.albicans and the rest of the species. Voriconazole showed significantly better antifungal activity than juglone, fluconazole, and nystatin, with MIC50/90 values of 0.031 and 0.5μg/mL. All Candida isolates had low MICs of anidulafungin (MIC range, 0.004–0.5μg/mL; MIC90, 0.5μg/mL) and micafungin (MIC range, 0.008–0.5μg/mL; MEC90, 0.5μg/mL). The checkerboard analysis of the juglone and fluconazole is summarized in Table 2. The FICI results revealed indifferent effect against fluconazole-susceptible and -resistant Candida isolates when juglone was combined with fluconazole. Overall, no antagonistic effects were observed against Candida isolates with this combination.

Table 1.

In vitro activity of juglone and seven antifungal drugs against clinical Candida isolates.

Strains and antifungal drugs  MICs (μg/mL)
  Range  MIC50/MIC90  G mean  ≤0.008  0.016  0.031  0.063  0.125  0.25  0.5  16  32  ≥64 
All Candida isolates (40)
AmB  0.031–1  0.25/0.5  0.213      13  12             
FLZ  0.125–>64  1/8  1.275          8   
ITZ  0.016–1  0.125/0.5  0.101    9  9             
VRZ  0.008–0.5  0.031/0.25  0.036  16  13               
NYT  0.125–4  1/2  0.982            10  18  10         
AFG  0.004–0.5  0.125/0.5  0.068  10               
MFG  0.008–0.5  0.5/0.5  0.043  15               
Juglone  0.5–>64  2/16  2.639              13 
Candida albicans (11)
AmB  0.31–1  0.125/0.5  0.117      5               
FLZ  0.125–1  0.5/1  0.413          4             
ITZ  0.016–0.25  0.031/0.125  0.035    6                   
VRZ  0.016–0.063  0.016/0.031  0.020    8                     
NYT  0.5–2  1/2  0.938              6           
AFG  0.004–0.031  0.008/0.016  0.009  8                       
MFG  0.008  0.008  0.008  11                           
Juglone  0.5–2  1/2  1.065              8           
Other Candida species (29)
AmB  0.125–1  0.25/0.5  0.268          12             
FLZ  0.125–>64  2/8  2.054          5   
ITZ  0.016–1  0.125/0.5  0.151    8             
VRZ  0.008–0.5  0.031/0.5  0.046  11               
NYT  0.125–4  1/2            12         
AFG  0.008–0.5  0.125/0.5  0.144      10               
MFG  0.008–0.5  0.125/0.5  0.083               
Juglone  0.5–>64  4/16              5  5 

AMB: amphotericin B; FLZ: fluconazole; ITZ: itraconazole; VRZ: voriconazole; NYT: nystatin; AFG: anidulafungin; MFG: micafungin. Figures in bold are modal values.

Table 2.

In vitro combination of fluconazole with juglone against resistant and susceptible Candida species.

MIC (μg/mL)
Isolate  Candida species  Fluconazole  Juglone  Fluconazole/Juglone  FICI/INT 
FDC1  C. albicans  0.5  0.125/1  1.25/IND 
FDC3  C. albicans  0.125  0.125/1  1.5/IND 
FDC22  C. albicans  0.5/1  1/IND 
FDC27  C. albicans  0.25  0.125/0.5  1/IND 
FDC8  C. glabrata  1/4  1.5/IND 
FDC9  C. glabrata  16  1/8  0.75/IND 
FDC15  C. glabrata  2/4  1.5/IND 
FDC43  C. parapsilosis  32  4/16  1/IND 
FDC48  C. parapsilosis  0.5  0.25/0.5  0.75/IND 
FDC52  C. parapsilosis  0.5/2  1/IND 
FDC17  C. krusei  ≥64  ≥64  ≥64/≥64  2/IND 
FDC51  C. krusei  32  ≥64  16/≥64  1.5/IND 
FDC38  C. kefyr  1/2  0.75/IND 
FDC6  C. kefyr  32  4/8  0.75/IND 
FDC41  C. tropicalis  0.5/1  1.5/IND 
FDC14  C. tropicalis  0.5  1/1  3/IND 
FDC21  C. tropicalis  0.5  0.5  0.5/0.5  2/IND 
FDC71  C. haemulonii  2/8  1.25/IND 
CMRC 386  C. haemulonii  16  2/4  0.75/IND 
FDC229  C. auris  ≥64  ≥64  16/≥64  1.25/IND 

MIC: minimum inhibitory concentration; FICI: fractional inhibitory concentration index; INT: interpretation; IND: indifference.

The limited therapeutic options to cure infections caused by strains resistant to one or more antifungal agents has increased the mortality.12 It is essential to design new classes of antifungals, as well as novel combination therapies to treat invasive fungal infections caused by drug-resistant pathogens. Based on the results of this study, juglone did not show good antifungal activity against Candida isolates. The MIC50 values for juglone and fluconazole against Candida isolates were 2μg/mL and 1μg/mL, respectively, whereas MIC90 values were 16 and 8μg/mL. However, D’Angeli et al. reported potent activity of Juglans regia pellicle extract against most of the tested Candida strains.4 The findings of a study conducted by Clark et al. also showed a moderate antifungal activity of juglone against Trichophyton mentagrophytes and Microsporum gypseum.2 The antifungal activity of juglone was also observed against Aspergillus strains, Penicillium strains, Hansenula strains, and Saccharomyces carlsbergensis.14,15 The reasons for these discrepancies in the results may rely on multiple factors such as the fungal strain, the method used, or even the way in which MIC endpoints have been determined. In this study, we also used the checkerboard microdilution method to analyze the drug-drug interactions of juglone with fluconazole against 20 fluconazole-resistant and -susceptible Candida isolates. Juglone increased the antifungal activity of fluconazole; however, no synergism effect was observed for any combination and an indifferent effect was found against all tested Candida. Finally, the increasing antifungal resistance, along with the lack of newly developed drugs, is an alarming signal for global public health. Although the critical point is the difficulty in obtaining new antifungal drugs, it is needed to plan a completely novel approach.

Conflict of interest

All authors report no potential conflicts of interest. The authors alone are responsible for the content and writing of the paper.

Acknowledgments

This work was supported by a grant (no. 96-09-43-3067) from the School of Medicine, Urmia University of Medical Sciences, Urmia, Iran, which we gratefully acknowledge.

References
[1]
N.F. Aldardeer, H. Albar, M. Al-Attas, A. Eldali, M. Qutub, A. Hassanien, et al.
Antifungal resistance in patients with candidaemia: a retrospective cohort study.
BMC Infect Dis, 20 (2020), pp. 1-7
[2]
A.M. Clark, T.M. Jurgens, C.D. Hufford.
Antimicrobial activity of juglone.
Phytotherap Res, 4 (1990), pp. 11-14
[3]
Clinical Laboratory Standards Institute.
Performance standards for antifungal susceptibility testing of yeasts. CLSI supplement M60.
CLSI, (2017),
[4]
F. D’Angeli, G.A. Malfa, A. Garozzo, G. Li Volti, C. Genovese, A. Stivala, et al.
Antimicrobial, antioxidant, and cytotoxic activities of Juglans regia L. pellicle extract.
Antibiotics, 10 (2021), pp. 159
[5]
K. Diba, K. Makhdoomi, E. Nasri, A. Vaezi, J. Javidnia, D.J. Gharabagh, et al.
Emerging Candida species isolated from renal transplant recipients: species distribution and susceptibility profiles.
Microb Pathogen, 125 (2018), pp. 240-245
[6]
H. Fakhim, A. Vaezi, E. Dannaoui, A. Chowdhary, D. Nasiry, L. Faeli, et al.
Comparative virulence of Candida auris with Candida haemulonii, Candida glabrata and Candida albicans in a murine model.
Mycoses, 61 (2018), pp. 377-382
[7]
H. Fakhim, A. Vaezi, J. Javidnia, E. Nasri, D. Mahdi, K. Diba, et al.
Candida africana vulvovaginitis: Prevalence and geographical distribution.
J Mycol Med, 30 (2020),
[8]
E. Nasri, H. Fakhim, A. Vaezi, S. Khalilzadeh, F. Ahangarkani, M. Laal kargar, et al.
Airway colonisation by Candida and Aspergillus species in Iranian cystic fibrosis patients.
Mycoses, 62 (2019), pp. 434-440
[9]
E. Noumi, M. Snoussi, H. Hajlaoui, E. Valentin, A. Bakhrouf.
Antifungal properties of Salvadora persica and Juglans regia L. extracts against oral Candida strains.
Eur J Clin Microbiol Infect Dis, 29 (2010), pp. 81-88
[10]
F.C. Odds.
Synergy, antagonism, and what the chequerboard puts between them.
J Antimicrob Chemother, 52 (2003), pp. 1
[11]
L. Ostrosky-Zeichner, S. Shoham, J. Vazquez, A. Reboli, R. Betts, M.A. Barron, et al.
MSG-01: a randomized, double-blind, placebo-controlled trial of caspofungin prophylaxis followed by preemptive therapy for invasive candidiasis in high-risk adults in the critical care setting.
Arch Clin Infect Dis, 58 (2014), pp. 1219-1226
[12]
Z. Sadeghi-Ghadi, A. Vaezi, F. Ahangarkani, M. Ilkit, P. Ebrahimnejad, H. Badali.
Potent in vitro activity of curcumin and quercetin co-encapsulated in nanovesicles without hyaluronan against Aspergillus and Candida isolates.
J Mycol Med, 30 (2020), pp. 101014
[13]
J. Wang, Z. Wang, R. Wu, D. Jiang, B. Bai, D. Tan, et al.
Proteomic analysis of the antibacterial mechanism of action of juglone against Staphylococcus aureus.
Nat Prod Commun, 11 (2016),
[14]
Z. Wu, G. Chen, Y. Wang.
Inhibition effect of juglong on several food deterioration microorganisms.
China Brewing, 8 (2009), pp. 76-78
[15]
A.Y. Yakubovskaya, N. Pokhilo, V. Anufriev, M. Anisimov.
Synthesis and antimicrobial and antifungal activities of compounds of the naphthazarin series.
Pharm Chem J, 43 (2009), pp. 396
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