Differential inhibition of Candida albicans CYP51 with azole antifungal stereoisomers

Azole antifungal compounds are important in agriculture and in the treatment of mycotic infection The target enzyme, sterol 14α-demethylase (CYP51), is inhibited through binding of triazole N-4 to the haem of this P450, as a sixth ligand together with the N-1 substituent groups interacting in some way with the apoprotein. Here we use Saccharomyces cerevisiae expression systems for the target enzyme of Candida albicans to investigate binding of enantiomers of the azole antifungal compounds SCH39304 and tetraconazole. A molecular model produced previously provided qualitative explanations for these differences. Interaction of the azole antifungal aromatic group with Phe-233 or -235 may cause the higher activity for (R)-tetraconazole while inactivity of the (SS)-enantiomer of SCH39304 was predicted to result from incompatibility of the hydrophilic sulfonyl moiety when located into the hydrophobic pocket of the active site.     

Reduced intracellular accumulation of azole antifungal results in resistance in Candida albicans isolate NCPF 3363

Candida albicans strain NCPF 3363 was isolated from a British patient with chronic mucocutaneous candidiasis (CMC) and confirmed to be resistant to azole antifungal compounds. In this study we investigate the molecular basis of resistance and show that azole tolerance in NCPF 3363 was associated with reduced intracellular accumulation of drug and not reduced affinity for the target site, as previously indicated. Relative impermeability or the presence of transporters related to those responsible for multidrug resistance are implicated in the mechanism of resistance.     

Synthesis of Sordaricin analogues as potent antifungal agents against Candida albicans

Sordaricin derivatives possessing a cyclohexane ring appendage attached via an ether, thioether, amine, oxime, ester or amide linkage were synthesized and their antifungal activity was evaluated in vitro. Compounds containing a thioether bond or an oxime bond as a linkage exhibited potent MICs (< or = 0.125 microg/mL) against four Candida albicans strains including azole-low-susceptible strains. They were also active (MIC < or = 0.125 microg/mL) against Candida glabrata. Their in vivo efficacy was confirmed in a murine intravenous infection model with Candida albicans.     

Suppression of ATP in Candida albicans by imidazole and derivative antifungal agents

Several antifungal agents, at concentrations of 10 micrograms/ml, were shown to suppress ATP concentrations very rapidly in intact cells and spheroplasts of Candida albicans. The highest ATP-suppressing activity was shown by the highly lipophilic imidazole derivatives difonazole, clotrimazole, econazole, isoconazole, miconazole, oxiconazole and tioconazole, which all caused a reduction of cellular ATP content of more than 50% in 10 min. Relatively hydrophilic imidazole derivatives such as ketoconazole were essentially inactive in the test, as were the triazole derivatives fluconazole, ICI 153066, itraconazole and terconazole, and 5-fluorocytosine. Amphotericin B and terbinafine possessed intermediate ATP-suppressing activity, and the dose-response and pH-response curves for these compounds suggested their mechanism of ATP suppression differed from that of the active imidazole derivatives. ATP suppression by azole antifungals did not involve leakage of ATP from the cells and the effect was entirely abrogated by the presence of serum. Intact cells and spheroplasts of yeast-form and hyphal-form C. albicans were generally equally sensitive to ATP suppression, but stationary-phase cells of both morphological forms were less sensitive than exponential-phase cells. The extent of ATP suppression was significantly reduced in stationary-phase yeast cells of a C. albicans strain with known resistance to azole antifungals, but exponential-phase cells of resistant and susceptible strains were equally sensitive. The effect is tentatively ascribed to membrane damage caused directly by the antifungals.     

Influence of lipid composition on the sensitivity of Candida albicans to antifungal agents

Cerulenin, a specific inhibitor of fatty acid and sterol biosyntheses, inhibited growth and lipid synthesis in C. albicans, which on supplementing the growth medium with optimum concentrations of fatty acids was reversed. Significant changes in the levels of phospholipids and sterols were observed in fatty acid-supplemented cells. Altered phospholipids and their fatty acid profile rendered cells more resistant to miconazole and thereby more permeable to [3H]proline. Thus it appears that fatty acid composition plays an important role in determining the permeability susceptibility of C. albicans to drugs.     

Molecular dynamic modeling of CYP51B in complex with azole inhibitors

Cytochrome P450 14α-sterol demethylase (CYP51), the key enzyme in sterol biosynthesis pathway, is an important target protein of cholesterol-lowering agents, antifungal drugs, and herbicides. CYP51B enzyme is one of the CYP51 family members. In the present study, we have chosen four representative inhibitors of CYP51B: diniconazole (Din), fluconazole (Flu), tebuconazole (Teb), and voriconazole (Vor), and launched to investigate the binding features of CYP51B-inhibitor and gating characteristics via molecular docking and molecular dynamics (MD) simulations. The results show that the ranking of binding affinities among these inhibitors is Din > Teb > Vor > Flu. Din shows the strongest binding affinity, whereas Flu shows the weakest binding affinity. More importantly, based on the calculated binding free energy results, we hypothesize that the nonpolar interactions are the most important contributors, and three key residues (Thr77, Ala258, and Lys454) play crucial role in protein-inhibitor binding. Besides, residue Phe180 may play a molecular switch role in the process of the CYP51B-Teb and CYP51B-Vor binding. Additionally, Tunnel analysis results show that the major tunnel of Din, Flu, and Teb is located between helix K, FG loop, and β4 hairpin (Tunnel II).The top ranked possible tunnel (Tunnel II) corresponds to Vor exits through helix K, F and helix J. This study further revealed the CYP51B relevant structural characteristics at the atomic level as well as provided a basis for rational design of new and more efficacious antifungal agents.     

Design,synthesis and evaluation of benzoheterocycle analogues as potent antifungal agents targeting CYP51

To further enhance the anti-Aspergillus efficacy of our previously discovered antifungal lead compound 1, a series of benzoheterocycle analogues were designed, synthesized and evaluated for their in vitro antifungal activity. The most promising compounds 13s and 14a exhibited excellent antifungal activity against C. albicans, C. neoformans, A. fumigatus and fluconazole-resistant C. albicans strains, that was superior or comparable to those of the reference drugs fluconazole and voriconazole. GC–MS analyses suggested that the novel compound 13s might have a similar mechanism to fluconazole by inhibiting fungal lanosterol 14α-demethylase (CYP51). Furthermore, compounds 13s and 14a exhibited low inhibition profiles for various human cytochrome P450 isoforms as well as excellent blood plasma stability.     

白念珠菌唑类药物耐药相关转录因子研究进展

近年来白念珠菌的感染率呈逐年上升趋势,随着唑类药物的广泛应用,耐药菌株不断增多,已成为临床治疗的一大难题.白念珠菌的耐药机制主要与ERG 11基因的突变和过表达、药物外排泵相关基因表达增多及生物膜的形成等有关,由于转录因子是耐药基因表达的关键调节因子,关于锌簇转录因子与耐药关系的研究越来越多,如TAC 1、MRR 1、MRR 2、UPC 2、NDT 80等,其点突变可引起某些耐药基因的过表达而介导耐药,该领域研究已成为热点,该文就此研究进展做一概述.     

Coprisin-induced antifungal effects in Candida albicans correlate with apoptotic mechanisms

Coprisin is a 43-mer defensin-like peptide from the dung beetle, Copris tripartitus. Here, we investigated the induction of apoptosis by coprisin in Candida albicans cells. Coprisin exerted antifungal and fungicidal activity without any hemolytic effect. Confocal microscopy indicated that coprisin accumulated in the nucleus of cells. The membrane studies, 1,6-diphenyl-1,3,5-hexatriene, calcein-leakage, and giant unilamellar vesicle assays, confirmed that coprisin did not disrupt the fungal plasma membrane at all. Moreover, the activity of coprisin was energy- and salt-dependent. Next, we investigated whether coprisin induced apoptosis in C. albicans. Annexin V-FITC staining and TUNEL assay showed that coprisin was involved with both the early and the late stages of apoptosis. Coprisin also increased the intracellular reactive oxygen species level, and hydroxyl radicals were included at high levels among the species. The effect of thiourea as a hydroxyl radical scavenger further confirmed the existence of the hydroxyl radicals. Furthermore, coprisin induced mitochondrial membrane potential dysfunction, cytochrome c release, and activation of metacaspases. In summary, this study suggests that coprisin could be a model molecule for a large family of novel antimicrobial peptides possessing apoptotic activity.     

Quantitative and qualitative analyses of the cell death process in Candida albicans treated by antifungal agents

The death process of Candida albicans was investigated after treatment with the antifungal agents flucytosine and amphotericin B by assessing morphological and biophysical properties associated with cell death. C. albicans was treated varying time periods (from 6 to 48 hours) and examined by scanning electron microscopy (SEM) and atomic force microscopy (AFM). SEM and AFM images clearly showed changes in morphology and biophysical properties. After drug treatment, the membrane of C. albicans was perforated, deformed, and shrunken. Compared to the control, C. albicans treated with flucytosine was softer and initially showed a greater adhesive force. Conversely, C. albicans treated with amphotericin B was harder and had a lower adhesive force. In both cases, the surface roughness increased as the treatment time increased. The relationships between morphological changes and the drugs were observed by AFM clearly; the surface of C. albicans treated with flucytosine underwent membrane collapse, expansion of holes, and shrinkage, while the membranes of cells treated with amphotericin B peeled off. According to these observations, the death process of C. albicans was divided into 4 phases, CDP(0), CDP(1), CDP(2), and CDP(4), which were determined based on morphological changes. Our results could be employed to further investigate the antifungal activity of compounds derived from natural sources.     

Interaction between Candida agglutinins and antifungal agents

Antifungal agents alter the function and morphology of Candida cell membranes and cell walls. We observed that brief (30 minute) exposure to either amphotericin B or clotrimazole inhibited the agglutination of Candida blastoconidia by murine bronchoalveolar lavage fluid. This inhibition required continuous drug presence. Neither amphotericin nor clotrimazole inhibited Candida agglutination by concanavalin A or pooled human serum. These results demonstrate that antifungal drugs can produce rapid changes in the surface characteristics of some fungi.     

The synergistic antifungal activity of resveratrol with azoles against Candida albicans

Candida albicans is one of the most common clinical pathogenic microorganisms and it is becoming a serious health threat, particularly to immunocompromised populations. Drug resistance of Candida species has also frequently emerged, and combination therapy for fungal infections has attracted considerable attention. In this study, we established the Qinling Mountains myxobacterial secondary metabolites library and a synergic assay in combination with ketoconazole against C. albicans was introduced for metabolites screening. Two active compounds with synergic anticandidal activities were obtained, which were identified as trans-resveratrol and cis-resveratrol. According to our study, resveratrol can reduce the dosage to 1/64 of ketoconazole as well as itraconazole. Furthermore, synergistic anticandidal activity of resveratrol combined with azoles was verified against a panel of clinical C. albicans isolates, and the combination strategy enhanced the azoles susceptibility of three fluconazole-resistant isolates. These findings suggest that resveratrol enhances the efficacy of azoles and provides a promising application in therapy of C. albicans infection.     

Synergistic action of nikkomycin X/Z with azole antifungals on Candida albicans.

Fluconazole, ketoconazole and tioconazole were shown to act synergistically in vitro with the antibiotic nikkomycin X/Z on the pathogenic fungus Candida albicans. The phenomenon was demonstrated using a checkerboard technique and growth inhibition experiments. The azole antifungal agents, even at concentrations not affecting growth, decreased the incorporation of the 14C-label from [14C]glucose into chitin of the candidal cell wall. After 3 h incubation with tioconazole, 1 microgram ml-1, the incorporation of the radiolabelled glucose into chitin of intact cells and regenerating spheroplasts of C. albicans was inhibited by 43% and 30%, respectively. Moreover, the relative chitin content was approximately 45% lower than that of control cells. The chitin content increased after prolonged incubation with azoles, thus confirming the known phenomenon of azole-induced uncoordinated chitin synthesis and deposition. On the other hand, azole derivatives had very little effect on the rate of nikkomycin transport into C. albicans cells. A sequential blockade mechanism of synergism is proposed.     

Effect of antifungal agents on protein composition of Candida albicans studied by capillary electrophoresis and chip technology

In the present study protein profile of a Candida albicans strain had been examined by chip technology and conventional capillary electrophoresis (CE). Profiles could be characterised by the presence of ten dominating protein peaks. These proteins could be distinguished by both techniques, but their quantity showed significant differences in the electropherograms obtained by CE and chip method. Changes in the protein profile were induced by administration of different antifungal agents. Fluconazole and amphotericin B treatment was able to induce similar changes in the pattern, appearance of a 40-kDa protein and up-regulation of a 60-kDa protein was observed by chip technology. Increase in the quantity of these proteins under stress effect (antifungal treatment) might refer to their stress function in the fungal cell. Treatment of C. albicans cells with MK 94 (fused cyclic Mannich ketone) antifungal compound induced not only the previously mentioned changes, but further specific alterations, appearance of a 19-kDa protein and up-regulation of the low molecular weight proteins. This might refer to the different mode of action of this agent on the fungal cells. Conventional capillary electrophoresis was suitable to detect the appearance of the 19-kDa peak, and up-regulation of the 60 kDa protein, but the other changes could not be detected by this technique. Shorter running time, more effective and baseline separation of proteins refer to the advantages of microchip-based method in the analysis of complex biological samples.     

白色念珠菌CYP51蛋白功能性氨基酸残基定点突变、蛋白表达及活性测定

实验设计了白色念珠菌CYP51蛋白功能性氨基酸残基突变体Y118A、Y118F、Y118T、S378A、S378T、H310A、H310R, 并转入基因工程菌D12667中表达。用Western及紫外分光光度法定性、定量检测蛋白, 用GC-MS法测定蛋白代谢活性。结果表明, 成功表达目标蛋白, 蛋白诱导表达量接近微粒体蛋白总量的25%。活性测定表明, 表达的野生型蛋白保持其对天然底物的代谢能力; 相较于野生型蛋白, 突变体蛋白代谢活性不同程度改变, 最多可下降1/2左右。因此, 本研究中成功表达了野生型和     

Saliva affects the antifungal activity of exogenously added histatin 3 towards Candida albicans

Antifungal activity of histatin 3 against two Candida albicans clinical isolates was determined in assays containing rabbit submandibular gland saliva. Histatin 3 inhibited the cell growth and germination of both isolates dose-dependently (10-100 microg ml(-1)) with maximum inhibition occurring after 60 min incubation. Adding fresh histatin 3 after 60 min caused further reduction in the viable cell count. Higher histatin 3 concentrations (50-100 microg ml(-1)) and prolonged exposure to peptide were required to inhibit germination. Histatin 3 was rapidly degraded in rabbit submandibular gland saliva and this may explain why fresh addition of histatin 3 increases candidacidal activity.     

Sensitization of Candida albicans biofilms to various antifungal drugs by cyclosporine A

Background

Biofilms formed by Candida albicans are resistant towards most of the available antifungal drugs. Therefore, infections associated with Candida biofilms are considered as a threat to immunocompromised patients. Combinatorial drug therapy may be a good strategy to combat C. albicans biofilms.

Methods

Combinations of five antifungal drugs- fluconazole (FLC), voriconazole (VOR), caspofungin (CSP), amphotericin B (AmB) and nystatin (NYT) with cyclosporine A (CSA) were tested in vitro against planktonic and biofilm growth of C. albicans. Standard broth micro dilution method was used to study planktonic growth, while biofilms were studied in an in vitro biofilm model. A chequerboard format was used to determine fractional inhibitory concentration indices (FICI) of combination effects. Biofilm growth was analyzed using XTT-metabolic assay.

Results

MICs of various antifungal drugs for planktonic growth of C. albicans were lowered in combination with CSA by 2 to 16 fold. Activity against biofilm development with FIC indices of 0.26, 0.28, 0.31 and 0.25 indicated synergistic interactions between FLC-CSA, VOR-CSA, CSP-CSA and AmB-CSA, respectively. Increase in efficacy of the drugs FLC, VOR and CSP against mature biofilms after addition of 62.5 μg/ml of CSA was evident with FIC indices 0.06, 0.14 and 0.37, respectively.

Conclusions

The combinations with CSA resulted in increased susceptibility of biofilms to antifungal drugs. Combination of antifungal drugs with CSA would be an effective prophylactic and therapeutic strategy against biofilm associated C. albicans infections.     

Synthetic arylquinuclidine derivatives exhibit antifungal activity against Candida albicans, Candida tropicalis and Candida parapsilopsis

Background

Severely burned patients may develop life-threatening nosocomial infections due to Pseudomonas aeruginosa, which can exhibit a high-level of resistance to antimicrobial drugs and has a propensity to cause nosocomial outbreaks. Antiseptic and topical antimicrobial compounds constitute major resources for burns care but in vitro testing of their activity is not performed in practice.

Results

In our burn unit, a P. aeruginosa clone multiresistant to antibiotics colonized or infected 26 patients over a 2-year period. This resident clone was characterized by PCR based on ERIC sequences. We investigated the susceptibility of the resident clone to silver sulphadiazine and to the main topical antimicrobial agents currently used in the burn unit. We proposed an optimized diffusion assay used for comparative analysis of P. aeruginosa strains. The resident clone displayed lower susceptibility to silver sulphadiazine and cerium silver sulphadiazine than strains unrelated to the resident clone in the unit or unrelated to the burn unit.

Conclusions

The diffusion assay developed herein detects differences in behaviour against antimicrobials between tested strains and a reference population. The method could be proposed for use in semi-routine practice of medical microbiology.