Effect of fluconazole on human polymorphonuclear leucocyte functions ex vivo against Candida albicans.

Polymorphonuclear leucocytes (PMNs) are important components of host defence against fungi. We investigated the ex vivo effect of fluconazole on chemotaxis, adherence, superoxide anion (O-2) generation and intracellular killing of Candida albicans blastoconidia after the administration of fluconazole (300 mg per os) to healthy volunteers. With regard to chemotaxis in response to zymosan-activated serum (ZAS), as measured using an agarose gel technique, fluconazole neither increased, nor decreased the chemotaxis of PMNs. The adherence was significantly enhanced after exposure of PMNs to fluconazole under ex vivo conditions, whereas, O-2 production after stimulation of PMNs with ZAS was not affected by fluconazole. The effect of fluconazole on intracellular killing of C. albicans blastoconidia by PMNs was determined by viable colony count, after release of yeast cells from disturbed neutrophils. Fluconazole under in vitro conditions, at a therapeutic concentration, significantly increased the intracellular killing of C. albicans by PMNs at 30 min when compared with the results obtained in ex vivo experiments (p < 0.001). During 90 min of exposure, no significant difference was found between in vitro and ex vivo conditions (p > 0.05).     

Increased in vitro sensitivity of Candida albicans to fluconazole.

Sodium dioctyl sulfosuccinate (SDSS), an anionic surfactant used at a non-antimicrobial concentration, increased the sensitivity of Candida albicans to fluconazole in complex media (such as Sabouraud). The conditions were assessed to determine the in vitro sensitivity to fluconazole. In this connection, the use of a liquid medium at a non-alkaline pH is important. The presence of SDSS in complex media does not seem to affect the neutralization of a particular substances but favours the activity of fluconazole.     

Improved medium for fluconazole susceptibility testing of Candida albicans.

We have compared fluconazole susceptibilities of 92 clinical isolates of Candida albicans by broth microdilution in two different media: standard RPMI 1640 (RPMI) and the same medium supplemented with 18 g of glucose per liter (RPMI-glucose). Preparation of media, drugs, and inocula, as well as incubation conditions, followed the preliminary recommendations of the National Committee for Clinical Laboratory Standards (Villanova, Pa.) antifungal agent working group for broth macrodilution tests with antifungal agents, adapted to microdilution. Microtiter plates were agitated for 5 min before spectrophotometric readings were performed with an automatic plate reader set at 405 mm. The MIC endpoint was defined as an inhibitory concentration calculated from the turbidimetric data as a function of the turbidity in the drug-free control wells. The mean absorbances in the drug-free wells in RPMI and RPMI-glucose were, respectively, 0.38 (41.6% transmission) and 0.99 (10.2% transmission) (P < 0.001; Student's t test). Despite the increased growth in RPMI-glucose, 98.9% of the C. albicans strains tested for fluconazole susceptibility yielded similar MICs (+/- 1 dilution) in both media. Moreover, strains with decreased susceptibility to fluconazole displaying similar MICs in both media are easier to detect in RPMI-glucose because of the greater differences between turbidimetric readings in wells with grown or fluconazole-inhibited cultures. This objective turbidimetric method, with an easy-to-read improved medium (RPMI with glucose), together with previous experience of the National Committee for Clinical Laboratory Standards antifungal agent subcommittee, could overcome some of the present problems associated with lack of reproducibility of azole susceptibility testing.     

Effect of prolonged fluconazole treatment on Candida albicans in diffusion chambers implanted into mice

Fluconazole is an azole agent with primarily fungistatic activity in standard in vitro susceptibility tests. The present study was undertaken to develop a diffusion chamber model system in mice in order to study the in vivo effects of prolonged fluconazole treatment on Candida albicans. Chambers containing 100 C. albicans yeast cells were implanted subcutaneously on the flanks of C57BL/6 mice and were then retrieved 6 or 14 weeks later (after fluconazole treatment for 4 or 12 weeks, respectively). Leukocyte counts demonstrated that implantation of the chambers did elicit an inflammatory response but that only small numbers of inflammatory cells were able to enter the chamber interior. Treatment with fluconazole at 10 mg/kg of body weight/day for 12 weeks not only reduced the numbers of viable organisms within the chambers compared to those in untreated mice (mean +/- standard deviation of log(10) CFU of 0.7 +/- 1.2 versus 2.3 +/- 2.0; P < 0.001 by the Bonferroni test) but also increased the numbers of chambers that became sterile over the treatment period (14 of 16 versus 6 of 19; P = 0.0009 by the chi-square test). However, treatment for only 4 weeks had minimal effects on the numbers of chamber CFU, and none of the chambers became sterile during this period. Distribution of retrieved organisms between interior fluid and the chamber filters was approximately equal in all the treatment groups. This model system appears to be useful for evaluating the effects of antifungal drugs over prolonged periods in vivo. Its use in the present study demonstrates that fluconazole can increase the rate of sterilization of C. albicans foci that are protected from the host's inflammatory response.     

Combinatory effect of fluconazole and FDA-approved drugs against Candida albicans

Candida albicans is the primary cause of systemic candidiasis, which has a high mortality rate. Unfortunately, the number of antifungal drugs available for treatment of Candida infections is limited, and there is an urgent need for development of new drugs and alternative therapeutic options. We investigated the combinatory effect of fluconazole (FLCZ) and 640 FDA-approved drugs in vitro. Ten drugs enhanced and 77 drugs attenuated the antifungal activity of FLCZ. Other drugs did not appear to alter the antifungal activity of FLCZ, although 17 drugs displayed potency equivalent to or greater than that of FLCZ. The 10 FLCZ-enhancing drugs included three inhibitors of 3-hydroxy-3-methyl-glutaryl-CoA reductase, whose synergistic activity had been reported previously. However, the antifungal effects of 3 FLCZ enhancers—artesunate, carvedilol, and bortezomib—were previously unknown. In addition, many drugs were found to attenuate the antifungal activity of FLCZ, including 17 cyclooxygenase (COX) inhibitors, 15 estrogen-related agents, vitamin A- and D-related compounds, antihypertensive drugs, and proton pump inhibitors. Although the clinical significance remains to be determined, analyses of molecular events responsible for synergy or antagonism could provide insight into more efficient use of existing antifungals and lead to novel therapies.     

Synergistic effect of ofloxacin and fluconazole against azole-resistant Candida albicans

We investigated the combination effects of ofloxacin and fluconazole against azole-resistant Candida albicans strains in vitro and in vivo. Ofloxacin alone showed no efficacy against the azole-resistant C. albicans strain, C26. The in-vitro combination effects were evaluated by the checkerboard method, calculated as the fractional inhibitory concentration (FIC) index, but there was no synergistic effect of the combination. The activity of the drug efflux pump in the azole-resistant C. albicans strains was measured by intracellular rhodamine 6G concentration. When the cells were incubated with ofloxacin or grepafloxacin, the intracellular rhodamine 6G concentration was significantly increased in the azole-resistant C. albicans strain. In-vivo combination effects were evaluated in murine disseminated candidiasis. The survival of the mice was not prolonged, but counts of the yeast cells in the kidney and spleen were reduced following treatment with the combination of ofloxacin (20 mg/kg) and fluconazole (20 mg/kg). The combination of ofloxacin and fluconazole may represent an effective strategy to treat infections caused by azole-resistant C. albicans. Received: March 10, 2000 / Accepted: May 17, 2000     

Antifungal pharmacodynamic characteristics of fluconazole and amphotericin B tested against Candida albicans.

Time-kill curves were determined for three isolates of Candida albicans tested against fluconazole and amphotericin B at multiples of the MIC. Fluconazole produced fungistatic activity, with concentration-related growth effects observed over a narrow range of concentrations. Amphotericin B exhibited fungicidal activity, with enhancement of activity over a broader range of concentrations.     

Sequential therapy with caspofungin and fluconazole for Candida albicans infection

A sequential therapy of caspofungin (CAS) and fluconazole (FLC) administration for treatment of Candida albicans infection was investigated. Treatment with CAS followed by FLC was as effective as CAS treatment given alone for the same duration. Our data suggest that switching from CAS to FLC is a potentially explorable therapeutic option for treatment of systemic candidiasis.     

Reversible fluconazole resistance in Candida albicans: a potential in vitro model.

To study the development and potential mechanisms of antifungal resistance in relation to antifungal exposure, reversible fluconazole resistance was examined in vitro. Candida albicans ATCC 36082 blastospores were passed in liquid yeast nitrogen base medium containing either 4, 8, 16, or 128 micrograms of fluconazole per ml, and susceptibility testing was performed after each passage. High-level fluconazole resistance (50% inhibitory concentration, > 256 micrograms/ml) developed in the isolates after serial passage in medium containing 8, 16, or 128 micrograms of fluconazole per ml, but not in isolates passed in 4 micrograms of fluconazole per ml. Reduced susceptibility was noted within four to seven passages, which was equivalent to 14 to 19 days of exposure to the drug. However, all isolates returned to the susceptible phenotype after 8 to 15 passages in medium lacking the drug; thus, fluconazole resistance was reversible in vitro. In vivo, organisms retained the resistant phenotype after a single passage in the rabbit model of infective endocarditis. Restriction digest profiles and karyotypic analysis of the parent strain and selected fluconazole-resistant and -susceptible isolates from each group were identical. Investigations into the molecular mechanisms of this reversible resistance failed to reveal increased accumulation of mRNA for 14 alpha-demethylase, the target enzyme for fluconazole, or for the candidal multidrug transporters CDR1 and BENr. This process of continuous in vitro exposure to antifungal drug may be useful as a model for studying the effects of different antifungal agents and dosing regimens on the development of resistance and for defining the mechanism(s) of reversible resistance.     

ERG11基因突变与白念珠菌对氟康唑耐药性的初步研究

目的探讨白念珠菌氟康唑作用的靶酶编码基因（ERG11）突变与氟康唑耐药性的关系。方法采用聚合酶链反应（PCR）扩增临床分离的23株白念珠菌ERG11基因,包括2株耐氟康唑株、9株氟康唑剂量依赖敏感株和12株氟康唑敏感株,并进行双向测序。应用B last软件,将测序结果与网上已发表序列（GenBankAY856352）进行比对,以确定是否发生基因突变。结果23株白念珠菌的ERG11基因序列共检出16个同义突变位点和18个错义突变位点。错义突变中Y205E、I437V、A255V、E260V、K487N、G472R、N435V、D502E、K143Q为新发现的突变位点。结论Y205E、I437V、A255V位点突变发现于敏感株,可能与白念珠菌耐药无关;K487N、G472R、N435V、D502E、E260V发现于剂量依赖敏感株,K143Q发现于耐药株,可能与耐药的形成有关。     

Synergistic effect of calcineurin inhibitors and fluconazole against Candida albicans biofilms

Calcineurin is a Ca2+-calmodulin-activated serine/threonine-specific protein phosphatase that governs multiple aspects of fungal physiology, including cation homeostasis, morphogenesis, antifungal drug susceptibility, and virulence. Growth of Candida albicans planktonic cells is sensitive to the calcineurin inhibitors FK506 and cyclosporine A (CsA) in combination with the azole antifungal fluconazole. This drug synergism is attributable to two effects: first, calcineurin inhibitors render fluconazole fungicidal rather than simply fungistatic, and second, membrane perturbation by azole inhibition of ergosterol biosynthesis increases intracellular calcineurin inhibitor concentrations. C. albicans cells in biofilms are up to 1,000-fold more resistant to fluconazole than planktonic cells. In both in vitro experiments and in an in vivo rat catheter model, C. albicans cells in biofilms were resistant to individually delivered fluconazole or calcineurin inhibitors but exquisitely sensitive to the combination of FK506-fluconazole or CsA-fluconazole. C. albicans strains lacking FKBP12 or expressing a dominant FK506-resistant calcineurin mutant subunit (Cnb1-1) formed biofilms that were resistant to FK506-fluconazole but susceptible to CsA-fluconazole, demonstrating that drug synergism is mediated via direct calcineurin inhibition. These findings reveal that calcineurin contributes to fluconazole resistance of biofilms and provide evidence that synergistic drug combinations may prove efficacious as novel therapeutic interventions to treat or prevent biofilms.     

Effects of amphotericin B and fluconazole on the extracellular and intracellular growth of Candida albicans.

The effects of amphotericin B and fluconazole on the extracellular and intracellular growth of Candida albicans were studied. With respect to the extracellular growth of C. albicans, antifungal activity was measured in terms of MICs and minimal fungicidal concentrations as well as by determination of the concentration that effectively killed (greater than 99.9%) C. albicans in the absence or presence (amphotericin B only) of serum. Amphotericin B was highly active in terms of killing, even at an increased inoculum size. In the presence of serum, amphotericin B activity was substantially reduced. For fluconazole, activity was restricted to inhibition of fungal growth, even after the inoculum size was reduced. With respect to the intracellular growth of C. albicans, antifungal activity was measured by using monolayers of murine peritoneal macrophages infected with C. albicans and was measured in terms of inhibition of germ tube formation as well as effective killing (greater than 99%) of C. albicans. Amphotericin B was highly active against C. albicans. At an increased ratio of infection, amphotericin B activity was slightly reduced. Fluconazole had no antifungal activity. Neither a reduction in the ratio of infection nor exposure of C. albicans to fluconazole prior to macrophage ingestion resulted in activity against intracellular C. albicans by fluconazole. Previous exposure of C. albicans to amphotericin B resulted in increased intracellular activity of amphotericin B. The intracellular antifungal activity of the combination of fluconazole with amphotericin B was less than that of amphotericin B alone. Amphotericin B showed fungicidal activity against C. albicans growing both extracellularly and intracellularly, whereas fluconazole inhibited growth only of extracellular C. albicans. A slight antagonistic effect between fluconazole and amphotericin B was found with respect to intracellular as well as extracellular C. albicans.     

Effects of cetylpyridinium chloride resistance and treatment on fluconazole activity versus Candida albicans

Mouthwash antiseptic cetylpyridinium chloride (CPC) has potent activity against Candida albicans; however, two of five azole-resistant strains showed reduced CPC susceptibility. To further examine the potential for cross-resistance, CPC-resistant mutants were selected in vitro and their fluconazole susceptibility was tested. MICs were unchanged, and trailing growth generally decreased. With CPC-fluconazole combinations, both antagonism and synergism were observed, which can be explained, in part, by CDR1-CDR2 multidrug transporter upregulation.     

Biofilm formation by fluconazole-resistant Candida albicans strains is inhibited by fluconazole

OBJECTIVES: The fungal pathogen Candida albicans forms biofilms on implanted medical devices, resulting in infections with high mortality. Fully developed biofilms, which are adherent communities of microorganisms, characteristically exhibit high resistance to antimicrobial drugs, making treatment of device-associated infection problematic. The aim of this study was to determine the effect of the addition of the azole antifungal fluconazole on the initiation of biofilm formation by both drug-susceptible and drug-resistant C. albicans strains. RESULTS: Our data reported here show that biofilm formation by both fluconazole-susceptible and fluconazole-resistant C. albicans strains was inhibited when fluconazole was present. For the fluconazole-susceptible strains, inhibition of growth due to the presence of the antifungal drug probably prevented the acquisition of high-level fluconazole resistance. However, for fluconazole-resistant strains, the inhibition of biofilm development was unexpected. CONCLUSIONS: Unexpectedly, fluconazole inhibited biofilm formation by a variety of laboratory isolated and clinically isolated fluconazole-resistant strains.     

Modulation of interactions of Candida albicans and endothelial cells by fluconazole and amphotericin B.

Using an in vitro model of intravascular infection, we examined the effects of exposure to subinhibitory concentrations of fluconazole and amphotericin B on the ability of Candida albicans to adhere to and damage human umbilical vein endothelial cells. Incubation of the organisms for 18 h in 0.5x the MICs of fluconazole and amphotericin B inhibited endothelial cell adherence by 22 and 91%, respectively (P less than 0.001 for each drug). Candida-induced endothelial cell injury was also decreased by exposing the organisms to the antifungal drugs while in contact with the endothelial cells. Fluconazole inhibited damage by approximately 50% at concentrations ranging from 0.25x to 5x the MIC (P less than 0.01 for each concentration). Exposure to amphotericin B at 0.5x the MIC completely blocked the ability of the organisms to injure endothelial cells. The capacities of the antifungal agents to inhibit endothelial cell injury paralleled their abilities to suppress candidal germination. Organisms exposed to up to 5x the MIC of fluconazole had diminished, but still detectable, germ tube production and elongation, whereas incubation in 0.5x the MIC of amphotericin B completely abrogated germination. In addition to their direct effects on the growth of C. albicans, fluconazole and amphotericin B may decrease the ability of the fungus to disseminate hematogenously by inhibiting the organisms' capacity to adhere to and injure endothelial cells.     

Potent synergism of the combination of fluconazole and cyclosporine in Candida albicans

Several types of drugs currently used in clinical practice were screened in vitro for their potentiation of the antifungal effect of the fungistatic agent fluconazole (FLC) on Candida albicans. These drugs included inhibitors of multidrug efflux transporters, antimicrobial agents, antifungal agents, and membrane-active compounds with no antimicrobial activity, such as antiarrhythmic agents, proton pump inhibitors, and platelet aggregation inhibitors. Among the drugs tested in an agar disk diffusion assay, cyclosporine (Cy), which had no intrinsic antifungal activity, showed a potent antifungal effect in combination with FLC. In a checkerboard microtiter plate format, however, it was observed that the MIC of FLC, as classically defined by the NCCLS recommendations, was unchanged when FLC and Cy were combined. Nevertheless, if a different reading endpoint corresponding to the minimal fungicidal concentration needed to decrease viable counts by at least 3 logs in comparison to the growth control was chosen, the combination was synergistic (fractional inhibitory concentration index of <1). This endpoint fitted to the definition of MIC-0 (optically clear wells) and reflected the absence of the trailing effect, which is the result of a residual growth at FLC concentrations greater than the MIC. The MIC-0 values of FLC and Cy tested alone in C. albicans were >32 and >10 microg/ml, respectively, and decreased to 0.5 and 0.625 microg/ml when the two drugs were combined. The combination of 0.625 microg of Cy per ml with supra-MICs of FLC resulted in a potent antifungal effect in time-kill curve experiments. This effect was fungicidal or fungistatic, depending on the C. albicans strain used. Since the Cy concentration effective in vitro is achievable in vivo, the combination of this agent with FLC represents an attractive perspective for the development of new management strategies for candidiasis.     

Effect of amphotericin B, fluconazole and itraconazole on intracellular Candida albicans and germ tube development in macrophages

Candida albicans may resist intracellular killing by macrophages through the formation of germ tubes. Antifungal drugs that inhibit intracellular germ tube formation could therefore facilitate host defence against C. albicans. We assessed the effects of amphotericin B and the new triazole drugs fluconazole and itraconazole on the multiplication and intracellular germ tube formation of C. albicans phagocytosed by murine peritoneal macrophages, and compared the findings with the effects of these drugs on C. albicans in the absence of macrophages. The fungicidal effect of amphotericin B against C. albicans in macrophages was less prominent than that found for extracellular candida. However, amphotericin B completely blocked germ tube formation of C. albicans both in macrophages and extracellularly. Fluconazole and itraconazole had little effect on the number of candida but significantly, although incompletely, inhibited germ tube formation both inside macrophages and extracellularly. The inhibition of intracellular germ tube formation by the triazoles may facilitate host defences against C. albicans and contribute to the efficacies of these drugs in vivo.     

Effects of cytokines and fluconazole on the activity of human monocytes against Candida albicans

This study evaluates the effects of cytokines, used singly and in combination, on the microbicidal activity of human monocyte-derived macrophages (MDM) against intracellular Candida albicans in the presence and absence of fluconazole. In the absence of fluconazole, the addition of tumor necrosis factor alpha (TNF-alpha), interleukin-1beta (IL-1beta), gamma interferon (IFN-gamma), or IL-4 had no effect on the growth of C. albicans. In contrast, the addition of granulocyte-macrophage colony-stimulating factor (GM-CSF) resulted in decreased growth (P < 0.05), while the addition of IL-10 resulted in increased growth (P < 0.01). In the presence of fluconazole, only the addition of IFN-gamma resulted in an increase in the growth of C. albicans. In the presence or absence of fluconazole, all cytokine combinations except IFN-gamma plus GM-CSF caused significant decreases in growth (P < 0.01). IL-10 and IL-4 did not influence the activity of TNF-alpha or IL-1beta. In the absence or presence of C. albicans the addition of fluconazole, all of the cytokines studied, and combinations of fluconazole and selected cytokines caused increases in nitric oxide (NO) production (P < 0.01). Similar observations were made for superoxide (O(2)(-)) only in the presence of C. albicans. The greatest concentrations of NO and O(2)(-) were produced when C. albicans alone was present in the assays. Our results demonstrate that in the presence of low concentrations of fluconazole (0.1 times the MIC), selected cytokines and their combinations significantly increase the microbicidal activity of MDM against intracellular C. albicans.     

Adherence of Candida albicans to silicone induces immediate enhanced tolerance to fluconazole

Wild-type and efflux pump-deficient cells of Candida albicans adhering to silicone were compared with planktonic cells by flow cytometry for their relative resistance to fluconazole (FCZ). Flow cytometry data on cells carrying a fusion of green fluorescent protein to efflux pump promoters confirmed that enhanced tolerance of attached cells to FCZ was due in part to increased expression of CaMDR1 and CDR1 promoters. Within 2 h of their attachment to silicone, the adherent cells demonstrated levels of FCZ tolerance shown by cells from 24-h biofilms. Following their mechanical detachment, this subset of cells retained a four- to eightfold increase in tolerance compared with the tolerance of planktonic cells for at least two generations. Enhanced efflux pump tolerance to FCZ appeared to be induced within the initial 15 min of attachment in a subset of cells that were firmly attached to the substrata.     

Pharmacodynamics of fluconazole, itraconazole, and amphotericin B against Candida albicans

The objective of this study was to evaluate the pharmacodynamic activity of fluconazole, itraconazole, and amphotericin B against Candida albicans. Susceptibilities were determined according to the NCCLS guidelines (M27). Time-kill studies were performed using antifungal concentrations of 0.25-32 x MIC. Samples were withdrawn at predetermined timepoints, then plated using a spiral plater. Colony counts were determined after incubation at 35 degrees C for 24 h. The AUKC(0-48) was plotted against the concentration/MIC ratio. Candida isolates (95-2672, 96-15, and 95-2542) were classified as susceptible, susceptible-dose dependent, and resistant to fluconazole and itraconazole (MIC = 0.25 and 0.03 microg/mL, 32 and 0.5 microg/mL, 64 and 1 microg/mL; respectively). All three isolates were susceptible to amphotericin B (MIC = 0.13 microg/mL). Fluconazole inhibited the growth of the susceptible and S-DD isolates and was ineffective at all concentrations against the resistant isolate. Itraconazole, on the other hand, inhibited growth of the susceptible isolate, but was ineffective for the S-DD and resistant isolates. Maximal effectiveness was noted at the concentration 8 x MIC and 2 x MIC for fluconazole and itraconazole, respectively. Amphotericin B demonstrated concentration-dependent antifungal activity. The times necessary for the colony counts to fall below the limit of quantification were inversely related to increasing concentrations of amphotericin B. The maximal effect for amphotericin B was recorded at 2 x MIC. In summary, the triazoles inhibit growth of susceptible C. albicans; however, careful consideration should be given to the MIC for S-DD isolates because itraconazole may not be active if the MIC is reported in the higher susceptible-dose dependency range. In reference to amphotericin B, optimal activity may be achieved by maximizing the peak drug concentration/MIC ratio.