Azole-Resistant Invasive Aspergillosis: Relationship to Agriculture

Azole resistance in Aspergillus fumigatus has been increasingly reported particularly over the last decade. Two routes of acquisition are described: selection of resistance during long term azole therapy in the clinical setting, and primary acquisition of resistant isolates from the environment due to the considerable use of azole fungicides in agriculture and for material preservation. Three specific resistance genotypes have been found in azole naïve patients. Two of these have also been found in the environment and are characterized by a tandem repeat in the promoter region of the target gene coupled with point mutation(s) in CYP51A (TR₃₄/L98H and TR₄₆/Y121F/T289A). In the third a single target enzyme alteration (G432S) is found. These resistant “environmental” strains have been detected in many West-European countries as well as in the Asia-Pacifics. Noticeably, these two continents account for the highest fungicide use in the global perspective (37 % and 24 %, respectively). Among the 25 azole fungicides, five have been associated with the potential to select for the TR₃₄/L98H genotype; three of these are among those most frequently used. Although the number of antifungal fungicide compounds and classes available is impressive compared to the armamentarium in human medicine, azoles will remain the most important group in agriculture due to superior field performance and significant resistance in fungal pathogens to other compounds. Hence, further spread of environmental resistant Aspergillus genotypes may occur and will depend on the fitness of each resistant phenotype and the pattern of azole fungicide use.     

Antifungal Susceptibility Testing of <Emphasis Type="Italic">Candida</Emphasis> and <Emphasis Type="Italic">Cryptococcus</Emphasis> Species and Mechanisms of Resistance: Implications for Clinical Laboratories

Purpose of Review

Resistance to antifungal drugs amongst Candida species is a growing concern, and azole resistance may be emerging in Cryptococcus species. This review provides a contemporary perspective, relevant to the clinical mycology laboratory, of antifungal susceptibility testing of these fungi, focussing on the challenges of phenotypic and genotypic methodologies to detect drug resistance.

Recent Findings

Standardised CLSI and EUCAST broth microdilution (BMD) susceptibility testing methods are the benchmark to determine clinical breakpoints (CBPs) and/or epidemiological cut-off values (ECVs) MICs for Candida and Cryptococcus spp. Commercial methods may be used but caution is required when employing BMD CBPs/ECVs to interpret results. Species-specific CBPs/ECVs for Candida spp. generally correlate well with predicting likelihood of therapeutic failure or of presence of a drug resistance mechanism with the exception of the echinocandins where the presence of specific FKS gene mutations and not the MIC correlates most accurately with clinical outcome. The relationship of presence of one or more mechanisms of azole resistance and drug MICs is uncertain. Next generation sequencing technology is offering insights into the relationships between susceptibility results obtained by phenotypic and genotypic methods. For Cryptococcus spp., CBPs are not established but species- and genetic type-specific EVCs are useful for guiding therapy where clinically indicated. Isolates of genotype VGII appear to exhibit the highest MICs.

Summary

Antifungal susceptibility testing of yeasts is important to detect drug resistance. For Candida spp., MICs have clinical utility for the azoles but detecting echinocandin resistance by genotypic methods is preferred. For Cryptococcus spp., ECVs are useful in guiding therapy.

     

Biofilm Formation and its Impact on Antifungal Therapy

Fungi can protect themselves from host defences and antifungal drugs by the production of an extracellular hydrophobic matrix. Candida biofilms exhibit resistance to antifungal agents from all classes including the azoles, echinocandins, amphotericin B complex, and flucytosine. Although demonstrated on polystyrene and bronchial epithelia cells, until today, only indirect evidence for A. fumigatus biofilms in patients is available. The antifungals with the most activity against biofilms are the liposomal formulation of amphotericin B and agents in the echinocandin drug class. Importantly, echinocandins show excellent anti-biofilm activity against C. albicans at therapeutic concentrations. However, other biofilms formed by moulds, including A. fumigatus, are relatively resistant to echinocandins. Multiple mechanisms contribute to the intrinsic and acquired antifungal resistance during the different stages of fungal biofilm development. During the growth phase of the early biofilm various factors account for biofilm resistance. Combinational and sequential antifungal therapy as well as combination with enhancers can improve the effect of a single drug. Further studies are warranted to develop new therapeutic strategies targeting fungal biofilm-specific resistance mechanisms.     

Breakthrough pulmonary Aspergillus fumigatus infection with multiple triazole resistance in a Spanish patient with chronic myeloid leukemia

BackgroundAn allogeneic hematopoietic cell transplantation (allo-HCT) patient presented with chronic pulmonary aspergillosis associated to pulmonary graft versus host disease (GVHD) and was treated for a long time with several antifungal agents that were administered as prophylaxis, combination therapies, and maintenance treatment. The patient suffered from a breakthrough invasive pulmonary aspergillosis due to Aspergillus fumigatus after long-term antifungal therapy.Material and methodsSeveral isolates were analyzed. First isolates were susceptible in vitro to all azole agents. However, after prolonged treatment with itraconazole and voriconazole a multiple azole resistant A. fumigatus isolate was cultured from bronchoalveolar lavage (BAL) when the patient was suffering from an invasive infection, and cavitary lesions were observed.ResultsAnalysis of the resistant mechanisms operating in the last strain led us to report the first isolation in Spain of an azole resistant A. fumigatus strain harboring the L98H mutation in combination with the tandem repeat (TR) alteration in CYP51A gene (TR-L98H). Long-term azole therapy may increase the risk of resistance selecting strains exhibiting reduced susceptibility to these compounds. However, since the isolates were genetically different the suggestion that could be made is that the resistance was not induced during the prolonged azole therapy but the patient might simply have acquired this resistant isolate from the environment, selected by the therapy.ConclusionsThese findings suggest that in all long-term treatments with antifungal agents, especially with azoles, repeated sampling and regular susceptibility testing of strains isolated is necessary as resistant isolates could be selected.     

Antifungal Drug Resistance: Clinical Relevance and Impact of Antifungal Drug Use

Antifungal drug resistance significantly impacts treatment outcomes in patients with invasive fungal infections (IFIs). Although primary (intrinsic) resistance may occur independent of previous therapy, prior concomitant antifungal exposure increases the risk for secondary (acquired) resistance and subsequent colonization or infection with less-susceptible pathogens. Among various pathogen-antifungal combinations, this effect has been best studied clinically with azole exposure and the risk of Candida spp. with reduced susceptibility. The rapid development of secondary resistance to flucytosine in Candida spp. has limited its use as monotherapy. Secondary resistance to amphotericin B is infrequent. In contrast, secondary resistance in Aspergillus spp. is less of a concern. Recent reports of secondary resistance in patients receiving fluconazole for cryptococcal infections may justify susceptibility testing in the setting of prior therapy or treatment failure. Despite numerous patient-focused, drug-focused, and disease-focused strategies to improve treatment outcomes, clinical resistance (manifesting as treatment failures despite adequate antifungal therapy) continues to be problematic in patients with serious IFIs.     

Update on Antifungal Resistance and its Clinical Impact

Candida and Aspergillus species are important causes of opportunistic infection in an ever-growing number of vulnerable patients, and these infections are associated with high mortality. This has partly been attributed to the emerging resistance of pathogenic fungi to antifungal therapy, which potentially compromises the management of infected patients. Multi-azole resistance of Aspergillus fumigatus is a current health problem, as well as is the co-resistance of Candida glabrata to both azoles and echinocandins. In most cases, negative clinical consequences of reduced in vitro fungal susceptibility to azoles and/or echinocandins can be traced to acquisition of particular resistance mechanisms. While strategies using antifungal combinations or adjunctive agents that maximize the efficacy of existing antifungals may limit treatment failures, new therapeutic approaches, including antifungal agents with novel mechanisms of action, are urgent. In the meantime, more efforts should be devoted to close monitoring of antifungal resistance and its evolution in the clinical setting.     

Investigation of aryl isonitrile compounds with potent,broad-spectrum antifungal activity

Invasive fungal infections present a formidable global public health challenge due to the limited number of approved antifungal agents and the emergence of resistance to the frontline treatment options, such as fluconazole. Three fungal pathogens of significant concern are Candida, Cryptococcus, and Aspergillus given their propensity to cause opportunistic infections in immunocompromised individuals. New antifungal agents composed of unique chemical scaffolds are needed to address this public health challenge. The present study examines the structure-activity relationship of a set of aryl isonitrile compounds that possess broad-spectrum antifungal activity primarily against species of Candida and Cryptococcus. The most potent derivatives are capable of inhibiting growth of these key pathogens at concentrations as low as 0.5 µM. Remarkably, the most active compounds exhibit an excellent safety profile and are non-toxic to mammalian cells even at concentrations up to 256 µM. The present study lays the foundation for further investigation of aryl isonitrile compounds as a new class of antifungal agents.     

Structure–activity relationship of cytochrome bc1 reductase inhibitor broad spectrum antifungal ilicicolin H

Ilicicolin H is a broad spectrum antifungal agent showing sub micro g/mL MICs against Candida spp., Aspergillus fumigatus and Cryptococcus spp. It is a potent inhibitor (C₅₀ 2–3 ng/mL) of the mitochondrial cytochrome bc1 reductase with over 1000-fold selectivity against rat liver cytochrome bc1 reductase. Structure–activity relationship of semisynthetic derivatives by chemical modification of ilicicolin H and its 19-hydroxy derivative produced by biotransformation have been described. Basic 4′-esters and moderately polar N- and O-alkyl derivatives retained antifungal and the cytochrome bc1 reductase activities. 4′,19-Diacetate and 19-cyclopropyl acetate retained antifungal and enzyme activity and selectivity with over 20-fold improvement of plasma protein binding.     

Azole resistance in aspergillosis: The next threat?

During the past years, aspergilli less susceptible to antifungals have begun to emerge, and antifungal drug resistance may partially account for treatment failures. Resistance of Aspergillus fumigatus clinical isolates to itraconazole, voriconazole, and posaconazole has been reported with increasing frequency, although it is considered an uncommon phenomenon. Molecular biologists have begun to shed light on the mechanisms of A. fumigatus resistance to azoles. Several mechanisms of resistance have been described, such as point mutations of cyp51A and reduced concentrations of intracellular drug. The latter mechanism might be the result of either overexpression of efflux pumps or reduced drug penetration. The issue of cross-resistance between the newer triazoles is of concern and depends on cyp51 mutations. Fungal drug resistance is an issue because of the limited number of antifungal compounds. Patients receiving long-term azole treatment are at highest risk for developing multidrug-resistant A. fumigatus infections.     

The Widely Used ATB FUNGUS 3 Automated Readings in China and Its Misleading High MICs of Candida spp. to Azoles: Challenges for Developing Countries' Clinical Microbiology Labs

The rapid development in the clinical microbiology diagnostic assays presents more challenges for developing countries than for the developed world, especially in the area of test validation before the introduction of new tests. Here we report on the misleading high MICs of Candida spp. to azoles using the ATB FUNGUS 3 (bioMérieux, La Balme-les Grottes, France) with automated readings in China to highlight the dangers of introducing a diagnostic assay without validation. ATB FUNGUS 3 is the most commonly used commercial antifungal susceptibility testing method in China. An in-depth analysis of data showed higher levels of resistance to azoles when ATB FUNGUS 3 strips were read automatically than when read visually. Based on this finding, the performance of ATB FUNGUS 3, read both visually and automatically, was evaluated by testing 218 isolates of five clinically important Candida species, using broth microdilution (BMD) following CLSI M27-A3 as the gold-standard. The overall essential agreement (EA) between ATB visual readings and BMD was 99.1%. In contrast, the ATB automated readings showed higher discrepancies with BMD, with overall EA of 86.2%, and specifically lower EA was observed for fluconazole (80.7%), voriconazole (77.5%), and itraconazole (73.4%), which was most likely due to the trailing effect of azoles. The major errors in azole drug susceptibilities by ATB automated readings is a concern in China that can result in misleading clinical antifungal drug selection and pseudo high rates of antifungal resistance. Therefore, the ATB visual reading is generally recommended. In the meantime, we propose a practical algorithm to be followed for ATB FUNGUS 3 antifungal susceptibility for Candida spp. before the improvement in the automated reading system.     

Azole-resistant Aspergillus fumigatus in the environment: Identifying key reservoirs and hotspots of antifungal resistance

Aspergillus fumigatus is an opportunistic human pathogen that causes aspergillosis, a spectrum of environmentally acquired respiratory illnesses. It has a cosmopolitan distribution and exists in the environment as a saprotroph on decaying plant matter. Azoles, which target Cyp51A in the ergosterol synthesis pathway, are the primary class of drugs used to treat aspergillosis. Azoles are also used to combat plant pathogenic fungi. Recently, an increasing number of azole-naive patients have presented with pan-azole–resistant strains of A. fumigatus. The TR₃₄/L98H and TR₄₆/Y121F/T289A alleles in the cyp51A gene are the most common ones conferring pan-azole resistance. There is evidence that these mutations arose in agricultural settings; therefore, numerous studies have been conducted to identify azole resistance in environmental A. fumigatus and to determine where resistance is developing in the environment. Here, we summarize the global occurrence of azole-resistant A. fumigatus in the environment based on available literature. Additionally, we have created an interactive world map showing where resistant isolates have been detected and include information on the specific alleles identified, environmental settings, and azole fungicide use. Azole-resistant A. fumigatus has been found on every continent, except for Antarctica, with the highest number of reports from Europe. Developed environments, specifically hospitals and gardens, were the most common settings where azole-resistant A. fumigatus was detected, followed by soils sampled from agricultural settings. The TR₃₄/L98H resistance allele was the most common in all regions except South America where the TR₄₆/Y121F/T289A allele was the most common. A major consideration in interpreting this survey of the literature is sampling bias; regions and environments that have been extensively sampled are more likely to show greater azole resistance even though resistance could be more prevalent in areas that are under-sampled or not sampled at all. Increased surveillance to pinpoint reservoirs, as well as antifungal stewardship, is needed to preserve this class of antifungals for crop protection and human health.     

Design, synthesis, and evaluations of antifungal activity of novel phenyl(2H-tetrazol-5-yl)methanamine derivatives

Fungal infections pose a continuous and serious threat to human health and life. The intrinsic resistance has been observed in many genera of fungi. Many fungal infections are caused by opportunistic pathogens that may be endogenous (Candida infections) or acquired from the environment (Cryptococcus and Aspergillus infections). So, new therapeutic strategies are needed to combat various fungal infections. Fluconazole shows good antifungal activity with relatively low toxicity and is preferred as first line antifungal therapy, but it has suffered from severe drug resistance. So, there is a need to design novel analogues by modification of fluconazole-like structure. A novel series of phenyl(2H-tetrazol-5-yl)methanamine derivatives were synthesized by reaction of α-amino nitrile with sodium azide and ZnCl₂ in presence of isopropyl alcohol. They were evaluated for antifungal activity against Candida albicans and Aspergillus niger and subjected to docking study against 1EA1.     

Commercialization of antifungal peptides

There remains an urgent and very much unmet medical need for new antifungal therapies. Ideally, the next generation of treatments for nosocomial and community-acquired infections, including those caused by Candida spp, Aspergillus spp, Cryptococcus spp and Fusarium spp, will be more efficacious, with higher therapeutic indices and broader activity spectra than existing antifungal drug classes. Moreover, future antifungal therapeutics should have novel modes of action/drug targets that at least minimise, if not negate, the risk of acquired resistance developing in their target fungal pathogen populations. In short, developing the next generation of antifungals is a tall order and whoever is successful in doing so must address the various and well-described shortcomings of what remains at present, a very limited choice of largely small molecule-based therapeutics against the fungal infection spectrum. Novel peptide antifungals engineered from a template of mammalian, amphibian and even insect endogenous antimicrobial peptides (AMPs) have clear potential to meet these requirements and consequent clinical success in a range of fungal diseases. This potential will hopefully be realised in the future as any number of the promising preclinical candidate antifungal peptides identified to date are developed further towards the clinic. The size of the ever-increasing market potential as well as unmet clinical need for new antifungal treatments is such that succeeding in delivering novel peptide antifungals as safe and potently efficacious therapies for the future will have a significant health-economic impact.     

Commercialization of antifungal peptides

There remains an urgent and very much unmet medical need for new antifungal therapies. Ideally, the next generation of treatments for nosocomial and community-acquired infections, including those caused by Candida spp, Aspergillus spp, Cryptococcus spp and Fusarium spp, will be more efficacious, with higher therapeutic indices and broader activity spectra than existing antifungal drug classes. Moreover, future antifungal therapeutics should have novel modes of action/drug targets that at least minimise, if not negate, the risk of acquired resistance developing in their target fungal pathogen populations. In short, developing the next generation of antifungals is a tall order and whoever is successful in doing so must address the various and well-described shortcomings of what remains at present, a very limited choice of largely small molecule-based therapeutics against the fungal infection spectrum. Novel peptide antifungals engineered from a template of mammalian, amphibian and even insect endogenous antimicrobial peptides (AMPs) have clear potential to meet these requirements and consequent clinical success in a range of fungal diseases. This potential will hopefully be realised in the future as any number of the promising preclinical candidate antifungal peptides identified to date are developed further towards the clinic. The size of the ever-increasing market potential as well as unmet clinical need for new antifungal treatments is such that succeeding in delivering novel peptide antifungals as safe and potently efficacious therapies for the future will have a significant health-economic impact.     

Resistance to antifungals that target CYP51

Fungal diseases are an increasing global burden. Fungi are now recognised to kill more people annually than malaria, whilst in agriculture, fungi threaten crop yields and food security. Azole resistance, mediated by several mechanisms including point mutations in the target enzyme (CYP51), is increasing through selection pressure as a result of widespread use of triazole fungicides in agriculture and triazole antifungal drugs in the clinic. Mutations similar to those seen in clinical isolates as long ago as the 1990s in Candida albicans and later in Aspergillus fumigatus have been identified in agriculturally important fungal species and also wider combinations of point mutations. Recently, evidence that mutations originate in the field and now appear in clinical infections has been suggested. This situation is likely to increase in prevalence as triazole fungicide use continues to rise. Here, we review the progress made in understanding azole resistance found amongst clinically and agriculturally important fungal species focussing on resistance mechanisms associated with CYP51. Biochemical characterisation of wild-type and mutant CYP51 enzymes through ligand binding studies and azole IC₅₀ determinations is an important tool for understanding azole susceptibility and can be used in conjunction with microbiological methods (MIC₅₀ values), molecular biological studies (site-directed mutagenesis) and protein modelling studies to inform future antifungal development with increased specificity for the target enzyme over the host homologue.     

Clonal Expansion and Emergence of Environmental Multiple-Triazole-Resistant Aspergillus fumigatus Strains Carrying the TR34/L98H Mutations in the cyp51A Gene in India

Azole resistance is an emerging problem in Aspergillus which impacts the management of aspergillosis. Here in we report the emergence and clonal spread of resistance to triazoles in environmental Aspergillus fumigatus isolates in India. A total of 44 (7%) A. fumigatus isolates from 24 environmental samples were found to be triazole resistant. The isolation rate of resistant A. fumigatus was highest (33%) from soil of tea gardens followed by soil from flower pots of the hospital garden (20%), soil beneath cotton trees (20%), rice paddy fields (12.3%), air samples of hospital wards (7.6%) and from soil admixed with bird droppings (3.8%). These strains showed cross-resistance to voriconazole, posaconazole, itraconazole and to six triazole fungicides used extensively in agriculture. Our analyses identified that all triazole-resistant strains from India shared the same TR₃₄/L98H mutation in the cyp51 gene. In contrast to the genetic uniformity of azole-resistant strains the azole-susceptible isolates from patients and environments in India were genetically very diverse. All nine loci were highly polymorphic in populations of azole-susceptible isolates from both clinical and environmental samples. Furthermore, all Indian environmental and clinical azole resistant isolates shared the same multilocus microsatellite genotype not found in any other analyzed samples, either from within India or from the Netherlands, France, Germany or China. Our population genetic analyses suggest that the Indian azole-resistant A. fumigatus genotype was likely an extremely adaptive recombinant progeny derived from a cross between an azole-resistant strain migrated from outside of India and a native azole-susceptible strain from within India, followed by mutation and then rapid dispersal through many parts of India. Our results are consistent with the hypothesis that exposure of A. fumigatus to azole fungicides in the environment causes cross-resistance to medical triazoles. The study emphasises the need of continued surveillance of resistance in environmental and clinical A. fumigatus strains.     

Synthesis and antifungal activity of substituted 2,4,6-pyrimidinetrione carbaldehyde hydrazones

Opportunistic fungal infections caused by the Candida spp. are the most common human fungal infections, often resulting in severe systemic infections—a significant cause of morbidity and mortality in at-risk populations. Azole antifungals remain the mainstay of antifungal treatment for candidiasis, however development of clinical resistance to azoles by Candida spp. limits the drugs’ efficacy and highlights the need for discovery of novel therapeutics. Recently, it has been reported that simple hydrazone derivatives have the capability to potentiate antifungal activities in vitro. Similarly, pyrimidinetrione analogs have long been explored by medicinal chemists as potential therapeutics, with more recent focus being on the potential for pyrimidinetrione antimicrobial activity. In this work, we present the synthesis of a class of novel hydrazone-pyrimidinetrione analogs using novel synthetic procedures. In addition, structure–activity relationship studies focusing on fungal growth inhibition were also performed against two clinically significant fungal pathogens. A number of derivatives, including phenylhydrazones of 5-acylpyrimidinetrione exhibited potent growth inhibition at or below 10 μM with minimal mammalian cell toxicity. In addition, in vitro studies aimed at defining the mechanism of action of the most active analogs provide preliminary evidence that these compound decrease energy production and fungal cell respiration, making this class of analogs promising novel therapies, as they target pathways not targeted by currently available antifungals.     

Urban Pigeons (<Emphasis Type="Italic">Columba livia</Emphasis>) as a Potential Source of Pathogenic Yeasts: A Focus on Antifungal Susceptibility of <Emphasis Type="Italic">Cryptococcus</Emphasis> Strains in Northeast Brazil

To investigate pigeons as a potential source of pathogenic yeast species, 47 samples of pigeon droppings and 322 samples from pigeon cloacae were evaluated. The samples were also collected from trees located near the pigeon habitats, in the city of Fortaleza, Ceará, Northeast Brazil. In addition, we evaluated the in vitro antifungal susceptibility of these environmental Cryptococcus strains to amphotericin B, azoles and caspofungin. C. neoformans var. neoformans (n = 10), C. laurentii (n = 3), Candida spp. (n = 14), Rhodotorula mucilaginosa (n = 6) and Trichosporon sp. (n = 3) were isolated from pigeon droppings. In contrast, only Candida spp. (n = 4), Trichosporon sp. (n = 3) and R. mucilaginosa (n = 2) were recovered from cloacae specimens. Only Candida glabrata (n = 1) was recovered from plant samples. Azole resistance was detected in only one environmental strain of Cryptococcus, which was resistant to itraconazole (MIC = 1 μg/ml). As expected, all Cryptococcus strains were resistant to caspofungin. In summary, the present study confirms that urban pigeons are a potential source of Cryptococcus spp. and other pathogenic yeasts. Additionally, antifungal resistance was observed in one environmental strain of Cryptococcus neoformans var. neoformans in Northeast Brazil.     

Possible Environmental Origin of Resistance of Aspergillus fumigatus to Medical Triazoles

We reported the emergence of resistance to medical triazoles of Aspergillus fumigatus isolates from patients with invasive aspergillosis. A dominant resistance mechanism was found, and we hypothesized that azole resistance might develop through azole exposure in the environment rather than in azole-treated patients. We investigated if A. fumigatus isolates resistant to medical triazoles are present in our environment by sampling the hospital indoor environment and soil from the outdoor environment. Antifungal susceptibility, resistance mechanisms, and genetic relatedness were compared with those of azole-resistant clinical isolates collected in a previous study. Itraconazole-resistant A. fumigatus (five isolates) was cultured from the indoor hospital environment as well as from soil obtained from flower beds in proximity to the hospital (six isolates) but never from natural soil. Additional samples of commercial compost, leaves, and seeds obtained from a garden center and a plant nursery were also positive (four isolates). Cross-resistance was observed for voriconazole, posaconazole, and the azole fungicides metconazole and tebuconazole. Molecular analysis showed the presence of the dominant resistance mechanism, which was identical to that found in clinical isolates, in 13 of 15 environmental isolates, and it showed that environmental and clinical isolates were genetically clustered apart from nonresistant isolates. Patients with azole-resistant aspergillosis might have been colonized with azole-resistant isolates from the environment.Invasive aspergillosis is a fungal disease caused by Aspergillus species that primarily affects immunocompromised patients, such as those treated for hematological malignancy. Patients may become infected by inhalation of ambient air that contains fungal spores. The Aspergillus conidia can penetrate into the alveoli and if not effectively removed, may germinate, proliferate, and cause invasive aspergillosis. Mortality and morbidity due to invasive aspergillosis remain a significant problem.Triazoles, such as itraconazole (ITZ), voriconazole, and posaconazole, are used increasingly in the management of patients with this disease. Although the risk of resistance due to the increased use of triazoles is considered low (11), we recently observed ITZ resistance rapidly emerging in clinical Aspergillus fumigatus isolates (19, 22, 24, 25). Azole resistance was observed in up to 6% of patients in our hospital and in up to 14.5% of isolates sent to our laboratory from other hospitals in The Netherlands, which were obtained from patients with aspergillus disease (19). Furthermore, azole resistance has been reported in other European countries (3, 13, 19). The ITZ-resistant isolates also showed significantly reduced susceptibility to the other mold-active medical triazoles voriconazole and posaconazole (19). A substitution of leucine for histidine at codon 98 (L98H), combined with a 34-bp tandem repeat (designated TR) in the promoter region of the cyp51A gene (TR/L98H), which is the target for antifungal azoles, was found in 94% of isolates (14, 19, 24).Azole resistance can develop through the exposure of the fungus to azole compounds, which may occur in azole-treated patients or through the use of azole compounds in the environment. The dominance of a single resistance mechanism is difficult to explain by resistance development in individual azole-treated patients, as one would expect multiple resistance mechanisms to develop. Also, spread by person-to-person transmission of any Aspergillus isolate is highly unlikely. As inhalation of airborne aspergillus spores is the common route of infection for aspergillus diseases, we hypothesized that the dominance of a single resistance mechanism in clinical ITZ-resistant isolates was more consistent with acquisition from a common environmental source (19). If azole-resistant A. fumigatus is present in our environment, patients could inhale resistant spores and subsequently develop azole-resistant disease. Indeed, azole-resistant aspergillosis was reported in azole-naïve patients, indicating that resistance does not exclusively develop during azole therapy (24).Favorable conditions for resistance development are exposure to azole compounds and the presence of reproducing fungus (1). A. fumigatus is abundantly present in our environment as saprophytic, reproducing fungi, most notably in soil and compost. Furthermore, azoles are commonly used for plant protection as well as material preservation. Therefore, it appears that resistance development in A. fumigatus is feasible in the environment, and isolates that develop resistance to fungicides might be cross-resistant to medical triazoles.We investigated if A. fumigatus isolates that are present in our environment are resistant to medical triazoles and if they are cross-resistant to azole fungicides. Furthermore, we characterized the isolates by microsatellite typing in order to determine if they were genetically related to clinical A. fumigatus isolates previously obtained from patients cared for in our University Medical Center.