Effect of temperature and water activity on the production of fumonisins by Aspergillus niger and different Fusariumspecies

Background

Amino acid substitutions in the target enzyme Erg11p of azole antifungals contribute to clinically-relevant azole resistance in Candida albicans. A simple molecular method for rapid detection of ERG11 gene mutations would be an advantage as a screening tool to identify potentially-resistant strains and to track their movement. To complement DNA sequencing, we developed a padlock probe and rolling circle amplification (RCA)-based method to detect a series of mutations in the C. albicans ERG11 gene using "reference" azole-resistant isolates with known mutations. The method was then used to estimate the frequency of ERG11 mutations and their type in 25 Australian clinical C. albicans isolates with reduced susceptibility to fluconazole and in 23 fluconazole-susceptible isolates. RCA results were compared DNA sequencing.

Results

The RCA assay correctly identified all ERG11 mutations in eight "reference" C. albicans isolates. When applied to 48 test strains, the RCA method showed 100% agreement with DNA sequencing where an ERG11 mutation-specific probe was used. Of 20 different missense mutations detected by sequencing in 24 of 25 (96%) isolates with reduced fluconazole susceptibility, 16 were detected by RCA. Five missense mutations were detected by both methods in 18 of 23 (78%) fluconazole-susceptible strains. DNA sequencing revealed that mutations in non-susceptible isolates were all due to homozygous nucleotide changes. With the exception of the mutations leading to amino acid substitution E266D, those in fluconazole-susceptible strains were heterozygous. Amino acid substitutions common to both sets of isolates were D116E, E266D, K128T, V437I and V488I. Substitutions unique to isolates with reduced fluconazole susceptibility were G464 S (n = 4 isolates), G448E (n = 3), G307S (n = 3), K143R (n = 3) and Y123H, S405F and R467K (each n = 1). DNA sequencing revealed a novel substitution, G450V, in one isolate.

Conclusion

The sensitive RCA assay described here is a simple, robust and rapid (2 h) method for the detection of ERG11 polymorphisms. It showed excellent concordance with ERG11 sequencing and is a potentially valuable tool to track the emergence and spread of azole-resistant C. albicans and to study the epidemiology of ERG11 mutations. The RCA method is applicable to the study of azole resistance in other fungi.     

The new mutation L321F in Candida albicans ERG11 gene may be associated with fluconazole resistance

BackgroundFor many years fluconazole has been commonly used to treat Candida infections. However, the indiscriminate use of this antimycotic therapy has favored the emergence of resistant isolates. Mutations in the ERG11 gene have been described as one of the primary mechanisms of resistance in Candida species.AimsIn this study we investigated missense mutations in ERG11 genes of Candida albicans, Candida glabrata and Candida tropicalis isolates previously evaluated by susceptibility testing to fluconazole.MethodsScreening for these mutations was performed on 19 Candida clinical isolates (eight C. albicans, five C. glabrata and six C. tropicalis) resistant and susceptible to fluconazole. The ERG11 gene was amplified by PCR with specific primers for each Candida species and analyzed by automated sequencing.ResultsWe identified 14 different missense mutations, five of which had not been described previously. Among them, a new mutation L321F was identified in a fluconazole resistant C. albicans isolate and it was analyzed by a theoretical three-dimensional structure of the ERG11p.ConclusionThe L321F mutation in C. albicans ERG11 gene may be associated with fluconazole resistance.     

Novel point mutations in the ERG11 gene in clinical isolates of azole resistant Candida species

The azoles are the class of medications most commonly used to fight infections caused by Candida sp. Typically, resistance can be attributed to mutations in ERG11 gene (CYP51) which encodes the cytochrome P450 14α-demethylase, the primary target for the activity of azoles. The objective of this study was to identify mutations in the coding region of theERG11 gene in clinical isolates of Candidaspecies known to be resistant to azoles. We identified three new synonymous mutations in the ERG11 gene in the isolates of Candida glabrata (C108G, C423T and A1581G) and two new nonsynonymous mutations in the isolates of Candida krusei - A497C (Y166S) and G1570A (G524R). The functional consequence of these nonsynonymous mutations was predicted using evolutionary conservation scores. The G524R mutation did not have effect on 14α-demethylase functionality, while the Y166S mutation was found to affect the enzyme. This observation suggests a possible link between the mutation and dose-dependent sensitivity to voriconazole in the clinical isolate of C. krusei. Although the presence of the Y166S in phenotype of reduced azole sensitivity observed in isolate C. kruseidemands investigation, it might contribute to the search of new therapeutic agents against resistant Candida isolates.     

Targeted amplification and MinION nanopore sequencing of key azole and echinocandin resistance determinants of clinically relevant Candida spp. from blood culture bottles

The objective of the study was to evaluate the use of targeted multiplex Nanopore MinION amplicon re-sequencing of key Candida spp. from blood culture bottles to identify azole and echinocandin resistance associated SNPs. Targeted PCR amplification of azole (ERG11 and ERG3) and echinocandin (FKS) resistance-associated loci was performed on positive blood culture media. Sequencing was performed using MinION nanopore device with R9.4.1 Flow Cells. Twenty-eight spiked blood cultures (ATCC strains and clinical isolates) and 12 prospectively collected positive blood cultures with candidaemia were included. Isolate species included Candida albicans, Candida glabrata, Candida krusei, Candida parapsilosis, Candida tropicalis and Candida auris. SNPs that were identified on ERG and FKS genes using Snippy tool and CLC Genomic Workbench were correlated with phenotypic testing by broth microdilution (YeastOne™ Sensititre). Illumina whole-genome-sequencing and Sanger-sequencing were also performed as confirmatory testing of the mutations identified from nanopore sequencing data. There was a perfect agreement of the resistance-associated mutations detected by MinION-nanopore-sequencing compared to phenotypic testing for acquired resistance (16 with azole resistance; 3 with echinocandin resistance), and perfect concordance of the nanopore sequence mutations to Illumina and Sanger data. Mutations with no known association with phenotypic drug resistance and novel mutations were also detected.     

两株希木龙假丝酵母14α-去甲基化酶基因(ERG11)的克隆及其功能初步验证

为探讨希木龙假丝酵母(假丝酵母又称念珠菌)的耐药机制,首先克隆出两株希木龙念珠菌ERG11基因,初步验证其功能,从而为后续研究奠定基础。从美国国家生物技术信息中心(National Center of Biotechnology Information,NCBI)基因数据库中获取白念珠菌、热带念珠菌、近平滑念珠菌和光滑念珠菌Erg11蛋白的保守序列,设计简并引物,聚合酶链反应(polymerase chain reaction,PCR)扩增获得希木龙念珠菌ERG11cDNA部分片段;用快速cDNA末端扩增法(rapid amplification of cDNA ends,RACE)分别扩增其5′和3′端,获得完整的ERG11编码序列(coding sequence,CDS);将CDS克隆到pYES2表达载体中,在尿嘧啶营养缺陷型酿酒酵母中过表达ERG11;用微量液基稀释法检测转化后的酿酒酵母对氟康唑的敏感性,初步验证其功能。结果显示,简并PCR扩增获得预期708bp片段,5′RACE和3′RACE分别获得385bp和1 336bp片段,经纯化、克隆、测序、比对分析,获得两株菌的ERG11CDS;比对其编码的蛋白,与其他念珠菌的Erg11蛋白高度同源;分别检测克隆了这两株希木龙念珠菌ERG11CDS表达载体的酿酒酵母对氟康唑的敏感性,发现过表达ERG11明显降低其对氟康唑的敏感性。结果提示,简并PCR联合RACE能准确有效地克隆出希木龙念珠菌ERG11基因,用pYES2酿酒酵母表达系统能初步验证其功能。     

牛源近平滑念珠菌对氟康唑耐药性研究

以牛源近平滑念珠菌（Candida parapsilosis）为试验菌株,采用微量稀释法进行药物敏感性试验,PCR扩增测序检测ERG11基因突变,Realtime PCR检测ERG11、CDR1、MDR1、MRR1基因的mRNA表达量,探讨耐药相关基因在牛源近平滑念珠菌耐唑类药物中的作用,为牛源近平滑念珠菌的耐药研究提供参考。结果表明,近平滑念珠菌对5-氟胞嘧啶、两性霉素Ｂ的敏感率均高于75%,对唑类药物的耐药率均高于50%,其中对氟康唑的耐药率最高,达58.3%;所有菌株的ERG11基因中均检测出错义突变A395T,耐氟康唑和剂量依赖菌株的ERG11基因中检测出同义突变T591C;氟康唑耐药组ERG11、CDR1、 MDR1、MRR1基因表达水平均显著高于敏感组（P<0.05）。牛源近平滑念珠菌对唑类抗真菌药物的耐药率较高且具有多重耐药性。牛源近平滑念珠菌ERG11基因中的T591C突变以及ERG11、CDR1、MDR1、MRR1基因的高表达都可能在其对氟康唑耐药性的产生中起到一定的作用。     

Analysis of gyrA mutations in quinolone-resistant and -susceptible Campylobacter jejuni isolates from retail poultry and human clinical isolates by non-radioactive single-strand conformation polymorphism analysis and DNA sequencing

AIMS: The aims of this study were to characterize the molecular variations in the quinolone resistance-determining region (QRDR) of gyrA among quinolone-resistant and -susceptible Campylobacter jejuni isolates originating from foods of animal origin and human infections and to evaluate the suitability of the single-strand conformation polymorphism (SSCP) method as a screening method for molecular characterization of fluoroquinolone resistance. METHODS AND RESULTS: Alterations in QRDR of gyrA from 182 C. jejuni isolates were determined by nonradioisotopic SSCP analysis and direct sequencing. A total of 13 types of nucleic acid sequence combinations within the QRDR of the gyrA gene resulted in 11 different SSCP patterns. All nalidixic acid resistant strains possessed nucleotide substitution at either codon Thr-86 or Asp-90. Silent mutations were detected additionally. Thr-86 to Ile mutation was detected in all 139 ciprofloxacin resistant strains, which showed cross-resistance to nalidixic acid. CONCLUSIONS: The SSCP method is suitable for a molecular screening of quinolone resistant C. jejuni isolates and in combination with DNA sequencing suitable to detect genetic variations of the QRDR of gyrA. SIGNIFICANCE AND IMPACT OF STUDY: This study provides data of the genetic variations of the QRDR of gyrA from C. jejuni isolates of foods and human beings.     

The genetic basis of fluconazole resistance development in Candida albicans

Infections by the opportunistic fungal pathogen Candida albicans are widely treated with the antifungal agent fluconazole that inhibits the biosynthesis of ergosterol, the major sterol in the fungal plasma membrane. The emergence of fluconazole-resistant C. albicans strains is a significant problem after long-term treatment of recurrent oropharyngeal candidiasis (OPC) in acquired immunodeficiency syndrome (AIDS) patients. Resistance can be caused by alterations in sterol biosynthesis, by mutations in the drug target enzyme, sterol 14alpha-demethylase (14DM), which lower its affinity for fluconazole, by increased expression of the ERG11 gene encoding 14DM, or by overexpression of genes coding for membrane transport proteins of the ABC transporter (CDR1/CDR2) or the major facilitator (MDR1) superfamilies. Different mechanisms are frequently combined to result in a stepwise development of fluconazole resistance over time. The MDR1 gene is not or barely transcribed during growth in vitro in fluconazole-susceptible C. albicans strains, but overexpressed in many fluconazole-resistant clinical isolates, resulting in reduced intracellular fluconazole accumulation. The activation of the gene in resistant isolates is caused by mutations in as yet unknown trans-regulatory factors, and the resulting constitutive high level of MDR1 expression causes resistance to other toxic compounds in addition to fluconazole. Disruption of both alleles of the MDR1 gene in resistant C. albicans isolates abolishes their resistance to these drugs, providing genetic evidence that MDR1 mediates multidrug resistance in C. albicans.     

应用4种方法检测结核分枝杆菌临床分离株对链霉素的耐受性

通过DNA测序、SSCP、RFLP和反向斑点杂交技术分析167株结核分枝杆菌临床分离株的耐药基因型,评价结核分枝杆菌rpsL或rrs基因突变与链霉素（SM）耐受性之间的关系,比较4种分子方法检测SM耐受性的临床价值。98株耐SM分离株中,78株（79．6％）rpsL 43位或88位密码子错义突变导致赖氨酸置换为精氨酸,6株（6．1％）rrs 513位碱基A突变为C或T或516位C突变为T,14株（14．3％）未发现突变;69株SM敏感的分离株未发现这两个基因突变。应用SSCP、RFLP和RDBH方法分析上述突变和野生序列的结果与DNA测序完全一致,RDBH方法可从98株耐SM分离株中正确鉴定出84株（85．7％）分离株的5种突变基因型。结果表明,应用分子技术分析rpsL和rrs基因突变可快速检测大多数结核分枝杆菌对SM的耐受性,反向斑点杂交方法是一个快速、简便和可靠地检测药物耐受性的分子方法。     

Ibuprofen reverts antifungal resistance on Candida albicans showing overexpression of CDR genes

Several mechanisms may be associated with Candida albicans resistance to azoles. Ibuprofen was described as being able to revert resistance related to efflux activity in Candida . The aim of this study was to uncover the molecular base of antifungal resistance in C. albicans clinical strains that could be reverted by ibuprofen. Sixty-two clinical isolates and five control strains of C. albicans were studied: the azole susceptibility phenotype was determined according to the Clinical Laboratory for Standards Institute, M27-A2 protocol and minimal inhibitory concentration values were recalculated with ibuprofen (100 μg mL⁻¹); synergistic studies between fluconazole and FK506, a Cdr1p inhibitor, were performed using an agar disk diffusion assay and were compared with ibuprofen results. Gene expression was quantified by real-time PCR, with and without ibuprofen, regarding CDR1 , CDR2 , MDR1 , encoding for efflux pumps, and ERG11 , encoding for azole target protein. A correlation between susceptibility phenotype and resistance gene expression profiles was determined. Ibuprofen and FK506 showed a clear synergistic effect when combined with fluconazole. Resistant isolates reverting to susceptible after incubation with ibuprofen showed CDR1 and CDR2 overexpression especially of the latter. Conversely, strains that did not revert displayed a remarkable increase in ERG11 expression along with CDR genes. Ibuprofen did not alter resistance gene expression significantly ( P >0.05), probably acting as a Cdrp blocker.     

近平滑念珠菌ERG 11基因编码区的克隆及生物信息学分析

目的克隆、测序近平滑念珠菌ERG11基因的编码区序列并进行生物信息学分析。方法运用生物信息学的方法 ,通过与白念珠菌ERG11基因碱基序列同源性比对,在近平滑念珠菌基因组(www.sanger.ac.uk/sequencing/Candida/pa-rapsilosis/)中寻找可能的ERG11基因序列(CpERG11),并据此序列设计引物,经PCR扩增近平滑念珠菌标准株(ATCC22019)的ERG11基因片段,产物经电泳、纯化、克隆到质粒prG-AMAI-NotI中,转染DH10B大肠杆菌细胞,并酶切鉴定筛选阳性克隆测序分析。结果近平滑念珠菌ERG11编码区由1569个碱基组成,编码一段含522个氨基酸的多肽。近平滑念珠菌ERG11的编码区序列与白念珠菌、热带念珠菌、光滑念珠菌、酿酒酵母菌ERG11基因的同源性分别为74%、75%、65%、64%。该近平滑念珠菌ERG11的编码区为唑类药物作用靶酶基因。结论成功克隆、测序、并生物信息学分析近平滑念珠菌ERG11基因的编码区序列,为进一步的功能研究奠定基础。     

Evaluation of the V404I and V509M amino acid substitutions of <Emphasis Type="Italic">ERG11</Emphasis> gene in <Emphasis Type="Italic">Candida albicans</Emphasis> isolates by pyrosequencing

The molecular mechanisms underlying fluconazole resistance in C. albicans involve mutations and the overexpression of the ERG11 gene and membrane transport proteins. We examined the relationship between the reduced fluconazole susceptibility of C. albicans and mutations of V404I and V509M in the ERG11 gene in 182 C. albicans clinical isolates using the Pyrosequencing™ method. DNAs from these clinical isolates with different levels of in-vitro fluconazole susceptibility — one resistant, five susceptible dose-dependent (SDD), four trailer, and 172 susceptible — were analyzed. None of the fluconazole-susceptible, SDD, trailer or resistant isolates had mutations of V404I or V509M. Our results showed that no correlation can be found between the V404I or V509M mutation and fluconazole susceptibility in C. albicans.     

Detection of Streptomycin Resistance in Mycobacterium tuberculosis Clinical Isolates Using Four Molecular Methods in China

To evaluate the relationship between mutations in rpsL or rrs genes and streptomycin (SM) resistance, we compared four molecular methods for their clinical value in the detection of SM resistance. Genotypic analysis of SM resistance in 167 M. tuberculosis clinical strains isolated from Chinese patients was performed by direct DNA sequencing, SSCP, RFLP, and reverse dot-blot hybridization (RDBH) assays. Of the 98 SM-resistant isolates, 78 (79.6%) had missense mutations in codon 43 or 88 of rpsL resulting in a Lys to Arg substitution, 6 (6.1%) had mutations of the rrs gene at positions 513 A to C or T or 516 C to T, and 14 (14.3%) had the wild-type sequence. None of the 69 SM-susceptible isolates examined had alterations in rpsL or rrs. The results of the SSCP, RFLP, and RDBH analyses for these mutations and wild-type sequences were completely consistent with DNA sequencing data. Five distinct single-nucleotide substitutions in codon 43 or 88 of rpsL gene or in position 513 or 516 of rrs gene were correctly identified in 84 of 98 (85.7%) phenotypically SM-resistant isolates by RDBH assay. Molecular analyses of the rpsL and rrs genes are useful for rapid prediction of SM resistance in most clinical strains of M. tuberculosis. Reverse dot-blot hybridization assay is a rapid, simple, and reliable method for the detection of drug resistance.     

Pathogenicity and drug resistance in Candida albicans and other yeast species. A review

Pathogenic yeasts from the genus Candida can cause serious infection in humans particularly, in immunocompromised patients and are now recognized as major agents of hospital acquired (nosocomial) infections. In the recent years, there has been a marked increase in the incidence of treatment failures in candidiasis patients receiving long-term antifungal therapy, which has posed a serious problem in its successful use in chemotherapy. Candida cells acquire drug resistance (MDR) during the course of the treatment. The mechanisms of resistance to azole antifungal agents have been elucidated in Candida species and can be mainly categorized as (i) changes in the cell wall or plasma membrane, which lead to impaired drug (azole) uptake; (ii) alterations in the affinity of the drug target Erg11p (lanosterol 14alpha-demethylase) especially to azoles or in the cellular content of Erg11p due to target site mutation or overexpression of the ERG11 gene; and (iii) the efflux of drugs mediated by membrane transport proteins belonging to the ATP-binding cassette (ABC) transporters, namely CDR1 and CDR2 or to the major facilitator superfamily (MFS) transporter, CaMDR1. Many such manifestations are associated with the formation of Candida biofilms including those occurring on devices like indwelling intravascular catheters. Biofilm-associated Candida show uniform resistance to a wide spectrum of antifungal drugs. A combination of different resistance mechanisms is responsible for drug resistance in clinical isolates of Candida species.     

Identification of a rare point mutation at C-terminus of merozoite surface antigen-1 gene of Plasmodium falciparum in eastern Indian isolates

Merozoite surface antigen-1 (MSA-1) of Plasmodium falciparum is highly immunogenic in human. Several studies suggest that MSA-1 protein is an effective target for a protective immune response. Attempt has been made to find new point mutations by analyzing 244 bp [codon 1655(R) to 1735 (I)] relatively conserved C-terminus region of MSA-1 gene in 125 isolates. This region contains two EGF like domains, which are involved in generating protective immune response in human. Point mutations in this region are very much important in view of vaccine development. Searching of mutational hot spots in MSA-1 protein by sequencing method in a representative number of isolates is quite critical and expensive. Therefore, in this study slot blot and PCR-SSCP method have been used to find out new mutations in the individual isolates showing alterations in the mobility of DNA fragment. Sequencing of the altered bands from the SSCP gel shows a rare non-synonymous point mutation in 7 (5.6%) of the 125 isolates at amino acid position 1704 of MSA-1 gene where isoleucine is replaced by valine.     

Application of SSCP-PCR fingerprinting to profile the yeast community in raw milk Salers cheeses

Bacteria and yeasts are important sensory factors of raw-milk cheeses as they contribute to the sensory richness and diversity of these products. The diversity and succession of yeast populations in three traditional Registered Designation of Origin (R.D.O.) Salers cheeses have been determined by using phenotypic diagnoses and Single-Strand Conformation Polymorphism (SSCP) analysis. Isolates were identified by phenotypic tests and the sequencing of the D1-D2 domains of the 26S rRNA gene. Ninety-two percent of the isolates were identified as the same species in both tests. Yeast-specific primers were designed to amplify the V4 region of the 18S rRNA gene for SSCP analysis. The yeast species most frequently encountered in the three cheeses were Kluyveromyces lactis, Kluyveromyces marxianus, Saccharomyces cerevisiae, Candida zeylanoides and Debaryomyces hansenii. Detection of less common species, including Candida parapsilosis, Candida silvae, Candida intermedia, Candida rugosa, Saccharomyces unisporus, and Pichia guilliermondii was more efficient with the conventional method. SSCP analysis was accurate and could be used to rapidly assess the proportions and dynamics of the various species during cheese ripening. Each cheese was clearly distinguished by its own microbial community dynamics.     

Resistance of human fungal pathogens to antifungal drugs

Resistance mechanisms can be engaged in clinically relevant fungal pathogens under different conditions when exposed to antifungal drugs. Over past years, active research was undertaken in the understanding of the molecular basis of antifungal drug resistance in these pathogens, and especially against the class of azole antifungals. The isolation of various alleles of the gene encoding the target of azoles has enabled correlation of the appearance of resistance with distinct mutations. Resistance mechanisms to azoles also converge to the upregulation of multidrug transporter genes, whose products have the capacity to extrude from cells several chemically unrelated antifungal agents and toxic compounds. Genome-wide studies of azole-resistant isolates are now permitting a more comprehensive analysis of the impact of resistance on gene expression, and may deliver new clues to their mechanisms. Several laboratories are also exploring, as well as possible alternative resistance pathways, the role of biofilm formation by several fungal species in the development of resistance to various antifungals, including azoles.