Figures
Abstract
An increasing trend in non albicans infections and various susceptibility patterns to antifungal agents implies a requirement for the quick and reliable identification of a number of medically important Candida species. Real-time PCR followed by high resolution melting analysis (HRMA) was developed, tested on 25 reference Candida collection strains and validated on an additional 143 clinical isolates in this study. All reference strains and clinical isolates inconclusive when using phenotypic methods and/or HRMA were analysed using ITS2 sequencing. Considering reference and clinical strains together, 23 out of 27 Candida species could be clearly distinguished by HRMA, while the remaining 4 species were grouped in 2 pairs, when applying the mean Tm ± 3 SD values, the shape of the derivative melting curve (dMelt curve) and, in some cases, the normalized and temperature—shifted difference plot against C. krusei. HRMA as a simple, rapid and inexpensive tool was shown to be useful in identifying a wide spectrum of clinically important Candida species. It may complement the current clinical diagnostic approach based on commercially available biochemical kits.
Citation: Nemcova E, Cernochova M, Ruzicka F, Malisova B, Freiberger T, Nemec P (2015) Rapid Identification of Medically Important Candida Isolates Using High Resolution Melting Analysis. PLoS ONE 10(2): e0116940. https://doi.org/10.1371/journal.pone.0116940
Academic Editor: Alix Therese Coste, Institute of Microbiology, SWITZERLAND
Received: September 18, 2014; Accepted: December 17, 2014; Published: February 17, 2015
Copyright: © 2015 Nemcova et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are within the paper.
Funding: The study was supported by the European Regional Development Fund—Project FNUSA-ICRC (No. CZ.1.05/1.1.00/02.0123) and by the grant CKTCH Brno No. 201211. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Candidiasis is a dominant fungal infection worldwide and candidemia represents the fourth most common bloodstream infection in hospitalized patients in the United States [1,2] and the seventh in Europe [3,4]. Although Candida albicans remains the most common fungal isolate from blood, many studies have reported an increasing trend in non-albicans infections [5–9]. Horn et al. (2009) [10] described an even higher incidence of candidemia caused by non-albicans Candida species than C. albicans in the United States.
The correct and quick identification of Candida species is very important, particularly for providing adequate antifungal therapy based on species-dependent susceptibility patterns [11], but also for epidemiological purposes [12]. Candidiasis diagnosis is based on microscopy, histopathology, culture and chromogenic culture media, as well as enzyme, metabolite, Candida cell wall structural component (1,3-β-D-glucan) and antibody (antimannan) or antigen (mannan) detection [12,13].
Molecular techniques are not recommended for diagnosing candidiasis in clinical practise because of insufficient data and lack of standardization [13]. However, many applications relying mainly on PCR have been developed to detect candidal DNA and may be useful in specific situations. Further species identification was carried out using restriction fragment length polymorphism (RFLP) [14,15], sequencing [16–18], pyrosequencing [19–21], real-time PCR with specific probes [22–26] or real-time PCR with species specific or pan-fungal primers [27–29]. Other authors applied semi-nested PCR [30], multiplex tandem PCR [31], single-strand conformation polymorphism (SSCP) [32], peptide nucleic acid fluorescent in situ hybridization (PNA FISH) [33], matrix-assisted laser desorption/ionization (MALDI-TOF) [34–36], nucleic acid sequence based amplification (NASBA) [37] or PCR coupled to electrospray ionization mass spectrometry (PCR/ESI-MS) [38]. Unfortunately, these approaches are either expensive, laborious, not proven to differentiate multiple Candida species simultaneously or lack verified comprehensive databases containing uncommon/emerging species.
Another strategy is based on high resolution melting analysis (HRMA), which can be used for species identification although it was developed originally for genotyping, mutation scanning and sequence matching [39]. This method has already been applied in bacteriology [40–43], virology [44,45] and mycology [46–54]. In this study we report a method combining broad-range real-time PCR and HRMA for the rapid identification of 25 medically important Candida species from culture, verified on clinical isolates.
Material and Methods
Fungal strains
Twenty five medically important Candida reference strains (Table 1) were selected from the Belgian Co-ordinated Collections of Micro-organisms (BCCM/MUCL), the Czech Collection of Microorganisms (CCM) and the Culture Collection of Yeasts (CCY): C. albicans (CCM 8320), C. catenulata (CCY 29-17-3), C. dubliniensis (CCY 29-177-1), C. fabianii (CCY 38-20-1), C. famata (CCY 26-9-9), C. glabrata (CCM 8270), C. guilliermondii (CCY 39-23-6), C. inconspicua (CCY 26-26-11), C. intermedia (CCY 29-12-10), Kluyveromyces marxianus (C. kefyr) (MUCL 29857), C. krusei (CCY 29-9-17), C. lambica (CCY 29-97-12), C. lipolytica (CCY 29-26-42), C. lusitaniae (CCY 29-59-1), C. metapsilosis (MUCL 46179), C. norvegensis (CCY 29-47-2), C. orthopsilosis (MUCL 49939), C. parapsilosis (CCM 8260), C. pelliculosa (CCY 29-6-7), C. pulcherrima (CCY 29-2-128), C. rugosa (CCY 29-15-1), C. tropicalis (CCM 8264), C. utilis (CCY 29-38-74), C. valida (CCY 29-93-4), C. zeylanoides (MUCL 27735) for the analysis.
In addition, 143 available Candida isolates phenotypically corresponding to selected reference strains, cultured from different clinical specimens, were included in the study.
DNA extraction
Pure cultures of all Candida reference strains and clinical isolates were homogenized in 100 μl of sterile water (B. Braun Medical, Inc., Germany) and incubated with lysis buffer (EDTA, Tris, Triton X-100), lysozyme (Sigma-Aldrich, USA) and lyticase (Sigma-Aldrich, USA) for 60 min at 37°C to disrupt the fungal cell wall. The DNA was isolated by using the fungal DNA isolation protocol with QIAamp DNA Blood Mini Kit (Qiagen, Germany). DNA purity and concentrations were measured using NanoDrop ND-1000 spectrophotometer (NanoDrop Technologies, Inc., North Carolina, USA).
Confirmation of strains
Extracted fungal DNA was used for PCR targeting the ITS2 region (primers UNF1 and UNF2 published previously [14] and run under the following conditions: 10 min at 96°C, then 45 cycles of 10 s at 98°C, 10 s at 56°C, 30 s at 72°C and a final step of 4 min at 72°C. Purified amplicons were subjected to cycle sequencing using a Big Dye Terminator 3.1 Cycle Sequencing Kit (Life Technologies, California, USA) and sequenced on ABI Prism 3100 Avant (Life Technologies). The sequences were put to alignment analysis using the BLAST tool of the National Centre for Biotechnology Information (NCBI) (http://www.ncbi.nlm.nih.gov/blast, accessed Dec 2013) [55] and to the pairwise sequence alignment tool of the Fungal Biodiversity Centre database (http://www.cbs.knaw.nl/Collections/BioloMICSSequences.aspx?file=all, accessed Dec 2013) [56] (Table 1).
All clinical isolates were tested using conventional biochemical methods, API-ID32C (BioMérieux, France) and CANDIDAtest 21 (Erba-Lachema, Czech Republic). C. dubliniensis was identified using the Bichro-Dubli Fumouze additional latex agglutination test (Fumouze Diagnostics, France). Clinical isolate sequencing was only carried out in cases when the HRMA pattern did not correspond with any reference strain, some inconsistencies in HRMA pattern were noted, phenotypic and HRMA testing differed in species determination or the phenotype was not determined unambiguously. MEGA4 software [57] was used for C. metapsilosis reference and clinical strain sequence alignment. Reference strains GC content (%) was determined using uMELT software v2.0.2 [58] (Table 1).
PCR conditions and HRMA
Real-time PCR amplification and HRMA of the ITS2 region were performed on the Rotor-Gene 6000 (Corbett Research, Austria) with primers UNF1 and UNF2, the same as were used for sequencing. PCR was carried out with 1 × SensiMix HRM (Quantace, United Kingdom), 20 ng of fungal DNA, 3.5 mmol/l MgCl2 (Fermentas UAB, Lithuania), 1.5 × saturating dye EvaGreen (Biotium, USA), 0.35 μmol/l of each primer (final concentration) and sterile water up to 25 μl (B. Braun Medical, Germany). The PCR program consisted of an initial denaturation of 10 min at 95°C, followed by 40 cycles of 10 s at 95°C, 15 s at 58°C and 30 s at 72°C, and ended with 4 min at 72°C. The amplification products for HRMA (229–422 bp long with GC content 39–58%) were cooled 1 min at 50°C and then heated from 70°C to 98°C monitoring fluorescence at the rate of 0.15°C/2 s. Melting data were normalised and the temperature shifted using Rotor-Gene 6000 analysis software version 1.7 (Corbett Research, Austria). Normalisation regions for HRMA were set at 71–73°C and 95–97°C. All reference strains were analysed in duplicates in 3 independent runs and the mean Tm and SD values were calculated for each melting domain. Different Tm value ranges were tested and finally the mean Tm ± 3 SD range was selected to overcome the interassay variability and reach maximum sensitivity and reproducibility. Then, randomly determined numbers of isolates (21 to 33) were tested per each HRMA run. Each clinical strain was evaluated by comparing its Tm value(s) with established reference intervals of mean Tm ± 3 SD and by simple visual inspection of its derivative melting curve shape (dMelt curve shape). If this approach did not result in unambiguous identification, a difference plot of analysed species against C. krusei was performed. Three positive controls were used in each assay (C. krusei, C. norvegensis, C. saitoana).
Results
Sequencing of reference strains
All reference strains except CCY 26-9-9 and CCY 29-93-4 were validated as those supplied by culture collections by ITS2 sequencing and alignment analysis (Table 1). Reference strains signed as C. famata (CCY 26-9-9) and C. valida (CCY 29-93-4) were re-identified as C. saitoana and C. californica respectively, using ITS2 sequencing.
HRMA in reference strains
Real-time PCR followed by HRMA, performed with 25 Candida reference strains, showed reproducible melting peaks for each species. Most of them displayed a single peak, whereas nine Candida species melted in two domains (Table 1, Figs. 1, 2).
1) C. zeylanoides, 2) C. saitoana, 3) C. utilis, 4) C. fabianii, 5) C. guilliermondii, 6) C. glabrata, 7) C. intermedia, 8) C. pulcherrima, 9) C. kefyr, 10) C. lusitaniae, 11) C. rugosa, 12) C. inconspicua, 13) C. californica, 14) C. krusei, 15) C. norvegensis, 16) C. lambica
Scale different from Fig. 1: 1) C. pelliculosa, 2) C. tropicalis, 3) C. metapsilosis, 4) C. orthopsilosis, 5) C. parapsilosis, 6) C. lipolytica, 7) C. dubliniensis, 8) C. albicans, 9) C. catenulata
Unique patterns were identified in 21 out of 25 Candida species directly after melting curve analysis, including C. saitoana and C. californica instead of C. famata and C. valida, respectively. The mean Tm ± 3 SD value(s) together with the dMelt curve shape were conclusive in 16 species, while normalized temperature-shifted difference plot against C. krusei had to be used to distinguish between two species in the other 5 reference strains (three couples), C. inconspicua vs. C. californica, C. krusei vs. C. norvegensis, and C. utilis vs. C. fabianii (Fig. 3), the latter, however, could not be distinguished from C. guilermondii (see below).
A) Tm ± 3 SD reference strains values, B) shapes of the selected reference strains dMelt curves, C) normalized and temperature–shifted difference plot of the reference strains against C. krusei. PK–positive control used in each HRMA run.
Four species (two pairs) could not be reliably distinguished. Tm ± 3SD values for C. orthopsilosis and C. metapsilosis occurred repeatedly in clearly overlapping ranges, and similarly, the reference strains of C. fabianii and C. guilliermondii, despite very different sequences, had significantly overlapping margins of Tm ± 3SD ranges. Neither the curve shape nor plotting had any additional value in these cases. Nevertheless, both C. orthopsilosis and C. metapsilosis were clearly distinguishable from C. parapsilosis.
The sensitivity of the assay was determined by serially diluted C. albicans reference strain DNA in duplicates. Concentrations of 50 ng–1 pg provided reliable HRMA patterns.
HRMA in clinical isolates
All clinical isolates (n = 143) were tested in a blinded manner. When the HRMA pattern of a particular clinical isolate was different from the melting data in a reference panel, the isolate was sequenced to clarify an observed discrepancy. Eleven samples showing mixed electropherogram were excluded from the primary analysis. An additional seven clinical isolates representing 2 species could not be identified, because they were not included in the reference list (three C. pararugosa and four C. famata samples) (Table 2, bottom). However, all of these 7 samples revealed a reliable pattern, either directly (C. pararugosa) or after being plotted against C. krusei (C. famata), and could be differentiated from every other species. Thus, 125 clinical isolates (21 species) finally corresponded to the set of reference strains (Table 2, top).
Eighty-two of them (65.6%), representing 16 species (76.2%), were identified correctly to species level using either Tm ± 3 SD ranges calculated from the corresponding reference strains only or in connection with the dMelt curve shape. Despite overlapping Tm ± 3 SD ranges in the reference strains in pairs of C. utilis/C. fabianii, C. inconspicua/C. californica and C. krusei/C. norvegensis, no plotting against C. krusei was needed in clinical isolates of these species, because their Tm values did not fall into these overlapping areas. Sequencing revealed some species heterogeneities in C. albicans (differed by 1 bp from the reference sequence in 4/13 isolates), C. norvegensis (3 bp in 4/4), C. intermedia (1 bp in 1/1) and C. lipolytica (1 bp in 1/3). However, the correct species identification was affected in none of these cases.
The other 38 isolates (30.4%), representing 4 species (19.0%), were ranged properly, but could not decide between two species (C. fabianii/C. guilliermondii in 26 and C. orthopsilosis/C. metapsilosis in 12 cases). Sequence variants in 1 bp detected by sequencing in 6/6 C. guillermondii and 4/9 C. metapsilosis, compared to the corresponding reference strains, did not affect the result.
Five clinical isolates (4.0%), belonging to the two species (9.5%), could not be identified at all (C. lambica in 3/3 and C. metapsilosis in 2/9 cases). In these isolates, variations in 4 bp and 1 bp respectively, compared to reference strains, were demonstrated, which shifted the Tm value out of the Tm ± 3 SD range calculated for the respective reference strains and identification failed. All of these 5 strains showed a unique pattern and could not be misidentified with any other clinical or reference strain included in our panel. Thus, two different heterogeneities differing by 1 bp from the reference strain were identified in C. metapsilosis clinical isolates (Fig. 4). While a difference in position 218 of the amplicon did not affect the Tm and the dMelt curve shape significantly, another difference in position 141 resulted in three-peak pattern and disabled the identification.
(amplicon position 141 bp and 218 bp highlighted)
In 2 out of 11 samples showing poly-fungal pattern on electropherogram, species identification was not possible at all. However, in the remaining 9 isolates the dMelt curve showed only a small deviation from the respective reference curve and the major species could be identified correctly and corresponded to phenotypic identification. Notably, the phenotypic approach failed to identify a minor strain in all these cases.
Phenotypic methods in clinical isolates
Based on phenotypic methods, all 5 C. orthopsilosis and 9 C. metapsilosis isolates were misidentified as C. parapsilosis, and 20 C. fabianii isolates were misidentified as C. utilis/C. pelliculosa. In an additional 4 isolates, C. pelliculosa and C. utilis could not be distinguished from each other. Three clinical isolates delivered to our lab as C. rugosa were finally determined using sequencing as C. pararugosa. All other clinical strains were identified correctly (Table 2).
Discussion
In this study, we combined traditional culture with real-time PCR and HRMA for rapid identification of Candida pathogens. A newly developed HRMA was optimized and tested on 25 reference collection strains, of which 21 were distinguished unambiguously. Using this method, 143 phenotypically defined clinical isolates were tested in a blinded manner and melting data, particularly the mean Tm ± 3 SD and the dMelt curve shape, were compared to the reference panel. Evaluating all clinical isolates, the samples were identified correctly in 18 out of 23 species supplied (Table 2). In addition, the clinical isolates of another species (C. lambica) were distinguished, although the identification failed due to sequence differences from the reference strain. All four species unavailable as clinical isolates, C. californica, C. saitoana, C. rugosa and C. zeylanoides, were clearly distinguishable when applying for collection strains.
Considering the reference and clinical strains together, 23 out of 27 Candida species were distinguished, while the remaining 4 species were grouped in 2 pairs, using HRMA in this study. To our knowledge, this is the widest spectrum of Candida species tested and distinguished using the HRMA method so far, with the large number of 143 clinical isolates covering 23 species used for validation. Three Candida species were used as positive controls in each run. Mandviwala et al. (2010) [49] differentiated 8 Candida species based on ITS1 and ITS2 sequences, when using a relatively demanding analysis in MS Excel. Arancia et al. (2011) [50] developed a procedure to identify 5 Candida sp. using MP65 gene with analysis made only following normalized and derivated melting curve shapes. Goldschmidt et al. (2012) [52] reported the HRMA approach based on 18S rDNA sequence to distinguish 5 Candida sp. simultaneously with 6 filamentous fungi, which were however necessary for further analysis (plotting) and the identification of Candida sp. Somogyvari et al. (2012) [51] differentiated 10 Candida sp. analysing the HRMA of the ITS2 sequence, but all expected species had to be used as positive controls in each run to get reliable results. Decat et al. (2013) [53] described an approach enabling the identification of 17 Candida sp. and one other pair based on the ITS2 sequence, using 5 positive controls in each run and two plotting schemes to interpret data. Alnuaimi et al. (2014) [54] used HRMA to distinguish 9 Candida sp. based on ITS1, 5.8S and ITS2 sequences, having 8 species as positive controls in each run. Despite HRMA performing well in this study, unequivocal identification could not be carried out in 4 reference strains (C. orthopsilosis vs. C. metapsilosis, C. fabianii vs. C. guillermondii) and 5 clinical isolates (C. orthopsilosis vs. C. metapsilosis, C. fabianii vs. C. guillermondii, C. lambica). Tm ± 3SD values for both reference and clinical isolates of C. orthopsilosis and C. metapsilosis occurred repeatedly in overlapping ranges, therefore these two species were subsumed into one undistinguishable group. However, routine discrimination within this group is not considered to be necessary and even commercial biochemical tests do not differentiate among species in the C. parapsilosis complex [59]. On the other hand, distinguishing C. orthopsilosis/C. metapsilosis from C. parapsilosis might be of importance, as variations in antifungal susceptibility with C. orthopsilosis and C. metapsilosis being more susceptible to antifungals than C. parapsilosis have been described [60]. Notably, all C. parapsilosis clinical isolates representing the medically most important organism in the *psilosis group were clearly distinguishable from C. orthopsilosis/C. metapsilosis strains using HRMA.
Interestingly, C. metapsilosis clinical isolates revealed three different types of heterogeneities (Fig. 4), two variants did not affect the correct species group ranging, but the other one caused three melting peaks instead of two in the Tm curve shape which prevented correct identification, although the HRMA pattern could not be confused with the curve of any other species tested. Similarly, the HRMA data of all 3 clinical isolates of C. lambica failed to match with the corresponding reference strain pattern, as they all differed by the same 4 nucleotides. Although the identification of clinical samples of C. lambica, could not be completed, all of them showed a unique curve avoiding confusion with any other species. HRMA is a sensitive method capable of discriminating sequences with minimal variations, which on the other hand can hamper correct pathogen identification at species level in cases of intraspecies variability. Nevertheless, this limitation may even become an advantage when using HRMA in typing clinical isolates for epidemiological reasons [54].
Despite very different sequences of C. fabianii and C. guilliermondii, HRMA could not differentiate between them, as their Tm ± 3SD ranges significantly overlapped, most likely due to the identical GC content both in reference and clinical isolate sequences. Using phenotypic determination, C. guilliermondii can be recognized unambiguously between these two species. Although not occurring in our clinical samples, biochemical identification can misidentify C. guilliermondii as C. famata (D. hansenii) [61] which, on the contrary, can reliably be distinguished using HRMA (as we demonstrated on clinical strains). Thus, combining both approaches all three species could be decidedly identified. In addition, the phenotypic differentiation of C. fabianii, C. pelliculosa and C. utilis is not easy since all have a similar pattern and could be mutually misidentified [62], which ultimately happened in our clinical samples. C. fabianii is included neither in CandidaTest 21, nor in API-ID32C although it is able to form biofilm and cause severe infections [62,63]. All C. pelliculosa, C. utilis and C. fabianii isolates were convincingly distinguishable using HRMA in our testing.
C. albicans and C. dubliniensis differentiation is usually based on biochemical tests exhibiting the ability of C. dubliniensis not to assimilate D-xylosis (XYL), methyl-α-D-glucoside (MDG) and D-trehalose (TRE), but neither these tests nor tests based on pseudohyphal and hyphal formation on special culture media, e.g. Staib agar [64] and chlamydospore production give unambiguous results [65,66]. The additional use of the Bichro-Dubli Fumouze latex-agglutination test enables reliable identification [67], as we demonstrated in our set of clinical isolates, and similarly HRMA had characteristic dMelt curves for both species.
Sequencing showed poly-fungal pattern with a prevalent sequence corresponding to the species identified by HRMA in nine clinical isolates, while phenotypic analysis reported them as a single species. A minority strain in these poly-fungal samples slightly affected the shape of the dMelt curve but did not compromise the identification of the prevailing strain. HRMA also detected two poly-fungal isolates, which could not be specified.
Several of HRMA’s other superiorities over routinely used Candida identification methods were shown in our study. Unlike HRMA, API-ID32C (including 34 Candida species except C. pararugosa) is not able to distinguish C. norvegensis and C. inconspicua, CANDIDAtest 21 does not include either C. pulcherrima or C. zeylanoides among 24 Candida species and, moreover, it is not able to differentiate C. rugosa and C. pararugosa. Even pyrosequencing failed to identify C. pararugosa, C. lambica and C. lipolytica [19,20] which could be clearly distinguished using HRMA.
Real-time PCR followed by HRMA is a simple, efficient and rapid method of identifying cultured Candida sp. our time to result after culture positivity was 6 hours compared to 24–48 hours required for the biochemical methods used in this study. This approach might be useful even to identify Candida sp. directly from biological samples, as has already been demonstrated by others [49,50,52]. Applying our HRMA directly to clinical samples would lead to further reducing the time to result, but additional studies are needed to validate this method for such a setting. However, this assay can be useful to complement current clinical diagnostic methods for Candida isolates, mainly when phenotypically similar Candida species or those not included in the biochemical tests are suspected.
Acknowledgments
The authors would like to acknowledge Lenka Suchankova-Krupkova for technical support.
Author Contributions
Conceived and designed the experiments: TF PN. Performed the experiments: EN MC FR BM. Analyzed the data: EN FR TF. Contributed reagents/materials/analysis tools: FR. Wrote the paper: EN TF.
References
- 1.
Wisplinghoff H, Bischoff T, Tallent M, Seifert H, Wenzel R, et al. (2004) Nosocomial bloodstream infections in US hospitals: analysis of 24,179 cases from a prospective nationwide surveillance study. Clin Infect Dis: 1093–1093.
- 2. Pfaller MA, Diekema DJ (2007) Epidemiology of invasive candidiasis: a persistent public health problem. Clin Microbiol Rev 20: 133–163. pmid:17223626
- 3.
Marchetti O, Bille J, Fluckiger U, Eggimann P, Ruef C, et al. (2004) Epidemiology of candidemia in Swiss tertiary care hospitals: Secular trends, 1991–2000. Clin Infect Dis: 311–320.
- 4.
Tortorano A, Peman J, Bernhardt H, Klingspor L, Kibbler C, et al. (2004) Epidemiology of candidaemia in Europe: Results of 28-month European Confederation of Medical Mycology (ECMM) hospital-based surveillance study. Eur J Clin MicrobiolInfect Dis: 317–322.
- 5.
Krcmery V, Barnes A (2002) Non-albicans Candida spp. causing fungaemia: pathogenicity and antifungal resistance. J Hosp Infect: 243–260.
- 6. Pfaller MA, Diekema DJ (2002) Role of sentinel surveillance of candidemia: trends in species distribution and antifungal susceptibility. J Clin Microbiol 40: 3551–3557. pmid:12354845
- 7. Martin D, Persat F, Piens MA, Picot S (2005) Candida species distribution in bloodstream cultures in Lyon, France, 1998–2001. Eur J Clin Microbiol Infect Dis 24: 329–333. pmid:15856138
- 8. Hachem R, Hanna H, Kontoyiannis D, Jiang Y, Raad I (2008) The changing epidemiology of invasive Candidiasis–Candida glabrata and Candida krusei as the leading causes of candidemia in hematologic malignancy. Cancer 112: 2493–2499. pmid:18412153
- 9.
Leroy O, Gangneux J, Montravers P, Mira J, Gouin F, et al. (2009) Epidemiology, management, and risk factors for death of invasive Candida infections in critical care: A multicenter, prospective, observational study in France (2005–2006). Crit Care Med: 1612–1618.
- 10. Horn DL, Neofytos D, Anaissie EJ, Fishman JA, Steinbach WJ, et al. (2009) Epidemiology and outcomes of candidemia in 2019 patients: data from the prospective antifungal therapy alliance registry. Clin Infect Dis 48: 1695–1703. pmid:19441981
- 11.
Pappas P, Rex J, Sobel J, Filler S, Dismukes W, et al. (2004) Guidelines for treatment of candidiasis. Clin Infect Dis: 161–189.
- 12.
Ellepola A, Morrison C (2005) Laboratory diagnosis of invasive candidiasis. J Microbiol: 65–84.
- 13. Cuenca-Estrella M, Verweij PE, Arendrup MC, Arikan-Akdagli S, Bille J, et al. (2012) ESCMID* guideline for the diagnosis and management of Candida diseases 2012: diagnostic procedures. Clin Microbiol Infect 18 Suppl 7: 9–18. pmid:23137134
- 14.
Dendis M, Horvath R, Michalek J, Ruzicka F, Grijalva M, et al. (2003) PCR-RFLP detection and species identification of fungal pathogens in patients with febrile neutropenia. Clin Microbiol Infect: 1191–1202.
- 15. Cornet M, Sendid B, Fradin C, Gaillardin C, Poulain D, et al. (2011) Molecular Identification of Closely Related Candida Species Using Two Ribosomal Intergenic Spacer Fingerprinting Methods. J Mol Diagn 13: 12–22. pmid:21227390
- 16. Kurtzman CP, Robnett CJ (1997) Identification of clinically important ascomycetous yeasts based on nucleotide divergence in the 5' end of the large-subunit (26S) ribosomal DNA gene. J Clin Microbiol 35: 1216–1223. pmid:9114410
- 17. Ciardo DE, Schär G, Böttger EC, Altwegg M, Bosshard PP (2006) Internal transcribed spacer sequencing versus biochemical profiling for identification of medically important yeasts. J Clin Microbiol 44: 77–84. pmid:16390952
- 18. Leaw SN, Chang HC, Sun HF, Barton R, Bouchara JP, et al. (2006) Identification of medically important yeast species by sequence analysis of the internal transcribed spacer regions. J Clin Microbiol 44: 693–699. pmid:16517841
- 19. Montero C, Shea Y, Jones P, Harrington S, Tooke N, et al. (2008) Evaluation of Pyrosequencing (R) technology for the identification of clinically relevant non-dematiaceous yeasts and related species. Eur J Clinl MicrobiolInfect Dis 27: 821–830. pmid:18421488
- 20. Borman A, Linton C, Oliver D, Palmer M, Szekely A, et al. (2010) Rapid Molecular Identification of Pathogenic Yeasts by Pyrosequencing Analysis of 35 Nucleotides of Internal Transcribed Spacer 2. J Clin Microbiol 48: 3648–3653. pmid:20702674
- 21. Gharizadeh B, Norberg E, Löffler J, Jalal S, Tollemar J, et al. (2004) Identification of medically important fungi by the Pyrosequencing technology. Mycoses 47: 29–33. pmid:14998396
- 22. Loeffler J, Henke N, Hebart H, Schmidt D, Hagmeyer L, et al. (2000) Quantification of fungal DNA by using fluorescence resonance energy transfer and the light cycler system. J Clin Microbiol 38: 586–590. pmid:10655350
- 23. Pryce TM, Kay ID, Palladino S, Heath CH (2003) Real-time automated polymerase chain reaction (PCR) to detect Candida albicans and Aspergillus fumigatus DNA in whole blood from high-risk patients. Diagn Microbiol Infect Dis 47: 487–496. pmid:14596967
- 24. Maaroufi Y, Ahariz N, Husson M, Crokaert F (2004) Comparison of different methods of isolation of DNA of commonly encountered Candida species and its quantitation by using a real-time PCR-based assay. J Clin Microbiol 42: 3159–3163. pmid:15243076
- 25. Klingspor L, Jalal S (2006) Molecular detection and identification of Candida and Aspergillus spp. from clinical samples using real-time PCR. Clin Microbiol Infect 12: 745–753. pmid:16842569
- 26. Fricke S, Fricke C, Schimmelpfennig C, Oelkrug C, Schonfelder U, et al. (2010) A real-time PCR assay for the differentiation of Candida species. J Appl Microbiol 109: 1150–1158. pmid:20456528
- 27. Hsu MC, Chen KW, Lo HJ, Chen YC, Liao MH, et al. (2003) Species identification of medically important fungi by use of real-time LightCycler PCR. J Med Microbiol 52: 1071–1076. pmid:14614065
- 28. Bergman A, Fernandez V, Holmström KO, Claesson BE, Enroth H (2007) Rapid identification of pathogenic yeast isolates by real-time PCR and two-dimensional melting-point analysis. Eur J Clin Microbiol Infect Dis 26: 813–818. pmid:17680284
- 29. Dunyach C, Bertout S, Phelipeau C, Drakulovski P, Reynes J, et al. (2008) Detection and identification of Candida spp. in human serum by LightCycler real-time polymerase chain reaction. Diagn Microbiol Infect Dis 60: 263–271. pmid:18036761
- 30. Ahmad S, Khan Z, Mustafa A, Khan Z (2002) Seminested PCR for diagnosis of candidemia: Comparison with culture, antigen detection, and biochemical methods for species identification. J Clin Microbiol 40: 2483–2489. pmid:12089267
- 31. Lau A, Sorrell T, Chen S, Stanley K, Iredell J, et al. (2008) Multiplex tandem PCR: a novel platform for rapid detection and identification of fungal pathogens from blood culture specimens. J Clin Microbiol 46: 3021–3027. pmid:18632914
- 32. Wang Q, Li J, Wang S, Bai F (2008) Rapid differentiation of phenotypically similar yeast species by single-strand conformation polymorphism analysis of ribosomal DNA. Appl Environl Microb 74: 2604–2611. pmid:18344345
- 33. Shepard JR, Addison RM, Alexander BD, Della-Latta P, Gherna M, et al. (2008) Multicenter evaluation of the Candida albicans/Candida glabrata peptide nucleic acid fluorescent in situ hybridization method for simultaneous dual-color identification of C. albicans and C. glabrata directly from blood culture bottles. J Clin Microbiol 46: 50–55. pmid:17977998
- 34. Marklein G, Josten M, Klanke U, Muller E, Horre R, et al. (2009) Matrix-Assisted Laser Desorption Ionization-Time of Flight Mass Spectrometry for Fast and Reliable Identification of Clinical Yeast Isolates. J Clin Microbiol 47: 2912–2917. pmid:19571014
- 35. Cassagne C, Ranque S, Normand A, Fourquet P, Thiebault S, et al. (2011) Mould Routine Identification in the Clinical Laboratory by Matrix-Assisted Laser Desorption Ionization Time-Of-Flight Mass Spectrometry. Plos One 6. pmid:22242145
- 36. Quiles-Melero I, Garcia-Rodriguez J, Gomez-Lopez A, Mingorance J (2012) Evaluation of matrix-assisted laser desorption/ionisation time-of-flight (MALDI-TOF) mass spectrometry for identification of Candida parapsilosis, C. orthopsilosis and C. metapsilosis. Eur J Clin Microbiol Infect Dis 31: 67–71. pmid:21547602
- 37. Zhao Y, Park S, Kreiswirth BN, Ginocchio CC, Veyret R, et al. (2009) Rapid real-time nucleic Acid sequence-based amplification-molecular beacon platform to detect fungal and bacterial bloodstream infections. J Clin Microbiol 47: 2067–2078. pmid:19403758
- 38. Kaleta E, Clark A, Johnson D, Gamage D, Wysocki V, et al. (2011) Use of PCR Coupled with Electrospray Ionization Mass Spectrometry for Rapid Identification of Bacterial and Yeast Bloodstream Pathogens from Blood Culture Bottles. J Clin Microbiol49: 345–353. pmid:21048006
- 39. Reed GH, Kent JO, Wittwer CT (2007) High-resolution DNA melting analysis for simple and efficient molecular diagnostics. Pharmacogenomics 8: 597–608. pmid:17559349
- 40. Cheng JC, Huang CL, Lin CC, Chen CC, Chang YC, et al. (2006) Rapid detection and identification of clinically important bacteria by high-resolution melting analysis after broad-range ribosomal RNA real-time PCR. Clin Chem 52: 1997–2004. pmid:16990426
- 41. Stephens AJ, Inman-Bamber J, Giffard PM, Huygens F (2008) High-resolution melting analysis of the spa repeat region of Staphylococcus aureus. Clin Chem 54: 432–436. pmid:18223135
- 42. Won H, Rothman R, Ramachandran P, Hsieh YH, Kecojevic A, et al. (2010) Rapid identification of bacterial pathogens in positive blood culture bottles by use of a broad-based PCR assay coupled with high-resolution melt analysis. J Clin Microbiol 48: 3410–3413. pmid:20631110
- 43. Slany M, Vanerkova M, Nemcova E, Zaloudikova B, Ruzicka F, et al. (2010) Differentiation of Staphylococcus spp. by high-resolution melting analysis. Can J Microbiol 56: 1040–1049. pmid:21164574
- 44. Steer PA, Kirkpatrick NC, O'Rourke D, Noormohammadi AH (2009) Classification of fowl adenovirus serotypes by use of high-resolution melting-curve analysis of the hexon gene region. J Clin Microbiol 47: 311–321. pmid:19036935
- 45. Tajiri-Utagawa E, Hara M, Takahashi K, Watanabe M, Wakita T (2009) Development of a rapid high-throughput method for high-resolution melting analysis for routine detection and genotyping of noroviruses. J Clin Microbiol 47: 435–440. pmid:19073870
- 46. Plachy R, Hamal P, Raclavsky V (2005) McRAPD as a new approach to rapid and accurate identification of pathogenic yeasts. J Microbiol Meth 60: 107–113.
- 47. Trtkova J, Pavlicek P, Ruskova L, Hamal P, Koukalova D, et al. (2009) Performance of optimized McRAPD in identification of 9 yeast species frequently isolated from patient samples: potential for automation. BMC Microbiol 9. pmid:20043849
- 48.
Hrncirova K, Lengerova M, Kocmanova I, Racil Z, Volfova P, et al. (2010) Rapid Detection and Identification of Mucormycetes from Culture and Tissue Samples by Use of High-Resolution Melt Analysis. J Clin Microbiol: 3392–3394.
- 49.
Mandviwala T, Shinde R, Kalra A, Sobel J, Akins R (2010) High-Throughput Identification and Quantification of Candida Species Using High Resolution Derivative Melt Analysis of Panfungal Amplicons. J Mol Diagn: 91–101.
- 50. Arancia S, Sandini S, De Bernardis F, Fortini D (2011) Rapid, simple, and low-cost identification of Candida species using high-resolution melting analysis. Diagn Microbiol Infect Dis 69: 283–285. pmid:21353953
- 51. Somogyvari F, Horvath A, Serly J, Majoros H, Vagvolgyi C, et al. (2012) Detection of Invasive Fungal Pathogens by Real-time PCR and High-resolution Melting Analysis. In Vivo 26: 979–983. pmid:23160681
- 52. Goldschmidt P, Degorge S, Sarria P, Benallaoua D, Semoun O, et al. (2012) New Strategy for Rapid Diagnosis and Characterization of Fungal Infections: The Example of Corneal Scrapings. Plos One 7. pmid:23349657
- 53. Decat E, Van Mechelen E, Saerens B, Vermeulen SJ, Boekhout T, et al. (2013) Rapid and accurate identification of isolates of Candida species by melting peak and melting curve analysis of the internally transcribed spacer region 2 fragment (ITS2-MCA). Res Microbiol 164: 110–117. pmid:23142490
- 54. Alnuaimi AD, Wiesenfeld D, O'Brien-Simpson NM, Reynolds EC, Peng B, et al. (2014) The development and validation of a rapid genetic method for species identification and genotyping of medically important fungal pathogens using high-resolution melting curve analysis. Mol Oral Microbiol 29: 117–130. pmid:24628973
- 55. Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ (1990) Basic local alignment search tool. J Mol Biol 215: 403–410. pmid:2231712
- 56.
CBS-KNAW Fungal Biodiversity Centre CBS Filamentous Fungi Database. Utrecht, The Netherlands.
- 57. Tamura K, Dudley J, Nei M, Kumar S (2007) MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Mol Biol Evol 24: 1596–1599. pmid:17488738
- 58. Dwight Z, Palais R, Wittwer CT (2011) uMELT: prediction of high-resolution melting curves and dynamic melting profiles of PCR products in a rich web application. Bioinformatics 27: 1019–1020. pmid:21300699
- 59. Lockhart SR, Messer SA, Pfaller MA, Diekema DJ (2008) Geographic distribution and antifungal susceptibility of the newly described species Candida orthopsilosis and Candida metapsilosis in comparison to the closely related species Candida parapsilosis. J Clin Microbiol 46: 2659–2664. pmid:18562582
- 60. Cantón E, Pemán J, Quindós G, Eraso E, Miranda-Zapico I, et al. (2011) Prospective multicenter study of the epidemiology, molecular identification, and antifungal susceptibility of Candida parapsilosis, Candida orthopsilosis, and Candida metapsilosis isolated from patients with candidemia. Antimicrob Agents Chemother 55: 5590–5596. pmid:21930869
- 61. Desnos-Ollivier M, Ragon M, Robert V, Raoux D, Gantier J, et al. (2008) Debaryomyces hansenii (Candida famata), a rare human fungal pathogen often misidentified as Pichia guilliermondii (Candida guilliermondii). J Clin Microbiol 46: 3237–3242. pmid:18701668
- 62. Hamal P, Ostransky J, Dendis M, Horvath R, Ruzicka F, et al. (2008) A case of endocarditis caused by the yeast Pichia fabianii with biofilm production and developed in vitro resistance to azoles in the course of antifungal treatment. Med Mycol 46: 601–605. pmid:18608935
- 63. Valenza G, Valenza R, Brederlau J, Frosch M, Kurzai O (2006) Identification of Candida fabianii as a cause of lethal septicaemia. Mycoses 49: 331–334. pmid:16784449
- 64. Staib P, Morschhäuser J (1999) Chlamydospore formation on Staib agar as a species-specific characteristic of Candida dubliniensis. Mycoses 42: 521–524. pmid:10592694
- 65. Pincus DH, Coleman DC, Pruitt WR, Padhye AA, Salkin IF, et al. (1999) Rapid identification of Candida dubliniensis with commercial yeast identification systems. J Clin Microbiol 37: 3533–3539. pmid:10523548
- 66. Ellepola AN, Hurst SF, Elie CM, Morrison CJ (2003) Rapid and unequivocal differentiation of Candida dubliniensis from other Candida species using species-specific DNA probes: comparison with phenotypic identification methods. Oral Microbiol Immunol 18: 379–388. pmid:14622344
- 67. Chryssanthou E, Fernandez V, Petrini B (2007) Performance of commercial latex agglutination tests for the differentiation of Candida dubliniensis and Candida albicans in routine diagnostics. APMIS 115: 1281–1284. pmid:18092961