Molecular Typing and Antifungal Susceptibility of Candida viswanathii, India

We report invasive candidiasis caused by Candida viswanathii over 2 time periods during 2013–2015 in a tertiary care hospital in Chandigarh, India. Molecular typing revealed multiple clusters of the isolates. We detected high MICs for fluconazole in the second time period.

I nvasive candidiasis is a life-threatening infection caused by various Candida species. Although C. albicans has been the predominant species causing invasive candidiasis, non-albicans Candida (NAC) species have emerged globally (1). C. viswanathii, a pathogen first isolated from the cerebrospinal fluid of a patient in 1959 (2), is rarely encountered, and only 17 cases have been reported worldwide (3). This agent has been isolated sporadically from animal and environmental sources (4)(5)(6).
We report on 23 cases of invasive candidiasis caused by C. viswanathii at a tertiary care center in Chandigarh, India, involving 7 case-patients during December 2013-April 2014 and 16 case-patients during December 2014-April 2015. In the first time period, all isolates were from blood, whereas in the second time period, the agent was isolated from pus (n = 5), blood (n = 5), cerebrospinal fluid (n = 3), and lung nodule, lung aspirate, and iliac fluid (n = 1 each).
We screened the hospital environment and the hands of healthcare workers for a possible source of C. viswanathii infection during the second time period. We could not isolate C. viswanathii from any of those samples from a total of 46 workers and 57 different environmental sites.
Conventional methods failed to differentiate C. viswanathii and C. tropicalis. C. viswanathii assimilated sucrose and cellobiose but failed to assimilate trehalose and raffinose. C. tropicalis has a variable assimilation pattern for these sugars.
To identify the isolates, we performed matrix-assisted laser desorption/ionization time-of-flight mass spectroscopy using MALDI-TOF MS, version 3 (Bruker Daltonik GmbH, Bremen, Germany) and sequenced the D1/D2 region of a large subunit of ribosomal DNA (7,8). Because we could not identify C. viswanathii using the MALDI-TOF MS version 3 database, we updated the database inhouse by adding sequence-proved isolates of C. viswanathii. We identified the isolates with a log score of >1.8 by using the modified database. The rDNA sequence of the isolates showed 100% similarity with the type strain of C. viswanathii ATCC 22981 (GenBank accession no. NG_054835.1) except for 1 isolate (99% similarity with type strain, accession no. MF682371). The molecular phylogenetic analysis revealed that 1 isolate (B-30815) had 1 nucleotide substitution (T to C), which was 1 of the 5 substitutions we observed in C. pseudoviswanathii while comparing it with C. viswanathii (9).
Amplified fragment-length polymorphism revealed a similarity coefficient of >90% of the isolates (online Technical Appendix Figure, https://wwwnc.cdc.gov/EID/ article/24/10/18-0801-Techapp1.pdf) (7). The isolates from the first time period formed 2 clusters (clusters A and B); 1 isolate from the second period was also in cluster B. Isolates of the second time period had 3 major clusters (clusters C, D, and E) and had higher MICs for fluconazole.
We performed antifungal susceptibility testing for amphotericin B, fluconazole, itraconazole, voriconazole, posaconazole, caspofungin, anidulafungin, and micafungin by the microbroth dilution method recommended by the Clinical and Laboratory Standards Institute (10). After incubating the plates for 24 h at 37°C, we took a visual reading to determine the MICs. The isolates of the second time period had higher MICs (MIC 50 64 μg/mL, MIC 90 64 μg/mL) for fluconazole compared with the isolates of the first period (MIC 50 1 μg/mL, MIC 90 1 μg/mL). We also recorded higher MICs (MIC 50 1 μg/mL, MIC 90 2 μg/mL) for voriconazole for the isolates of the second period (Table).
In conclusion, our study showed multiple clusters of C. viswanathii causing invasive infections in patients with neutropenia and chronic diseases at a single healthcare center in India. We could not trace the source of the agent. Conventional identification methods could not differentiate the isolates from those of C. tropicalis. The high MICs for fluconazole among the isolates from the second time period also raise concerns about possible antifungal resistance.  We report a rare case of Staphylococcus argenteus bone and joint infection in a 9-year-old boy in France. His finger arthritis was complicated by osteitis 5 weeks later, which resulted in a secondary intervention. This case indicates the virulence of S. argenteus, an emerging pathogen whose clinical effects are poorly described.

About the Author
S taphylococcus argenteus (formerly S. aureus clonal complex 75) is an emerging species in the S. aureus complex (1). Several studies reported sporadic cases of S. argenteus infections mainly in Asia, Oceania, and the Pacific Islands (2) but rarely in Europe (3). We report the clinical characteristics of a community-acquired bone and joint infection with S. argenteus in a child living in France.
At the end of July 2017, a 9-year-old boy with no unusual medical history or previous local trauma was hospitalized because of acute signs of infection of the third finger on his right hand. He was first seen in a local hospital and given an initial diagnosis of cellulitis (arthritis). Two days later, he was admitted to the emergency pediatric ward of a tertiary care hospital where a surgical joint exploration was performed and confirmed the diagnosis of arthritis associated with an abscess of the extensor tendon sheath (Table).
Surgical microbiological samples cultured on blood agar plates (aerobic conditions at 37°C for 24 h) grew a strain that was identified by matrix-assisted laser desorption/ ionization time-of-flight mass spectrometry (Microflex LT, Bruker, France) as having log scores ranging from 1.39 to