Jeong Won Song

Changes in Karyotype and Azole Susceptibility of Sequential Bloodstream Isolates from Patients with Candida glabrata Candidemia

ABSTRACT We examined the changes in genotypes and azole susceptibilities among sequential bloodstream isolates of Candida glabrata during the course of fungemia and the relationship of these changes to antifungal therapy. Forty-one isolates were obtained from 15 patients (9 patients who received antifungal therapy and 6 patients who did not) over periods of up to 36 days. The isolates were analyzed using pulsed-field gel electrophoresis (PFGE) and multilocus sequence typing (MLST) and tested for antifungal susceptibility to fluconazole, itraconazole, and voriconazole. PFGE typing consisted of electrophoretic karyotyping and restriction endonuclease analysis of genomic DNA by use of NotI (REAG-N). The 41 isolates yielded 23 different karyotypes and 11 different REAG-N patterns but only 3 MLST types. The sequential strains from each patient had identical or similar REAG-N patterns. However, they had two or three different karyotypes in 6 (40%) of 15 patients. The isolates from these six patients exhibited the same or similar azole susceptibilities, and five patients did not receive antifungal therapy. Development of acquired azole resistance in sequential isolates was detected for only one patient. For this patient, an isolate of the same genotype obtained after azole therapy showed three- or fourfold increases in the MICs of all three azole antifungals and exhibited increased expression of the CgCDR1 efflux pump. This study shows that karyotypic changes can develop rapidly among sequential bloodstream strains of C. glabrata from the same patient without antifungal therapy. In addition, we confirmed that C. glabrata could acquire azole resistance during the course of fungemia in association with azole therapy.

Microevolution of Candida albicans Strains during Catheter-Related Candidemia

ABSTRACT We examined microevolution in a series of Candida albicans strains isolated from patients with catheter-related candidemia. Sixty-one isolates (29 from blood, 18 from catheters, 10 from urine, and 4 from other sites) were obtained from 15 patients who were admitted to the same hospital over a 3-year period. Isolates were analyzed by using Southern hybridization with the C1 fragment of Ca3 as a probe (C1 fingerprinting) and pulsed-field gel electrophoresis (PFGE). PFGE typing consisted of electrophoretic karyotyping (EK) and restriction endonuclease analysis of genomic DNA (REAG) by using SfiI (REAG-S) and BssHII (REAG-B). When catheter isolates were compared with blood isolates from the same patient, catheter isolates from 5 of 14 patients (36%) exhibited minor band differences (microevolution) relative to blood isolates in either C1 fingerprinting (n = 4), REAG-S (n = 3), or REAG-B (n = 5) profiles, although they had identical EK patterns. However, the other sequential isolates from each patient, which had identical EK patterns, showed the same REAG and C1 fingerprinting patterns. Both fingerprinting methods revealed that two distinct genotypes were shared by isolates from seven patients in a neonatal intensive care unit, suggesting two nosocomial clusters. Except for two catheter isolates from the index patients of each cluster, no consecutive isolates collected from each of the two clusters showed any microevolution during the 2- or 7-month cluster periods. The findings suggest that in catheter-related candidemia, some C. albicans strains undergo microevolution during catheter colonization.

Electrophoretic Karyotype Analysis of Sequential Candida parapsilosis Isolates from Patients with Persistent or Recurrent Fungemia

ABSTRACT We assessed the genetic relatedness of sequential isolates ofCandida parapsilosis during persistent or recurrent fungemia and the effect of central venous catheter (CVC) removal. Serial isolates of C. parapsilosis were obtained from 17 patients with persistent or recurrent fungemia over periods of up to 5 months. Forty-eight C. parapsilosis isolates from the blood of 17 patients were analyzed by electrophoretic karyotyping (EK) with pulsed-field gel electrophoresis (PFGE), revealing 25 different karyotypes. The strains sequentially isolated from each of seven patients whose fungemia resolved following CVC removal had the same karyotype. Two patients with fungemia that cleared without CVC removal each had two sequential isolates with different karyotypes. In six (75%) of the eight patients whose fungemia was recurrent even after CVC removal, the karyotypes of the pre- and post-CVC removal isolates were different, implying the emergence of a new strain. Overall, the sequential strains from each patient had identical karyotypes in 53% (9 of 17) of the patients and two different karyotypes in 47% (8 of 17). This study shows that EK with PFGE is useful for investigating persistent or recurrent fungemia due to C. parapsilosis and that recurrent fungemia due to C. parapsilosis is more likely caused by reinfection with a second strain.

Differences in biofilm production by three genotypes of Candida parapsilosis from clinical sources

Three distinct genotypes of Candida parapsilosis (group I, II, and III) have been identified among clinical isolates but their clinical significance remains unclear. We investigated the distribution of C. parapsilosis genotypes in isolates from blood, all other sites from patients, and the hands of health care workers (HCWs), and we examined the relationship between genotype and biofilm positivity. The 53 bloodstream isolates and 38 of 39 HCW isolates were categorized as group I, whereas the 67 non-blood isolates taken from patients were distributed in groups I (n=43), II (n=13), and III (n=11). Biofilm positivity was observed in 77% (103 of 134) of group I isolates versus 0% (0 of 25) of non-group I (groups II and III) isolates (P < 0.01). There was no difference in biofilm production among group I isolates from blood (81%), other clinical specimens (72%), and the hands of HCWs (73%). This study has shown that biofilm production differs among three genotypes of C. parapsilosis isolates and that a majority of C. parapsilosis isolates from the bloodstream (100%), the hands of HCWs (97%), and all other sites from patients (64%) belong to group I, which has the ability to produce biofilm.

Expression of CgCDR1, CgCDR2, and CgERG11 in Candida glabrata biofilms formed by bloodstream isolates.

Many studies have shown that Candida biofilms are highly resistant to fluconazole. The mechanisms of acquired fluconazole resistance of Candida glabrata in non-biofilms have been elucidated, but the relevance of them relative to C. glabrata in biofilms are unknown. We examined by real-time PCR the expression of CgCDR1, CgCDR2, and CgERG11 of four bloodstream isolates of C. glabrata during the early (6 h), intermediate (15 h), and mature (48 h) phases of biofilm development. We found high levels of biofilm formation in vitro. At 6 and 15 h, the biofilms exhibited, in comparison to planktonic cells, approximately 1.5- and 3.3-fold upregulation of CgCDR1 and 0.5- and 3.1-fold upregulation of CgCDR2, respectively. However, at 48 h, neither gene was upregulated. In comparison, the expression of CgERG11 did not significantly increase during any of the three phases. Our results indicate a temporary increase in the expression of both CgCDR1 and CgCDR2 during the intermediate phase of C. glabrata biofilm development. In addition, the data collected at 48 h suggest that CgCDR1, CgCDR2, and CgERG11 may not play a role in the azole resistance of C. glabrata in mature biofilms.

A novel Bvar allele (547 G>A) demonstrates differential expression depending on the co-inherited ABO allele

Background and Objectives  Genetic analysis of group B donors in Korea was performed.

Multiplex in-cell reverse transcription-polymerase chain reaction for the simultaneous detection of p210 and p190 BCR-ABL mRNAs in chronic myeloid leukemia and philadelphia-positive acute lymphoblastic leukemia cell lines

Abstract We designed a novel multiplex in-cell reverse transcription- polymerase chain reaction method for the simultaneous detection and differentiation of p190 and p210 BCR-ABL mRNAs within single cells from the human chronic myeloid leukemia and Philadelphia positive acute lymphoblastic leukemia. Human K562 chronic myeloid leukemia and SUP B-15 Ph+ acute lymphoblastic leukemia cell lines were used as positive controls for p210 and p190 BCR-ABL mRNAs, respectively. HL60 cell line was used as a negative control. After the leukemia cells were fixed and permeabilized, without extracting nucleic acids, the mRNAs were reverse transcribed to cDNAs, and the cDNAs were amplified by multiplex polymerase chain reaction with fluorescent primers specific for p190 and p210 BCR-ABL mRNAs. After transfer onto glass slides by cytospin, the amplified cells were detected by fluorescence microscopy. Fluorescence microscopy after propidium iodide or 4′,6-diamidino-2-phenylindone counterstaining showed that the positive K562 cells exhibited a yellow-green fluorescent cytoplasm around a red nucleus, and that the positive SUP B-15 cells exhibited an orange cytoplasm around a blue nucleus. Only the red or blue nucleus was visible in respective negative HL60 cells. The specificity of amplification was confirmed by the absence of a signal when control experiments were performed either with RNase digestion of mRNA or without reverse transcriptase/Taq polymerase. We conclude that the multiplex in-cell reverse transcription-polymerase chain reaction method is capable of simultaneously detecting and differentiating the p210 and p190 BCR-ABL mRNAs of chronic myeloid leukemia and Philadelphia-positive acute lymphoblastic leukemia cells, and that it may be useful in quantitatively monitoring the minimal residual disease during therapy.