P017 Echinocandin resistance mechanism in Candida tropicalis and Candida glabrata

IF 1.4 Q4 MYCOLOGY

Medical mycology journal Pub Date : 2022-09-01 DOI:10.1093/mmy/myac072.P017

Dipti Sharma, R. Paul, J. Murlidharan, Sadhna Sharma, H. Kaur, Anup K. Ghosh, A. Chakrabarti, S. Rudramurthy

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引用次数: 0

Abstract

Abstract Poster session 1, September 21, 2022, 12:30 PM - 1:30 PM Objective Candida tropicalis and Candida glabrata account for 41.6% and 7.08% of total Candidaemia cases in India. Echinocandins are the first-line treatment option for these infections. Resistance to Echinocandins is rare with Candida sp. However, in recent years, has been noted across many centers. We determined the mechanism of echinocandin resistance in C. tropicalis and C. glabrata. Methods C. tropicalis and C. glabrata isolated from Candidaemia patients over a period of 3 years (August 2016-July 2019), identified by MALDI-TOF-MS were used in this study. Antifungal susceptibility testing was done following CLSI broth microdilution reference method (M 27A). FKS1 gene was sequenced using species-specific primers for the presence of any mutation. To determine any changes in the cell wall chitin and glucan contents, expression fold changes of chitin synthase (CHS1, CHS2, and CHS3), and glucan synthase genes upon caspofungin treatment were determined using real-time qPCR. These findings were correlated with cell wall chitin and glucan content determined by flowcytometry. Results A total of 3558 Candida species were isolated from patients of all age groups at our hospital. C. tropicalis was the predominant agent (34%), while the prevalence of C. glabrata was 6%. A total of 17 (8.5%) C. glabrata and 3 (0.25%) C. tropicalis exhibited reduced susceptibility to echinocandins. All these isolates carried a wild-type FKS genes. In C. tropicalis, inducible expression of Chs1, Chs2 and Chs3 genes were comparable among susceptible and resistant isolates1.8 (0.4-2.8) vs. 2.5 (0.9-6.6), P = .247); [0.7 (0.3-1.8) vs. 0.7 (0.2-1.6), P = .793]; [1.3 (0.14-4.8) vs. 1.1(0.48-1.7), P = .522], respectively. In concordance with gene expression, there was no significant difference in cell wall chitin contents among resistant and susceptible [14.37 (6.5-24.8) vs 16.28 (6.0-24.7), P = .114] C. tropicalis isolates. In contrast in resistant isolates of C. glabrata, caspofungin treatment resulted in significantly higher induction of chitin synthase genes compared to susceptible isolates; Chs1 [2.34 (0.24-9.71) vs. 1.56 (0.55-4.5) (P = .007)], CHS2 [1.59 (0.33-8.0) vs. (2.3 (0.69-6.15), P = .0006], and CHS3 gene [3.8 (0.13-12.73) vs. 1.9 (0.56-7.16), P <.0001]. Flowcytometric data in terms of chitin content, correlated well with expression changes as staining index was significantly higher in resistant compared to susceptible isolates [320 (198-535) vs. 164 (5.34-254.10) P = .0001]. Glucan synthase expression was comparable in susceptible and resistant isolates of C. tropicalis [3.47 (1.57-7.63) vs. 4.41 (0.41-17.51), (P = .518)]. However, glucan synthase gene expression was found significantly increased in resistant C. glabrata isolates compared to susceptible isolates; 3.10 (1.02-16.45) vs. 1.61 (0.13-7.67), P <.001. Conclusion We evaluated the role of cell wall components in echinocandin resistance in isolates with reduced susceptibility to echinocandins but lacking an FKS1 mutation. While chitin was induced at higher levels in C. glabrata, a similar finding was not observed in C. tropicalis. This warrants further studies to elucidate the role of fungal cell wall polymers in resistance.

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P017热带假丝酵母菌和光滑假丝酵母菌棘白菌素耐药机制

【摘要】海报会议1,2022年9月21日，12:30 PM - 1:30 PM目的热带假丝酵母菌和光滑假丝酵母菌分别占印度念珠菌血症病例总数的41.6%和7.08%。棘白菌素是这些感染的一线治疗选择。念珠菌对棘白菌素的耐药性是罕见的。然而，近年来，在许多中心已经注意到。研究了热带棘球蚴和光斑棘球蚴对棘球蚴素的抗性机制。方法采用MALDI-TOF-MS鉴定的3年间(2016年8月- 2019年7月)从念珠菌血症患者中分离得到的热带C. (C. tropical)和光棘C. (C. glabrata)。采用CLSI肉汤微量稀释参比法(m27a)进行抗真菌药敏试验。使用物种特异性引物对FKS1基因进行测序，以确定是否存在突变。为了检测细胞壁几丁质和葡聚糖含量的变化，我们采用实时荧光定量pcr检测了caspofungin处理后几丁质合成酶(CHS1、CHS2和CHS3)和葡聚糖合成酶基因的表达折叠变化。这些结果与流式细胞术测定的细胞壁甲壳素和葡聚糖含量有关。结果本院各年龄组患者共分离念珠菌3558株。以热带蠓为主(34%)，光斑蠓为主(6%)。共有17只(8.5%)裸棘球绦虫和3只(0.25%)热带棘球绦虫对棘白菌素的敏感性降低。所有分离株均携带野生型FKS基因。在热带镰刀菌中，Chs1、Chs2和Chs3基因的诱导表达量在易感菌株和抗性菌株中具有可比性，分别为1.8(0.4-2.8)和2.5 (0.9-6.6)，P = 0.247;[0.7 (0.3-1.8) vs. 0.7 (0.2-1.6)， P = .793];[1.3(0.14 - -4.8)和1.1 (0.48 - -1.7),P = .522],分别。与基因表达一致，耐药株和敏感株细胞壁甲壳素含量无显著差异[14.37 (6.5-24.8)vs 16.28 (6.0-24.7)， P = .114]。在抗性菌株中，caspofungin诱导的几丁质合成酶基因显著高于敏感菌株;Chs1[2.34(0.24 - -9.71)和1.56 (0.55 - -4.5)(P = .007)], CHS2[1.59(0.33 - -8.0)和(2.3 (0.69 - -6.15),P =考虑),和CHS3基因[3.8(0.13 - -12.73)和1.9(0.56 - -7.16)、P <。)。流式细胞术数据显示，与敏感菌株相比，耐药菌株的染色指数明显高于敏感菌株[320(198-535)比164 (5.34-254.10)P = 0.0001]。葡聚糖合成酶在敏感和耐药菌株中表达量相当[3.47(1.57-7.63)比4.41 (0.41-17.51)，(P = .518)]。然而，与敏感菌株相比，抗性菌株的葡聚糖合成酶基因表达显著增加;3.10 (1.02 ~ 16.45) vs. 1.61 (0.13 ~ 7.67)， P < 0.001。结论我们评估了细胞壁成分在棘白菌素耐药性中的作用，这些菌株对棘白菌素敏感性降低，但缺乏FKS1突变。虽然几丁质在光棘草中诱导的水平较高，但在热带棘草中没有观察到类似的发现。这需要进一步的研究来阐明真菌细胞壁聚合物在抗性中的作用。

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来源期刊

Medical mycology journal Medicine-Infectious Diseases

CiteScore

1.80

自引率

10.00%

发文量

期刊介绍： The Medical Mycology Journal is published by and is the official organ of the Japanese Society for Medical Mycology. The Journal publishes original papers, reviews, and brief reports on topics related to medical and veterinary mycology.