核酸质谱技术在热带念珠菌ERG11位点突变检测中的应用

doi:10.3969/j.issn.1006-5725.2025.16.020

Abstract

Abstract:

Objective To evaluate the application value of nucleic acid mass spectrometry in detecting ERG11 gene mutations associated with azole resistance in Candida tropicalis （C. tropicalis）， thereby providing a scientific basis for the rational clinical use of azole antifungal agents. Methods Clinical isolates of C. tropicalis were obtained from the Affiliated Hospital of Xuzhou Medical University between July 2023 and November 2024. For each isolate， specific ERG11 mutations （A395T and C461T） were analyzed using Sanger sequencing and nucleic acid mass spectrometry. Sanger sequencing was used as the reference standard to evaluate the performance of mass spectrometry in mutation detection. Results The established nucleic acid mass spectrometry method effectively identified four genotypes of ERG11 （A395T and C461T）， with distinct spectral peaks for each mutation and no cross-interference observed. Among 88 clinical isolates， the sensitivity， specificity， positive predictive value （PPV）， and negative predictive value （NPV） for the A395T mutation were 86.7%， 100%， 100%， and 97.3%， respectively. For the C461T mutation， the corresponding values were 81.3%， 100%， 100%， and 96.0%， respectively. Kappa statistics demonstrated a high level of agreement between mass spectrometry and sequencing results. Conclusions Nucleic acid mass spectrometry exhibits high sensitivity and specificity in the detection of ERG11 mutations， enabling rapid， accurate， and adaptable high-throughput analysis. This makes it a highly effective method for identifying mutations associated with fungal resistance.

Key words: Candida tropicalis, azole resistance, ERG11 gene, nucleic acid mass spectrometry

CLC Number:

R446

Yan CHEN,Hongxia ZHU,Haiquan KANG,Yi GUO,Yinhai XU,Jingfang. SUN. Application value of nucleic acid mass spectrometry in detecting ERG11 mutation in Candida tropicalis[J]. The Journal of Practical Medicine, 2025, 41(16): 2575-2580.

Figures/Tables 6

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References 22

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标本类型	氟康唑			伏立康唑
标本类型	S	SDD	R	S	I	R
血液	9	2	3	9	2	3
尿液	20	7	10	22	8	7
肺泡灌洗液	11	4	4	12	3	4
胸腹水/引流液	5	1	4	4	3	3
其他	5	1	2	6	0	2

引物名称	用途	引物序列（5'-3'）
ERG11-CX-F	ERG11基因扩增、测序	ATGGCTATTGTTGATACTGCC
ERG11-CX-R	ERG11基因扩增、测序	CTAAACCATACAAGTATCTC
ERG11-KZ-F	ERG11位点扩增	ACGTTGGATGCTGCTGAAGAAGCTTATACCCATT
ERG11-KZ-R	ERG11位点扩增	ACGTTGGATGACCATGGTCTCTTTCCTTGGT
探针A395T	单碱基延伸	CTCCTGTTT TTGGTAAAGGTGTTATTT
探针C461T	单碱基延伸	GCTAAATTTGCTTTGACTACTGATT

395位点基因	461位点基因	氟康唑			伏立康唑
395位点基因	461位点基因	S	SDD	R	S	I	R
A	C	50	15	7	53	16	3
A	T	0	0	1	0	0	1
T	T	0	0	15	0	0	15
T	C	0	0	0	0	0	0

样本号	标本来源	MIC值/（μg/mL）		395位点检测（A→T）		461位点检测（C→T）
样本号	标本来源	氟康唑	伏立康唑	核酸质谱	测序	核酸质谱	测序
14	引流液	16	2	T	T	T	T
36	尿液	256	8	A	T	C	T
56	尿液	256	8	T	T	T	T
71	尿液	256	8	A/T	T	C/T	T
134	尿液	256	8	T	T	T	T
166	尿液	256	8	T	T	T	T
175	尿液	256	8	T	T	C/T	T
203	分泌物	256	8	T	T	T	T
238	肺泡灌洗液	256	8	T	T	T	T
293	血液	256	8	T	T	T	T
297	尿液	256	8	T	T	T	T
322	肺泡灌洗液	256	8	T	T	T	T
341	胸水	64	2	A	A	C	T
448	脑脊液	256	8	T	T	T	T
472	血液	256	8	T	T	T	T
3149	血液	256	8	A	T	C	T

Application value of nucleic acid mass spectrometry in detecting ERG11 mutation in Candida tropicalis

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