四川省高海拔地区结核分枝杆菌耐药及传播特征分析

doi:10.19982/j.issn.1000-6621.20250217

摘要/Abstract

摘要：

目的: 分析四川省高海拔地区(石渠县,4520m)结核分枝杆菌耐药情况及遗传多样性,为我国高海拔高寒地区制定结核病精准防控策略、建立分枝杆菌菌种库、探索高海拔对分枝杆菌进化的影响提供科学数据。方法: 采用前瞻性研究方法,按照标准流程采集2023年6月至2024年4月期间四川省石渠县结核病定点医疗机构收集的189例肺结核患者痰液样本(每例1份)进行罗氏固体培养,再经上级机构基因芯片技术和基因测序,最终纳入75株有效菌株。再使用结核分枝杆菌序列分析平台对所有菌株的菌型、耐药及基因突变、谱系及成簇情况等进行分析。结果: 75株菌株中,33株菌株对9种抗结核药物耐药,总耐药率为44.00%,包含33个耐药突变位点和35种突变耐药类型。33株耐药菌株中,10株(13.33%)为耐多药菌株,2株(2.67%)为准广泛耐药菌株,21株(28.00%)为其他耐药菌株;14株(42.42%)为单一突变耐药,12株(36.36%)为2种突变耐药,7株(21.21%)为3种及以上突变耐药。在耐药的9种药物中,异烟肼的耐药率最高[42.42%(14/33)],利福平次之[39.39%(13/33)]。谱系分型中,东亚型(L2型)占89.33%(67/75),且以东亚系北京型为主[94.03%(63/67)],余8株(10.67%)为欧美谱系型(L4型)。51株为成簇菌株,成簇率为68.00%,共鉴定出12个簇,成簇菌株数介于2~12株,以2株为最多[50.00%(6/12)]。结论: 四川省高海拔高寒地区石渠县肺结核耐药比例明显高于其他地区,主要流行谱系为L2型,且成簇率较高,肺结核近期传播风险较严重。该地区应进一步加强结核病防治工作,以减少结核分枝杆菌传播和耐药产生。

关键词: 分枝杆菌,结核, 序列标记位点,串联重复序列, 结核,抗多种药物性, 流行病学研究特征(主题), 高海拔

Abstract:

Objective: To analyze the drug resistance profile and genetic diversity of Mycobacterium tuberculosis (MTB) in high-altitude regions of Sichuan Province (Sêrxü County, 4520 meters) and provide scientific data for formulating targeted tuberculosis (TB) prevention and control strategy, establishing MTB strain bank, and exploring influence of high altitude on MTB evolution in high altitude and alpine areas of China. Methods: A prospective study design was adopted, sputum samples from 189 pulmonary tuberculosis (PTB) patients, collected by designated medical institutions in Sêrxü County, Sichuan Province between June 2023 and April 2024, were obtained following standard procedures and subjected to modified Lowenstein-Jensen (LJ) solid culture, followed by genetic chip analysis and sequencing by a higher-level institution. Ultimately, a total of 75 valid strains were finally included in the study. An MTB sequence analysis platform was used to analyze the strain type, drug resistance, gene mutation, lineage, and clustering status of all strains. Results: Among the 75 strains, 33 strains were found to be resistant to 9 anti-tuberculosis drugs, with 33 resistant mutation sites and 35 types of resistant mutations. The total drug resistance rate was 44.00%. Among them, 10 strains (13.33%) were multidrug-resistant strains, 2 strains (2.67%) were pre-extensively drug-resistant strains, and 21 strains (28.00%) were other resistant strains. Among the 33 drug-resistant strains, 14 strains (42.42%) were single-mutation resistant, 12 strains (36.36%) had two resistance-related mutations, and 7 strains (21.21%) had three or more resistance-related mutations. For the 9 anti-TB drugs, the resistance rate to isoniazid was the highest (42.42%, 14/33), followed by rifampicin (39.39%, 13/33). In the lineage typing, the East Asian type (L2 type) accounted for 89.33% (67/75), mainly the Beijing East Asian type (94.03%, 63/67), while the other 8 strains were European-American type (L4 type, 10.67%). Fifty-one strains were clustered strains, with a clustering rate of 68.00%, and a total of 12 clusters were identified. The number of clustered strains ranged from 2 to 12, with 2 strains being the most common type (50.00%, 6/12). Conclusion: The proportion of drug-resistant tuberculosis in Sêrxü County, a high-altitude and cold area in Sichuan Province, is significantly higher than that in other regions. The main prevalent lineage is L2 type, and the clustering rate is relatively high, indicating a serious risk of recent tuberculosis transmission. The region should further strengthen tuberculosis prevention and control efforts to reduce the spread of MTB and the emergence of drug resistance.

Key words: Mycobacterium tuberculosis, Sequence-based typing, tandem repeat sequence, Tuberculosis, multi-drug resistant, Epidemiological research characteristics (subject), High altitude

中图分类号:

高媛, 雷卉, 何璐, 于子涵, 陈闯, 何金戈, 夏岚. 四川省高海拔地区结核分枝杆菌耐药及传播特征分析[J]. 中国防痨杂志, 2025, 47(11): 1459-1464. doi: 10.19982/j.issn.1000-6621.20250217

Gao Yuan, Lei Hui, He Lu, Yu Zihan, Chen Chuang, He Jin’ge, Xia Lan. Analysis of drug resistance and transmission of Mycobacterium tuberculosis in high-altitude areas of Sichuan Province, China[J]. Chinese Journal of Antituberculosis, 2025, 47(11): 1459-1464. doi: 10.19982/j.issn.1000-6621.20250217

图/表 3

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药品/突变基因与位点	突变菌株株数	药品/突变基因与位点	突变菌株株数	药品/突变基因与位点	突变菌株株数
异烟肼	14	gid_large_deletion	1	gyrB_T500N;gyrA_D94G	1
katG_S315G	7	rpsL_K43R	1	莫西沙星	6
katG_S315T	4	rrs_A514C	1	gyrB_S447F	3
katG_A162T	1	对氨基水杨酸	7	gyrA_A90V	1
inhA_S94A	1	thyA_H75N	7	gyrA_D94G	1
katG_D94A;ahpC_G-48A	1	乙胺丁醇	6	gyrB_T500N;gyrA_D94G	1
利福平	13	embB_M306I	2	吡嗪酰胺	4
rpoB_L430P	7	embB_G406A	1	pncA_Q141P	1
rpoB_S450L	2	embA_C-12T	1	pncA_D12G	1
rpoB_S450F	1	embB_M306V	1	pncA_C138R	1
rpoB_L430P;rpoB_H445Q	1	embB_Q497R	1	pncA_M175V	1
rpoB_D435Y;rpoB_N437H	1	氧氟沙星	6	乙硫异烟胺	2
rpoB_S450L;rpoC_L527V	1	gyrB_S447F	3	inhA_S94A	1
链霉素	9	gyrA_A90V	1	fabG1_L203L	1
rpsL_K88R	6	gyrA_D94G	1	合计	67

株号	耐药类型/突变基因与位点	株号	耐药类型/突变基因与位点	株号	耐药类型/突变基因与位点
	单一耐药	12	thyA_H75N	23	gyrA_D94G;gyrA_D94G
1	rpsL_K88R	13	embB_M306I	24	katG_S315G;rpoB_L430P
2	thyA_H75N	14	rpsL_K88R	25	gyrB_S447F;gyrB_S447F
3	rpsL_K88R		2种突变耐药	26	gyrB_S447F;gyrB_S447F
4	rpsL_K88R	15	katG_S315G;rpoB_L430P		3种及以上突变耐药
5	thyA_H75N	16	inhA_S94A;inhA_S94A	27	katG_D94A;ahpC_G-48A;rpoB_S450F;embB_M306I;pncA_Q141P
6	rpsL_K88R	17	katG_S315G;rpoB_L430P	28	katG_S315T;rpoB_L430P;gid_large_deletion
7	thyA_H75N	18	katG_S315G;rpoB_L430P	29	katG_S315T;rpoB_S450L;embB_G406A
8	rpsL_K88R	19	katG_A162T;rpsL_K43R	30	katG_S315T;rpoB_S450L;embA_C-12T;pncA_D12G
9	thyA_H75N	20	katG_S315G;rpoB_L430P	31	katG_S315G;rpoB_L430P;rpoB_H445Q;embB_M306V;pncA_C138R;gyrB_T500N;gyrA_D94G;gyrB_T500N;gyrA_D94G
10	thyA_H75N	21	katG_S315G;rpoB_L430P	32	katG_S315T;rpoB_D435Y;rpoB_N437H;embB_Q497R;pncA_M175V;gyrA_A90V;gyrA_A90V
11	thyA_H75N	22	gyrB_S447F;gyrB_S447F	33	rpoB_S450L;rpoC_L527V;rrs_A514C;fabG1_L203L

簇大小 (株)	簇		菌株
簇大小 (株)	数量(个)	构成比(%)	株数	构成比(%)
2	6	50.00	12	23.53
3	1	8.33	3	5.89
5	1	8.33	5	9.80
6	2	16.67	12	23.53
7	1	8.33	7	13.73
12	1	8.33	12	23.53
合计	12	100.00	51	100.00