中高海拔地区帕金森病非运动症状的临床特征谱及其与肠道菌群-肠-脑轴关联机制

doi:10.3969/j.issn.1004-583X.2026.04.002

摘要/Abstract

摘要：

目的探讨中高海拔地区帕金森病(PD)患者非运动症状(NMS)的临床特征及其与肠道菌群组成、血浆短链脂肪酸(SCFAs)和炎症因子水平的关联。方法采用横断面研究,选取长期居住于中高海拔地区(西宁市,海拔约2 295 m;海南州,海拔>3 000 m)的PD患者(PD组,n=45)和年龄、性别、民族匹配的健康对照者(HC组,n=45)。采用非运动症状问卷(NMSQuest)、帕金森病睡眠量表(PDSS)、医院焦虑抑郁量表(HADS)评估NMS,统一帕金森病评定量表第三部分(UPDRS-III)评估运动症状。采集晨起粪便和空腹静脉血。采用16S rRNA基因测序分析肠道菌群;气相色谱-质谱联用法检测血浆SCFAs(乙酸、丙酸、丁酸)水平;酶联免疫吸附法检测血浆白细胞介素1β(IL-1β)、IL-6、肿瘤坏死因子α(TNF-α)水平。比较组间差异,采用Spearman相关分析及多元线性回归分析各指标间关联。结果与HC组相比,PD组NMSQuest总分、HADS-A及HADS-D评分均显著增高(均P<0.01),PDSS评分显著降低,便秘发生率更高(82.2% vs 31.1%,P<0.01)。PD组肠道菌群α多样性(Shannon指数)低于HC组(P<0.05),β多样性存在显著差异(PERMANOVA,P=0.001)。在属水平,PD组普雷沃菌属(Prevotella)丰度显著降低,肠杆菌科(Enterobacteriaceae)未分类属、乳酸杆菌属(Lactobacillus)丰度显著增高(均P<0.05)。相关性分析显示,PD患者普雷沃菌属丰度与血浆丁酸水平呈正相关(r=0.462,P=0.002),与HADS-D评分呈负相关(r=-0.384,P=0.010);血浆丁酸水平与HADS-D评分呈负相关(r=-0.356,P=0.018),与TNF-α水平呈负相关(r=-0.332,P=0.028)。中介效应模型提示,血浆丁酸水平在普雷沃菌属丰度与抑郁症状(HADS-D评分)间起部分中介作用(中介效应占比21.7%)。结论中高海拔地区PD患者NMS负担重,尤其以睡眠障碍、抑郁焦虑及便秘突出。其肠道菌群结构失调,特征为产丁酸菌减少、潜在促炎菌增多。菌群紊乱可能通过减少丁酸生成、加剧系统性炎症,进而参与抑郁等NMS的发生。本研究为高海拔地区PD的NMS管理及针对肠-脑轴的干预提供了新思路。

关键词: 帕金森病, 高海拔, 非运动症状, 肠道菌群, 短链脂肪酸, 神经炎症

Abstract:

Objective To investigate the clinical characteristics of non-motor symptoms (NMS) in patients with Parkinson's disease (PD) living at mid-to-high altitude, and to explore their associations with gut microbiota composition, plasma short-chain fatty acids (SCFAs), and inflammatory cytokine levels. Methods A cross-sectional study was conducted. Patients with PD who had long-term residence at mid-to-high altitude areas (Xining, altitude approximately 2295 m; Hainan Prefecture, altitude >3000 m) were enrolled as the PD group (n=45), and age-, sex-, and ethnicity-matched healthy individuals were enrolled as the healthy control group (HC group, n=45). NMS were assessed using the Non-Motor Symptoms Questionnaire (NMSQuest), the Parkinson's Disease Sleep Scale (PDSS), and the Hospital Anxiety and Depression Scale (HADS), while motor symptoms were evaluated using Part III of the Unified Parkinson's Disease Rating Scale (UPDRS-III). Morning stool samples and fasting venous blood samples were collected. Gut microbiota was analyzed by 16S rRNA gene sequencing. Plasma SCFAs, including acetate, propionate, and butyrate, were measured by gas chromatography-mass spectrometry. Plasma interleukin-1β (IL-1β), IL-6, and tumor necrosis factor-α (TNF-α) levels were determined by enzyme-linked immunosorbent assay. Group differences were compared, and Spearman correlation analysis and multivariable linear regression were used to examine associations among variables. Results Compared with the HC group, the PD group had significantly higher total NMSQuest scores, HADS-A scores, and HADS-D scores (all P<0.01), PDSS scores significantly lower(P<0.01), as well as a higher prevalence of constipation (82.2% vs 31.1%, P<0.01). The PD group showed lower gut microbiota α-diversity (Shannon index) than the HC group (P<0.05), and significant differences in β-diversity were observed (PERMANOVA, P=0.001). At the genus level, the abundance of Prevotella was significantly decreased in the PD group, whereas the abundance of unclassified Enterobacteriaceae and Lactobacillus was significantly increased (all P<0.05). Correlation analysis showed that in patients with PD, Prevotella abundance was positively correlated with plasma butyrate levels (r=0.462, P=0.002) and negatively correlated with HADS-D scores (r=-0.384, P=0.010). Plasma butyrate levels were negatively correlated with HADS-D scores (r=-0.356, P=0.018) and TNF-α levels (r=-0.332, P=0.028). Mediation analysis suggested that plasma butyrate partially mediated the association between Prevotella abundance and depressive symptoms (HADS-D score), accounting for 21.7% of the total effect. Conclusion Patients with PD living at mid-to-high altitude bear a substantial NMS burden, particularly with prominent sleep disturbance, anxiety, depression, and constipation. Their gut microbiota composition is dysregulated, characterized by a reduction in butyrate-producing bacteria and an increase in potentially pro-inflammatory bacteria. Such microbial imbalance may contribute to NMS, including depression, by reducing butyrate production and exacerbating systemic inflammation. This study provides new insights into NMS management in PD at high altitude and into interventions targeting the gut-brain axis.

Key words: Parkinson’s disease, high altitude, non-motor symptoms, gastrointestinal microbiome, short-chain fatty acids, neuroinflammation

中图分类号:

R742.5

林涛, 吴玮君. 中高海拔地区帕金森病非运动症状的临床特征谱及其与肠道菌群-肠-脑轴关联机制[J]. 临床荟萃, 2026, 41(4): 301-306.

Lin Tao, Wu Weijun. Clinical feature spectrum of non-motor symptoms in Parkinson's disease at mid-to-high altitude and their associations with the gut microbiota-gut-brain axis[J]. Clinical Focus, 2026, 41(4): 301-306.

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链接本文: https://www.lchc.cn/CN/10.3969/j.issn.1004-583X.2026.04.002

https://www.lchc.cn/CN/Y2026/V41/I4/301

图/表 5

表1 两组受试者一般资料及临床特征比较

Tab.1 Comparison of general data and clinical characteristics between the two groups

项目	PD组( $n$ =45)	HC组( $n$ =45)	统计值	$P$ 值
年龄(岁)	65.0(58.5, 70.0)	63.0(58.0, 68.0)	$Z$ =-0.786	0.432
性别(男/女)	28/17	26/19	χ²=0.202	0.653
民族(汉/其他)	39/6	41/4	χ²= 0.455	0.500
主要居住地(西宁/海南州)	30/15	28/17	χ²= 0.183	0.669
病程(年)	5.0(3.0, 8.0)	-	-	-
Hoehn-Yahr分期[例(%)]
1~1.5期	15(33.3)	-	-	-
2~2.5期	22(48.9)	-	-	-
3~4期	8(17.8)	-	-	-
UPDRS-III评分(分)	28.0(21.0, 36.5)	1.0(0.0, 3.0)	$Z$ =-8.203	<0.01
NMSQuest总分(分)	12.0(9.0, 16.0)	4.0(2.0, 6.0)	$Z$ =-7.360	<0.01
PDSS评分(分)	105.0(92.0, 118.0)	138.0(130.0, 143.0)	$Z$ =-6.922	<0.01
HADS-A评分(分)	8.0(6.0, 11.0)	3.0(1.0, 4.0)	$Z$ =-7.046	<0.01
HADS-D评分(分)	7.0(5.0, 10.0)	2.0(1.0, 3.0)	$Z$ =-6.981	<0.01
便秘[例(%)]	37(82.2)	14(31.1)	χ²= 24.229	<0.01

表1 两组受试者一般资料及临床特征比较

Tab.1 Comparison of general data and clinical characteristics between the two groups

项目	PD组( $n$ =45)	HC组( $n$ =45)	统计值	$P$ 值
年龄(岁)	65.0(58.5, 70.0)	63.0(58.0, 68.0)	$Z$ =-0.786	0.432
性别(男/女)	28/17	26/19	χ²=0.202	0.653
民族(汉/其他)	39/6	41/4	χ²= 0.455	0.500
主要居住地(西宁/海南州)	30/15	28/17	χ²= 0.183	0.669
病程(年)	5.0(3.0, 8.0)	-	-	-
Hoehn-Yahr分期[例(%)]
1~1.5期	15(33.3)	-	-	-
2~2.5期	22(48.9)	-	-	-
3~4期	8(17.8)	-	-	-
UPDRS-III评分(分)	28.0(21.0, 36.5)	1.0(0.0, 3.0)	$Z$ =-8.203	<0.01
NMSQuest总分(分)	12.0(9.0, 16.0)	4.0(2.0, 6.0)	$Z$ =-7.360	<0.01
PDSS评分(分)	105.0(92.0, 118.0)	138.0(130.0, 143.0)	$Z$ =-6.922	<0.01
HADS-A评分(分)	8.0(6.0, 11.0)	3.0(1.0, 4.0)	$Z$ =-7.046	<0.01
HADS-D评分(分)	7.0(5.0, 10.0)	2.0(1.0, 3.0)	$Z$ =-6.981	<0.01
便秘[例(%)]	37(82.2)	14(31.1)	χ²= 24.229	<0.01

表2 两组受试者肠道菌群多样性及主要差异菌群比较[ M(P25,P75)]

Tab.2 Comparison of gut microbiota diversity and main differential bacteria between the two groups( M[P25, P75])

项目	PD组( $n$ =45)	HC组( $n$ =45)	$Z$ 值	$P$ 值^*
α多样性指数
Chao1指数	320.5(285.2, 378.6)	348.7(298.3, 405.1)	-1.321	0.186
Shannon指数	5.21(4.68, 5.72)	5.98(5.41, 6.45)	-2.263	0.024
主要菌门相对丰度(%)
厚壁菌门(Firmicutes)	68.5(62.1, 75.3)	65.2(58.9, 71.8)	-0.931	0.352
拟杆菌门(Bacteroidota)	18.3(12.5, 25.6)	24.1(17.8, 30.2)	-1.762	0.078
变形菌门(Proteobacteria)	7.8(4.1, 12.5)	5.2(2.9, 8.7)	-1.845	0.065
差异菌属相对丰度(%)
普雷沃菌属(Prevotella)	2.15(0.86, 5.22)	8.47(4.35, 15.61)	-4.217	<0.01
肠杆菌科未分类属(unclassified Enterobacteriaceae)	1.86(0.72, 4.15)	0.51(0.18, 1.23)	-2.654	0.008
乳酸杆菌属(Lactobacillus)	0.95(0.41, 2.08)	0.38(0.15, 0.92)	-2.431	0.015

表2 两组受试者肠道菌群多样性及主要差异菌群比较[ M(P25,P75)]

Tab.2 Comparison of gut microbiota diversity and main differential bacteria between the two groups( M[P25, P75])

项目	PD组( $n$ =45)	HC组( $n$ =45)	$Z$ 值	$P$ 值^*
α多样性指数
Chao1指数	320.5(285.2, 378.6)	348.7(298.3, 405.1)	-1.321	0.186
Shannon指数	5.21(4.68, 5.72)	5.98(5.41, 6.45)	-2.263	0.024
主要菌门相对丰度(%)
厚壁菌门(Firmicutes)	68.5(62.1, 75.3)	65.2(58.9, 71.8)	-0.931	0.352
拟杆菌门(Bacteroidota)	18.3(12.5, 25.6)	24.1(17.8, 30.2)	-1.762	0.078
变形菌门(Proteobacteria)	7.8(4.1, 12.5)	5.2(2.9, 8.7)	-1.845	0.065
差异菌属相对丰度(%)
普雷沃菌属(Prevotella)	2.15(0.86, 5.22)	8.47(4.35, 15.61)	-4.217	<0.01
肠杆菌科未分类属(unclassified Enterobacteriaceae)	1.86(0.72, 4.15)	0.51(0.18, 1.23)	-2.654	0.008
乳酸杆菌属(Lactobacillus)	0.95(0.41, 2.08)	0.38(0.15, 0.92)	-2.431	0.015

表3 两组受试者血浆SCFAs及炎症因子水平比较( x -±s)

Tab.3 Comparison of plasma SCFAs and inflammatory cytokine levels between the two groups( x -±s)

项目	PD组( $n$ =45)	HC组( $n$ =45)	$t$ 值	$P$ 值
乙酸(μmol/L)	85.6±23.4	89.7±20.1	-0.901	0.370
丙酸(μmol/L)	12.8±5.2	14.1±4.8	-1.247	0.216
丁酸(μmol/L)	5.3±2.1	7.8±2.5	-5.173	<0.001
IL-1β(ng/L)	1.05±0.41	0.98±0.38	0.858	0.393
IL-6(ng/L)	3.28±1.05	2.67±0.89	3.041	0.003
TNF-α(ng/L)	8.45±2.67	7.12±2.31	2.579	0.011

表3 两组受试者血浆SCFAs及炎症因子水平比较( x -±s)

Tab.3 Comparison of plasma SCFAs and inflammatory cytokine levels between the two groups( x -±s)

项目	PD组( $n$ =45)	HC组( $n$ =45)	$t$ 值	$P$ 值
乙酸(μmol/L)	85.6±23.4	89.7±20.1	-0.901	0.370
丙酸(μmol/L)	12.8±5.2	14.1±4.8	-1.247	0.216
丁酸(μmol/L)	5.3±2.1	7.8±2.5	-5.173	<0.001
IL-1β(ng/L)	1.05±0.41	0.98±0.38	0.858	0.393
IL-6(ng/L)	3.28±1.05	2.67±0.89	3.041	0.003
TNF-α(ng/L)	8.45±2.67	7.12±2.31	2.579	0.011

表4 PD组主要指标间的Spearman相关性分析[ r( P)]

Tab.4 Spearman correlation analysis among main variables in the PD group( r[ P])

变量	普雷沃菌属丰度	肠杆菌科未分类属丰度	血浆丁酸	血浆TNF-α	HADS-D评分
普雷沃菌属丰度	1.000
肠杆菌科未分类属丰度	-0.201(0.187)	1.000
血浆丁酸	0.462(0.002)	-0.158(0.302)	1.000
血浆TNF-α	-0.289(0.055)	0.345(0.022)	-0.332(0.028)	1.000
HADS-D评分	-0.384(0.010)	0.241(0.112)	-0.356(0.018)	0.285(0.059)	1.000

表5 HADS-D评分影响因素的多元线性回归分析

Tab.5 Multiple linear regression analysis of factors influencing HADS-D score

变量	回归系数	标准误	标准化回归系数	$t$ 值	$P$ 值	95% $C I$
常量	10.856	2.374		4.573	<0.01	6.058~15.654
普雷沃菌属丰度	-0.415	0.158	-0.301	-2.626	0.012	-0.735~-0.095
血浆丁酸水平	-0.672	0.297	-0.268	-2.263	0.029	-1.272~-0.072
TNF-α水平	0.185	0.116	0.186	1.595	0.119	-0.049~0.419
UPDRS-III评分	0.028	0.031	0.105	0.903	0.372	-0.035~0.091

表5 HADS-D评分影响因素的多元线性回归分析

Tab.5 Multiple linear regression analysis of factors influencing HADS-D score

变量	回归系数	标准误	标准化回归系数	$t$ 值	$P$ 值	95% $C I$
常量	10.856	2.374		4.573	<0.01	6.058~15.654
普雷沃菌属丰度	-0.415	0.158	-0.301	-2.626	0.012	-0.735~-0.095
血浆丁酸水平	-0.672	0.297	-0.268	-2.263	0.029	-1.272~-0.072
TNF-α水平	0.185	0.116	0.186	1.595	0.119	-0.049~0.419
UPDRS-III评分	0.028	0.031	0.105	0.903	0.372	-0.035~0.091

参考文献 15

[1]	Marogianni C, Sokratous M, Dardiotis E, et al. Neurodegeneration and inflammation-an interesting interplay in Parkinson's disease[J]. Int J Mol Sci, 2020, 21(22):8421. doi: 10.3390/ijms21228421.
[2]	Berg D, Borghammer P, Fereshtehnejad SM, et al. Prodromal Parkinson disease subtypes-key to understanding heterogeneity[J]. Nat Rev Neurol, 2021, 17(6):349-361. doi: 10.1038/s41582-021-00486-9.
[3]	Claudino Dos Santos JC, Lima MPP, Brito GAC, Viana GSB. Role of enteric glia and microbiota-gut-brain axis in parkinson disease pathogenesis[J]. Ageing Res Rev, 2023,84:101812. doi: 10.1016/j.arr.2022.101812.
[4]	Salim S, Ahmad F, Banu A, et al. Gut microbiome and Parkinson's disease: Perspective on pathogenesis and treatment[J]. J Adv Res, 2023, 50:83-105. doi: 10.1016/j.jare.2022.10.013.
[5]	Ni Z, Zhou Y, Chang M, et al. High-altitude impacts on gut microbiota: Accelerated aging and the urgency for targeted health interventions[J]. High Alt Med Biol, 2025, 26(4):388-392. doi: 10.1089/ham.2025.0016.
[6]	Hao D, Niu H, Zhao Q, et al. Impact of high-altitude acclimatization and de-acclimatization on the intestinal microbiota of rats in a natural high-altitude environment[J]. Front Microbiol, 2024, 15:1371247. doi: 10.3389/fmicb.2024.1371247.
[7]	Kauser H, Sahu S, Kumar S, et al. Guanfacine is an effective countermeasure for hypobaric hypoxia-induced cognitive decline[J]. Neuroscience, 2013, 254:110-119. doi: 10.1016/j.neuroscience.2013.09.023. pmid: 24056194
[8]	Postuma RB, Berg D, Stern M, et al. MDS clinical diagnostic criteria for Parkinson's disease[J]. Movement Disorders, 2015, 30(12): 1591-1601.doi: 10.1002/mds.26424. pmid: 26474316
[9]	Du W, Liu L, Ma Y, Zhu Q, et al. Analysis of the gut microbiome in obese native Tibetan children living at different altitudes: A case-control study[J]. Front Public Health, 2022, 10:963202. doi: 10.3389/fpubh.2022.963202.
[10]	Li J, Zhao G, Yu C, et al. Ginsenoside Re exerts neuroprotective in MPTP mice: Potential links to gut microbiota and serum metabolism[J]. Neuropharmacology, 2026, 282:110596. doi: 10.1016/j.neuropharm.2025.110596.
[11]	Dong X, Deng L, Su Y, et al. Curcumin alleviates traumatic brain injury induced by gas explosion through modulating gut microbiota and suppressing the LPS/TLR4/MyD88/NF-κB pathway[J]. Environ Sci Pollut Res Int, 2024, 31(1):1094-1113. doi: 10.1007/s11356-023-30708-0.
[12]	Leta V, Zinzalias P, Batzu L, et al. Effects of a four-strain probiotic on gut microbiota, inflammation, and symptoms in Parkinson's disease: A randomized clinical trial[J]. Mov Disord, 2025, 40(12):2710-2721. doi: 10.1002/mds.70047.
[13]	Dodiya HB, Forsyth CB, Voigt RM, et al. Chronic stress-induced gut dysfunction exacerbates Parkinson's disease phenotype and pathology in a rotenone-induced mouse model of Parkinson's disease[J]. Neurobiol Dis, 2020, 135:104352. doi: 10.1016/j.nbd.2018.12.012.
[14]	Quraishi MN, Cheesbrough J, Rimmer P, et al. Open label vancomycin in primary sclerosing cholangitis-inflammatory bowel disease: Improved colonic disease activity and associations with changes in host-microbiome-metabolomic signatures[J]. J Crohns Colitis, 2025, 19(2):jjae189. doi: 10.1093/ecco-jcc/jjae189.
[15]	Oliveira SDS, Minshall RD. Caveolin and endothelial NO signaling[J]. Curr Top Membr, 2018, 82:257-279. doi: 10.1016/bs.ctm.2018.09.004. pmid: 30360781