膳食结构对鞭虫感染人群肠道菌群的影响研究

doi:10.3969/j.issn.1672-2302.2023.01.007

摘要/Abstract

摘要：

目的探讨不同膳食结构对鞭虫感染人群肠道菌群的影响，为研究鞭虫感染者肠道疾病与饮食关系奠定基础。方法在山东省日照市岚山区5个乡镇选取34名鞭虫感染者，收集研究对象膳食资料，通过16S rDNA测序平台分析不同膳食结构下鞭虫感染人群肠道菌群多样性和物种组成的差异。结果未发现膳食摄入量高低与肠道菌群α多样性或β多样性有关，但蔬菜、奶制品和肉制品三种膳食结构与鞭虫感染人群肠道菌群的丰度与组成有显著关联。不同蔬菜摄入量组在属水平上相对丰度变化差异有统计学意义的有3个菌属：每日摄入量<300 g的鞭虫感染组（PDV3组）狭义梭菌属1（Clostridium sensu stricto 1）相对丰度高于每日摄入量>500 g的鞭虫感染组（PDV1组）（t=2.211，P<0.05）；PDV3组瘤胃球菌属（Ruminococcus）相对丰度低于PDV1组（t=2.246，P<0.05）；PDV3组双歧杆菌属（Bifidobacterium）相对丰度低于每日摄入量300~500 g的鞭虫感染组（PDV2组）（t=2.610，P<0.05）。不同奶制品摄入量组在属水平上相对丰度变化差异有统计学意义的有3个菌属：每日摄入量300~500 g的鞭虫感染组（PDD2组）狭义梭菌属1相对丰度高于每日摄入量>500 g的鞭虫感染组（PDD1组）（t=3.025，P<0.05）；每日摄入量<300 g的鞭虫感染组（PDD3组）另枝菌属（Alistipes）相对丰度低于PDD1组（t=3.234，P<0.05）；PDD3组瘤胃球菌UCG-014属（Ruminococcaceae UCG-014）相对丰度低于PDD2组（t=2.255，P<0.05）。不同肉制品摄入量组在属水平上相对丰度变化差异有统计学意义的有3个菌属：每日摄入量120~200 g的鞭虫感染组（PDM2组）考拉杆菌属（Phascolarctobacterium）和瘤胃球菌属2（Ruminococcus 2）相对丰度低于PDM1组（t=2.672、2.731，P均<0.05）；每日摄入量<120 g的鞭虫感染组（PDM3组）小类杆菌属（Dialister）相对丰度低于PDM2组（t=2.402，P<0.05）。结论不同膳食结构影响鞭虫感染人群的肠道菌群组成，提示应重视日常膳食摄入对鞭虫感染人群肠道疾病的调节作用，通过补充蔬菜、奶制品、肉制品来降低狭义梭菌属1等有害菌丰度，提高双歧杆菌属和另枝菌属等有益菌丰度，提高机体免疫力，减轻或避免鞭虫感染人群肠道炎症性疾病的发生发展。

关键词: 鞭虫, 膳食结构, 肠道菌群, 相对丰度, 多样性

Abstract:

Objective To investigate the effects of different dietary structures on the intestinal flora in population infected by Trichuris trichura (T. trichura) so as to lay a foundation for studying the relationship between intestinal diseases and diet in patients with T. trichura infection. Methods Thirty-four patients infected by T. trichura were recruited from five towns in Lanshan District, Rizhao City, Shandong Province, and their dietary information was collected and analyzed by 16S rDNA high-throughput sequencing to determine the differences in intestinal flora diversity and species composition among T. trichura infected populations with different dietary structures. Results No association was found between high dietary intake and gut flora Alpha diversity or Beta diversity. The three dietary structures of vegetables, dairy products and meat products were significantly associated with the abundance and composition of intestinal flora.There were three species with significant differences in the intake of different vegetables at the genus level. The relative abundance of Clostridium sensu stricto 1 in the PDV3 group with a daily intake of <300 g was higher than that in PDV1 group with a daily intake of >500 g, and the difference was statistically significant (t=2.211, P<0.05). The relative abundance of Ruminococcus in PDV3 group was significantly lower than that in PDV1 group (t=2.246, P<0.05), whereas the relative abundance of Bifidobacterium was lower in PDV3 group than in PDV2 group with daily intake of 300-500 g. The difference was significant (t=2.610, P<0.05). Three species were significantly different in the intake of different dairy products at the genus level. The abundance of Clostridium sensu stricto 1 in PDD2 group with daily intake of 300 g-500 g was higher than that in PDD1 group with daily intake of >500 g(t=3.025, P<0.05), contrarily, the abundance of the Alistipes in PDD3 group with daily intake <300 g was lower than that in PDD1 group (t=3.234, P<0.05). The abundance of Ruminococcaceae UCG-014 was significantly lower in PDD3 group than in PDD2 group (t=2.255, P<0.05). Three species with significant differences in the intake of different meat products at the genus level were observed. The abundance of the genus pair of Phascolarctobacterium and Ruminococcus 2 in PDM2 group with a daily intake of 120-200 g was lower than that in the PDM1 group, with significant difference between groups (t=2.672, P<0.05; t=2.731, P<0.05), yet the relative abundance of Dialister in PDM3 group with daily intake <120 g was lower than that in PDM2 group (t=2.402, P<0.05). Conclusion Different dietary structures affected the composition of intestinal flora in whipworm-infected populations. By supplementing the diet with vegetables, dairy products and meat products to reduce harmful bacteria such as Clostridium sensu stricto 1 and increasing beneficial bacteria such as Bifidobacterium and Alistipes can improve the immunity of the body and reduce or avoid the development of intestinal inflammatory diseases in people with T. trichura infection.

Key words: Trichuris trichura, Dietary structures, Intestinal flora, Relative abundance, Diversity

中图分类号:

R383.1+4

张艺馨, 王龙江, 刘建成, 刘萍萍, 王用斌, 许艳, 闫歌, 卜秀芹, 张佃波, 李曰进, 张本光. 膳食结构对鞭虫感染人群肠道菌群的影响研究[J]. 热带病与寄生虫学, 2023, 21(1): 35-43.

ZHANG Yi-xin, WANG Long-jiang, LIU Jian-cheng, LIU Ping-ping, WANG Yong-bin, XU Yan, YAN Ge, BU Xiu-qin, ZHANG Dian-bo, LI Yue-jin, ZHANG Ben-guang. Effect of dietary structures on intestinal flora in population infected with Trichuris trichura[J]. Journal of Tropical Diseases and Parasitology, 2023, 21(1): 35-43.

图/表 17

表1

表2

表3

图1

图2

图3

图4

图5

表4

图6

图7

图8

图9

表5

图10

图11

图12

参考文献 41

[1]	Duque-Correa MA, Karp NA, McCarthy C, et al. Exclusive dependence of IL-10Rα signalling on intestinal microbiota homeostasis and control of whipworm infection[J]. PLoS Pathog, 2019, 15(1):e1007265. doi: 10.1371/journal.ppat.1007265 URL
[2]	Summers RW, Elliott DE, Urban JF Jr, et al. Trichuris suis therapy for active ulcerative colitis:a randomized controlled trial[J]. Gastroenterology, 2005, 128(4):825-832. doi: 10.1053/j.gastro.2005.01.005 pmid: 15825065
[3]	Mejia R, Damania A, Jeun R, et al. Impact of intestinal parasites on microbiota and cobalamin gene sequences:a pilot study[J]. Parasit Vectors, 2020, 13(1):200. doi: 10.1186/s13071-020-04073-7
[4]	梁婷婷. 基于肠道微生态改善的植物蛋白脂质代谢调节机制[D]. 西安: 陕西科技大学, 2018.
[5]	Sonnenburg ED, Sonnenburg JL. Starving our microbial self:the deleterious consequences of a diet deficient in microbiota-accessible carbohydrates[J]. Cell Metab, 2014, 20(5):779-786. doi: S1550-4131(14)00311-8 pmid: 25156449
[6]	Abell GC, Cooke CM, Bennett CN, et al. Phylotypes related to Ruminococcus bromii are abundant in the large bowel of humans and increase in response to a diet high in resistant starch[J]. FEMS Microbiol Ecol, 2008, 66(3):505-515. doi: 10.1111/j.1574-6941.2008.00527.x pmid: 18616586
[7]	Walker AW, Ince J, Duncan SH, et al. Dominant and diet-responsive groups of bacteria within the human colonic microbiota[J]. ISME J, 2011, 5(2):220-230. doi: 10.1038/ismej.2010.118 pmid: 20686513
[8]	Connolly ML, Lovegrove JA, Tuohy KM. In vitro evaluation of the microbiota modulation abilities of different sized whole oat grain flakes[J]. Anaerobe, 2010, 16(5):483-488. doi: 10.1016/j.anaerobe.2010.07.001 pmid: 20624475
[9]	Lubbs DC, Vester BM, Fastinger ND, et al. Dietary protein concentration affects intestinal microbiota of adult cats:a study using DGGE and qPCR to evaluate differences in microbial populations in the feline gastrointestinal tract[J]. J Anim Physiol Anim Nutr (Berl), 2009, 93(1):113-121. doi: 10.1111/jpn.2009.93.issue-1 URL
[10]	刘雪姬, 陈庆森, 闫亚丽. 高脂饮食对小鼠肠道菌群的影响[J]. 食品科学, 2011, 32(23):306-311. doi: 10.7506/spkx1002-6630-201123062
[11]	Fava F, Gitau R, Griffin BA, et al. The type and quantity of dietary fat and carbohydrate alter faecal microbiome and short-chain fatty acid excretion in a metabolic syndrome ‘at-risk’ population[J]. Int J Obes (Lond), 2013, 37(2):216-223. doi: 10.1038/ijo.2012.33
[12]	付炯兴, 姚伟元, 徐望红. 2型糖尿病患者膳食纤维摄入量与肠道菌群的关联:基于一项随机对照试验的数据再分析[J]. 中华疾病控制杂志, 2022, 26(9):1078-1084.
[13]	陈世玉. 东北地区驼鹿种群扩散模式、肠道微生物及寄生虫对气候变暖的响应研究[D]. 哈尔滨: 东北林业大学, 2022.
[14]	陈静, 薛琳. 营养状况与寄生虫病间的相互影响(一)[J]. 湖北预防医学杂志, 1992, 3(1):40-44.
[15]	徐梦. 广西部分农村地区人群华支睾吸虫感染风险因素及其肠道菌群研究[D]. 北京: 中国疾病预防控制中心, 2019.
[16]	诸廷俊, 周长海, 许隆祺, 等. 《肠道蠕虫检测改良加藤厚涂片法》(WS/T 570—2017)解读[J]. 中国血吸虫病防治杂志, 2018, 30(5):575-577.
[17]	陈欢欢. 膳食纤维摄入、肠道微生物分布及血清短链脂肪酸浓度与肺癌治疗效果的关系及其作用机制[D]. 沈阳: 中国医科大学, 2022.
[18]	中国营养学会. 中国居民膳食指南:2022[M]. 北京: 人民卫生出版社, 2022.
[19]	周心晨, 王兰, 张雨琛, 等. 腹泻仔猪的粪便微生物代谢组学分析[J]. 中国畜牧杂志, 2022, 58(9):279-285.
[20]	Bolger AM, Lohse M, Usadel B. Trimmomatic:a flexible trimmer for Illumina sequence data[J]. Bioinformatics, 2014, 30(15):2114-2120. doi: 10.1093/bioinformatics/btu170 URL
[21]	Caporaso JG, Kuczynski J, Stombaugh J, et al. QIIME allows analysis of high-throughput community sequencing data[J]. Nat Methods, 2010, 7(5):335-336. doi: 10.1038/nmeth.f.303 pmid: 20383131
[22]	Wang Q, Garrity GM, Tiedje JM, et al. Naive Bayesian classifier for rapid assignment of rRNA sequences into the new bacterial taxonomy[J]. Appl Environ Microbiol, 2007, 73(16):5261-5267. doi: 10.1128/AEM.00062-07 URL
[23]	王景. 16S rRNA基因二代测序中的测序深度与测序错误对微生物群落多样性分析的影响[D]. 上海: 上海交通大学, 2018.
[24]	韩翔宇, 孟凡, 王建忠. 肠道菌群的形成及影响因素的研究进展[J]. 新疆医学, 2021, 51(7):836-839.
[25]	Peng J, Narasimhan S, Marchesi JR, et al. Long term effect of gut microbiota transfer on diabetes development[J]. J Autoimmun, 2014, 53:85-94. doi: 10.1016/j.jaut.2014.03.005 pmid: 24767831
[26]	Goff LM, Cowland DE, Hooper L, et al. Low glycaemic index diets and blood lipids:a systematic review and meta-analysis of randomised controlled trials[J]. Nutr Metab Cardiovasc Dis, 2013, 23(1):1-10. doi: 10.1016/j.numecd.2012.06.002 pmid: 22841185
[27]	王娴, 潘研, 万红, 等. 2型糖尿病合并肥胖患者膳食结构及肠道菌群结构的差异性[J]. 中华疾病控制杂志, 2020, 24(7):761-766.
[28]	Haghikia A, Jörg S, Duscha A, et al. Dietary fatty acids directly impact central nervous system autoimmunity via the small intestine[J]. Immunity, 2015, 43(4):817-829. doi: 10.1016/j.immuni.2015.09.007 pmid: 26488817
[29]	Koh A, De Vadder F, Kovatcheva-Datchary P, et al. From dietary fiber to host physiology:short-chain fatty acids as key bacterial metabolites[J]. Cell, 2016, 165(6):1332-1345. doi: 10.1016/j.cell.2016.05.041 URL
[30]	Singh N, Gurav A, Sivaprakasam S, et al. Activation of Gpr109a,receptor for niacin and the commensal metabolite butyrate,suppresses colonic inflammation and carcinogenesis[J]. Immunity, 2014, 40(1):128-139. doi: 10.1016/j.immuni.2013.12.007 URL
[31]	谢海胜. 高糖饮食干预下AD模型小鼠肠道菌群结构和血浆代谢谱变化的研究[D]. 杭州: 浙江工业大学, 2017.
[32]	Hu Y, le Leu RK, Christophersen CT, et al. Manipulation of the gut microbiota using resistant starch is associated with protection against colitis-associated colorectal cancer in rats[J]. Carcinogenesis, 2016, 37(4):366-375. doi: 10.1093/carcin/bgw019 pmid: 26905582
[33]	Myhill LJ, Stolzenbach S, Hansen TVA, et al. Mucosal barrier and Th2 immune responses are enhanced by dietary inulin in pigs infected with Trichuris suis[J]. Front Immunol, 2018, 9:2557. doi: 10.3389/fimmu.2018.02557 pmid: 30473696
[34]	Leonardi I, Gerstgrasser A, Schmidt TSB, et al. Preventive Trichuris suis ova (TSO) treatment protects immunocompetent rabbits from DSS colitis but may be detrimental under conditions of immunosuppression[J]. Sci Rep, 2017, 7(1):16500. doi: 10.1038/s41598-017-16287-4 pmid: 29184071
[35]	Gong LX, Cao WY, Gao J, et al. Whole Tibetan hull-less barley exhibit stronger effect on promoting growth of genus Bifidobacterium than refined barley in vitro[J]. J Food Sci, 2018, 83(4):1116-1124. doi: 10.1111/jfds.2018.83.issue-4 URL
[36]	Parker BJ, Wearsch PA, Veloo ACM, et al. The genus Alistipes:gut bacteria with emerging implications to inflammation,cancer,and mental health[J]. Front Immunol, 2020, 11:906. doi: 10.3389/fimmu.2020.00906 URL
[37]	Wu FF, Guo XF, Zhang JC, et al. Phascolarctobacterium faecium abundant colonization in human gastrointestinal tract[J]. Exp Ther Med, 2017, 14(4):3122-3126. doi: 10.3892/etm.2017.4878 URL
[38]	Yunes RA, Poluektova EU, Dyachkova MS, et al. GABA production and structure of gadB/gadC genes in Lactobacillus and Bifidobacterium strains from human microbiota[J]. Anaerobe, 2016, 42:197-204. doi: S1075-9964(16)30130-5 pmid: 27794467
[39]	刘甜. 肠道菌群—筛查肺癌患者免疫相关性腹泻的新标志物[D]. 北京: 中国人民解放军医学院, 2018.
[40]	谢坤铭. 膝骨关节炎患者肠道菌群与代谢变化及桂皮醛对兔膝骨关节炎模型肠道菌群及巨噬细胞极化影响的研究[D]. 北京: 北京中医药大学, 2021.
[41]	臧凯丽. 微生态制剂调控与脂代谢相关肠道菌群多样性的相关信息分析[D]. 天津: 天津商业大学, 2019.

特征	调查人数	构成比（%）
性别
男	19	55.9
女	15	44.1
年龄（岁）
<40	1	2.9
≥40	33	97.0
职业
农民	32	94.1
工人	1	2.9
学生	1	2.9
文化程度
文盲或半文盲	12	34.3
小学	12	34.3
初中	9	25.7
高中、中专	1	2.9
大学及以上	0	0
蔬菜摄入量（g）
<300	4	11.8
300~500	21	61.8
>500	9	26.5
奶制品摄入量（g）
<300	20	58.8
300~500	10	29.4
>500	4	11.8
肉制品摄入量（g）
<120	10	29.4
120~200	4	11.8
>200	20	58.8

组别	Shannon	Chao1	Observed species	PD whole tree
PDV1	5.77±0.79	744.05±230.86	666.25±203.95	34.16±8.73
PDV2	5.02±1.02	621.38±207.74	555.95±188.33	29.56±8.26
PDV3	5.67±1.24	769.33±262.24	688.75±233.29	35.50±9.87

组别	Shannon	Chao1	Observed species	PD whole tree
PDD1	5.88±0.67	728.90±194.37	659.00±180.85	33.59±8.02
PDD2	5.48±0.89	699.93±197.59	624.70±171.05	32.54±7.24
PDD3	5.05±1.12	640.20±243.75	572.47±220.52	30.33±9.64

组别	Shannon	Chao1	Observed species	PD whole tree
PDM1	5.26±0.98	663.09±212.26	591.39±190.01	31.15±8.38
PDM2	5.15±0.87	606.33±221.33	544.60±200.72	29.31±7.82
PDM3	5.39±1.27	711.16±252.53	639.20±227.12	32.87±10.04