Correlation between the gut bacteria and host physiological indices of Cyprinidae fish species in the Nanhai Wetland of Baotou City

doi:10.17520/biods.2025131

Abstract

Abstract:

Aims: This study investigated the gut bacterial community structure and diversity of six economically important cyprinid species (Hypophthalmichthys molitrix, Parabramis pekinensis, Aristichthys nobilis, Culter alburnus, Carassius auratus, Megalobrama amlycephala) in the Nanhai Wetland of Baotou, and explored their correlations with host growth performance, antioxidant capacity, and feeding ecology, to provide a theoretical basis for healthy aquaculture and disease prevention.

Methods: High-throughput sequencing technology was employed to systematically analyze the gut bacteria across six cyprinid fish species. Additionally, we investigated their correlations with host growth performance, antioxidant capacity, and dietary niche type. Key methods included α diversity analysis, β diversity analysis, and community composition analysis. Linear discriminant analysis effect size (LEfSe) was employed to identify significantly differentially abundant microbial taxa across groups. Correlation analysis was conducted using redundancy analysis (RDA) and Spearman correlation heatmaps.

Results: A total of 1,051,137 valid sequences were obtained, which were divided into 11,164 operational taxonomic units (OTUs). Based on the minimum number of reads (45,813) of all samples, 11,108 OTUs were retained for subsequent statistical analysis, among which these OTUs belonged to 37 phyla and 1,005 genera. Microbial community composition analysis revealed that all six Cyprinidae fish species shared a core gut microbiota, with Pseudomonadota, Fusobacteriota, and Actinomycetota identified as the dominant phyla, while Cetobacteriumand Rothia emerged as the dominant genera. The results suggested that Cyprinidae fish shared a core gut microbiota, which was likely functionally conserved in processes such as short-chain fatty acid production, vitamin synthesis, and energy metabolism. Nevertheless, significant interspecific divergence was detected. There were significant differences among the gut bacterial structure of the six cyprinid fish species using the methods of principal coordinates analysis (PCoA) and permutational multivariate analysis of variance (PERMANOVA), indicating species-specific characteristics, meaning that the gut bacterial communities of different fish species possess unique compositional features. At the phylum level, LEfSe analysis identified significant enrichment of Cyanobacteriota in Hypophthalmichthys molitrix, consistent with its filter-feeding ecological habit in the upper water layer, reflecting host adaptation to specific food sources. At the genus level, 20 significantly differential bacterial genera were identified, such as Methylobacterium_Methylorubrum, Synechocystis_PCC_6803, and Cyanobium_PCC_6307 in Hypophthalmichthys molitrix; Plesiomonas in Aristichthys nobilis; and Candidatus_Competibacter in Carassius auratus, all of which were closely associated with host ecological habits. Moreover, the gut bacterial community structure significantly correlated with host growth performance, antioxidant indicators, and dietary niche type using correlation analysis. Specifically, growth-related parameters including condition factor (R² = 0.731, P= 0.001), sex (R² = 0.595, P= 0.002), age (R²= 0.530, P= 0.003), and viscerosomatic index (R²= 0.453, P= 0.013) sequentially exerted significant effects on gut bacterial structure, with four key bacterial genera (e.g., Sphingomonas, Algoriphagus, Acinetobacter, and unclassified_Cyanobacteriales) identified as critical correlates. In terms of antioxidant capacity, 2,2-Diphenyl-1-picrylhydrazyl (DPPH) radical scavenging activity (R² = 0.700, P= 0.001) and H₂O₂ content (R²= 0.690, P= 0.001) were the primary determinants of microbial community composition, linked to ten functional genera (e.g., Vibrio, Aeromonas, and Plesiomonas). Meanwhile, six bacterial genera (e.g., Marivivens, Acinetobacter, and Candidatus_Competibacter) were identified as significantly associated with distinct feeding niches.

Conclusion: The results demonstrated that Cyprinidae fish shared a core gut microbiota, which exhibited functional conservation in fundamental metabolic processes, while species-specific bacteria synergistically regulated host nutrient metabolism, oxidative stress responses, and growth-related physiological processes to enhance their adaptation to specific environmental conditions. These findings provide a scientific experimental basis for wetland fish resource management and precision fish farming.

Key words: Cyprinidae, gut microbiota, growth performance, antioxidant capacity, dietary niche type

Lili Wang, Zhen Li, Yuping Yang, Li Liu, Li Gao. Correlation between the gut bacteria and host physiological indices of Cyprinidae fish species in the Nanhai Wetland of Baotou City[J]. Biodiv Sci, 2025, 33(11): 25131.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2025131

https://www.biodiversity-science.net/EN/Y2025/V33/I11/25131

Figures/Tables 8

References 39

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编号 Code	物种名 Species name	分类地位 Taxonomy	食性生态类型 Dietary niche type	参考文献 References
LY1-LY3	鲢 Hypophthalmichthys molitrix	鲢属 Hypophthalmichthys	滤食性(浮游植物) Filter-feeding (phytoplankton)	赵志刚, 2011
BY1-BY3	鳊 Parabramis pekinensis	鳊属 Parabramis	草食性 Herbivory	宋文, 2016
YY1-YY3	鳙 Aristichthys nobilis	鳙属 Aristichthys	滤食性(浮游动物) Filter-feeding (zooplankton)	赵志刚, 2011
QZB1-QZB3	翘嘴鲌 Culter alburnus	鲌属 Culter	肉食性 Carnivory	王伟, 2007
JY1-JY3	鲫 Carassius auratus	鲫属 Carassius	杂食性 Omnivory	黄业辉, 2020^②(②黄业辉 (2020) 鲫(Carassius auratus)对浅水水体水质的影响: 中型系统实验. 硕士学位论文, 暨南大学, 广州.)
TTF1-TTF3	团头鲂 Megalobrama amblycephala	鲂属 Megalobrama	草食性 Herbivory	宋文, 2016

编号 Code	物种名 Species name	分类地位 Taxonomy	食性生态类型 Dietary niche type	参考文献 References
LY1-LY3	鲢 Hypophthalmichthys molitrix	鲢属 Hypophthalmichthys	滤食性(浮游植物) Filter-feeding (phytoplankton)	赵志刚, 2011
BY1-BY3	鳊 Parabramis pekinensis	鳊属 Parabramis	草食性 Herbivory	宋文, 2016
YY1-YY3	鳙 Aristichthys nobilis	鳙属 Aristichthys	滤食性(浮游动物) Filter-feeding (zooplankton)	赵志刚, 2011
QZB1-QZB3	翘嘴鲌 Culter alburnus	鲌属 Culter	肉食性 Carnivory	王伟, 2007
JY1-JY3	鲫 Carassius auratus	鲫属 Carassius	杂食性 Omnivory	黄业辉, 2020^②(②黄业辉 (2020) 鲫(Carassius auratus)对浅水水体水质的影响: 中型系统实验. 硕士学位论文, 暨南大学, 广州.)
TTF1-TTF3	团头鲂 Megalobrama amblycephala	鲂属 Megalobrama	草食性 Herbivory	宋文, 2016

编号 Code	全长 Total length (mm)	体长 Body length (mm)	体质量 Body mass (g)	内脏质量 Viscera mass (g)	脏体比 Viscerosomatic index (VSI, %)	肥满度 Condition factor (CF, %)	年龄 Age	性别 Sex		性腺发育期 Gonad stage						肠管充塞度 Intestine fullness
编号 Code	全长 Total length (mm)	体长 Body length (mm)	体质量 Body mass (g)	内脏质量 Viscera mass (g)	脏体比 Viscerosomatic index (VSI, %)	肥满度 Condition factor (CF, %)	年龄 Age	♂	♀	I	II	III	IV	V	VI	0	I	III	III	IV	V
LY1	390	331	570	40	7.02	1.57	1	1			1										1
LY2	453	378	790	50	6.33	1.46	2		1			1								1
LY3	420	350	710	90	12.68	1.66	3	1		1										1
BY1	269	218	180	10	5.56	1.74	1		1			1						1
BY2	240	196	120	10	8.33	1.59	1		1		1									1
BY3	247	205	100	30	30.00	1.16	1		1			1							1
YY1	601	515	2,690	270	10.04	1.97	3	1				1								1
YY2	450	379	990	80	8.08	1.82	2	1				1									1
YY3	451	359	820	50	6.10	1.77	1	1			1									1
JY1	200	163	110	10	9.09	2.54	4	1				1								1
JY2	160	125	50	20	40.00	2.56	3		1			1						1
JY3	110	90	20	5	25.00	2.74	3		1			1						1
QZB1	340	290	260	50	19.23	1.07	1		1					1					1
QZB2	246	200	140	10	7.14	1.75	2	1				1						1
QZB3	208	182	70	10	14.29	1.16	1		1					1				1
TTF1	336	275	360	50	13.89	1.73	4		1					1					1
TTF2	116	98	250	40	16.00	1.64	3		1					1					1
TTF3	283	236	210	20	9.52	1.60	2	1				1						1

编号 Code	全长 Total length (mm)	体长 Body length (mm)	体质量 Body mass (g)	内脏质量 Viscera mass (g)	脏体比 Viscerosomatic index (VSI, %)	肥满度 Condition factor (CF, %)	年龄 Age	性别 Sex		性腺发育期 Gonad stage						肠管充塞度 Intestine fullness
编号 Code	全长 Total length (mm)	体长 Body length (mm)	体质量 Body mass (g)	内脏质量 Viscera mass (g)	脏体比 Viscerosomatic index (VSI, %)	肥满度 Condition factor (CF, %)	年龄 Age	♂	♀	I	II	III	IV	V	VI	0	I	III	III	IV	V
LY1	390	331	570	40	7.02	1.57	1	1			1										1
LY2	453	378	790	50	6.33	1.46	2		1			1								1
LY3	420	350	710	90	12.68	1.66	3	1		1										1
BY1	269	218	180	10	5.56	1.74	1		1			1						1
BY2	240	196	120	10	8.33	1.59	1		1		1									1
BY3	247	205	100	30	30.00	1.16	1		1			1							1
YY1	601	515	2,690	270	10.04	1.97	3	1				1								1
YY2	450	379	990	80	8.08	1.82	2	1				1									1
YY3	451	359	820	50	6.10	1.77	1	1			1									1
JY1	200	163	110	10	9.09	2.54	4	1				1								1
JY2	160	125	50	20	40.00	2.56	3		1			1						1
JY3	110	90	20	5	25.00	2.74	3		1			1						1
QZB1	340	290	260	50	19.23	1.07	1		1					1					1
QZB2	246	200	140	10	7.14	1.75	2	1				1						1
QZB3	208	182	70	10	14.29	1.16	1		1					1				1
TTF1	336	275	360	50	13.89	1.73	4		1					1					1
TTF2	116	98	250	40	16.00	1.64	3		1					1					1
TTF3	283	236	210	20	9.52	1.60	2	1				1						1

组别 Groups	属名 Genera	LY (%)	BY (%)	YY (%)	JY (%)	QZB (%)	TTF (%)	参考文献 References
具潜在有益功能的属 Genera with potential beneficial functions	鲸杆菌属 Cetobacterium	22.11	18.13	13.09	7.30	27.12	17.13	Wang et al, 2021
	拟杆菌属 Bacteroides	1.94	1.29	4.57	2.40	1.52	4.47	Wang et al, 2022
	芽孢杆菌属 Bacillus	0.09	0.35	0.19	0.14	0.23	0.52	张宇柔等, 2022
	阿克曼菌属 Akkermansia	0.15	0.10	0.25	0.09	0.04	0.26	Wang et al, 2024
	乳酸菌属 Lacticaseibacillus	0.10	0.07	0.21	0.12	0.09	0.13	李鹏飞等, 2024
	总计 Total	24.39	19.95	18.30	10.05	29.01	22.52
包含致病菌种的属 Genera containing pathogenic species	弧菌属 Vibrio	0.02	0.42	12.67	0.00	4.49	1.64	Roh, 2022
	气单胞菌属 Aeromonas	0.00	0.00	2.52	0.00	11.75	0.05	Semwal et al, 2023
	葡萄球菌属 Staphylococcus	1.13	1.69	2.50	1.78	1.04	2.78	Hussein et al, 2019
	梭杆菌属 Fusobacterium	0.49	1.07	1.92	1.20	0.31	2.67	孟晓林等, 2019
	邻单胞菌属 Plesiomonas	0.00	0.00	3.99	0.00	0.15	0.00	陈美群等, 2020
	脱硫杆菌属 Desulfobacca	0.72	0.56	0.01	1.09	1.07	0.06	黄国鑫等, 2022
	不动杆菌属 Acinetobacter	0.18	1.31	0.23	0.22	0.42	0.86	Zhou et al, 2019
	嗜麦芽窄食单胞菌属 Stenotrophomonas	0.42	0.35	0.52	0.41	0.20	0.75	Abraham et al, 2016
	大肠杆菌-志贺氏菌属 Escherichia-Shigella	0.21	0.38	0.32	0.32	0.14	0.46	Sun et al, 2019
	假单胞菌属 Pseudomonas	0.07	0.30	0.12	0.13	0.07	0.13	周琳, 2015^①(① 周琳 (2015) 大黄鱼源变形假单胞菌的致病性研究. 硕士学位论文, 集美大学, 福建厦门.)
	黄杆菌属 Flavobacterium	0.09	0.19	0.02	0.11	0.11	0.22	柴静茹等, 2021
	链球菌属 Streptococcus	0.12	0.19	0.27	0.28	0.25	0.17	He et al, 2021
	微囊藻属 Microcystis	2.02	0.42	0.00	0.03	0.11	0.11	毕相东, 2021
	希瓦氏菌属 Shewanella	0.10	1.61	0.01	0.00	0.83	0.04	叶明皓等, 2018
	总计 Total	5.57	8.49	25.09	5.57	20.96	9.93