文章摘要
杨金龙,于相冰,胡晓梦,贺楚晗,梁箫.人工鱼礁表面分离细菌形成单一生物被膜对厚壳贻贝稚贝附着的影响.渔业科学进展,2024,45(3):224-234
人工鱼礁表面分离细菌形成单一生物被膜对厚壳贻贝稚贝附着的影响
The effect of mono-species bacterial biofilms formed on the surface of artificial reef on settlement of plantigrades in Mytilus coruscus
投稿时间:2023-01-29  修订日期:2023-02-19
DOI:10.19663/j.issn2095-9869.20230129001
中文关键词: 人工鱼礁  厚壳贻贝  稚贝  附着  生物被膜
英文关键词: Artificial reef  Mytilus coruscus  Mussel juvenile  Settlement  Biofilm
基金项目:
作者单位
杨金龙 上海海洋大学 国家海洋生物科学国际联合研究中心 上海 201306上海市水产动物良种创制 与绿色养殖协同创新中心 上海 201306南方海洋科学与工程广东省实验室(广州) 广东 广州 511458 
于相冰 上海海洋大学 国家海洋生物科学国际联合研究中心 上海 201306上海市水产动物良种创制 与绿色养殖协同创新中心 上海 201306 
胡晓梦 上海海洋大学 国家海洋生物科学国际联合研究中心 上海 201306上海市水产动物良种创制 与绿色养殖协同创新中心 上海 201307 
贺楚晗 上海海洋大学 国家海洋生物科学国际联合研究中心 上海 201306上海市水产动物良种创制 与绿色养殖协同创新中心 上海 201308 
梁箫 上海海洋大学 国家海洋生物科学国际联合研究中心 上海 201306上海市水产动物良种创制 与绿色养殖协同创新中心 上海 201309 
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中文摘要:
      为探讨存在于人工鱼礁表面的海洋细菌与贝类附着之间的互作关系,本研究从自然海域中的人工鱼礁表面上分离了9株海洋细菌,并分别构建单一细菌生物被膜,探索不同细菌种属形成的生物被膜特性与厚壳贻贝(Mytilus coruscus)稚贝附着之间的关系。结果显示,9株人工鱼礁表面细菌形成的生物被膜对厚壳贻贝稚贝附着的诱导活性存在显著差异,其中,Mesoflavibacter sp.2对稚贝附着的诱导活性最高,Phaeobacter sp.2的诱导活性最低。Sutcliffiella sp.1和Jeotgalibacillus sp.1的细菌密度与诱导活性呈显著正相关,Cytobacillus sp.1和Phaeobacter sp.2的细菌密度与诱导活性呈显著负相关。通过比较分析Mesoflavibacter sp.2和Phaeobacter sp.2生物被膜的蛋白质及多糖含量发现,生物被膜对厚壳贻贝稚贝附着的诱导活性与多糖含量呈显著负相关,与蛋白质含量呈正相关。本研究初步探索了人工鱼礁表面细菌形成的生物被膜对厚壳贻贝稚贝附着的影响,为后续在自然海区进一步解析人工鱼礁表面生物被膜与海洋无脊椎动物附着的互作关系具有重要理论研究意义,同时,对于人工鱼礁表面海洋生物附着机制的研究具有重要的实践价值。
英文摘要:
      Aquaculture is the fastest growing food production industry. The Chinese mariculture industry has made great progress in the past 40 years to become the dominant producer of aquaculture. However, the current deterioration of the water environment and the aggravation of farming diseases poses challenges for the traditional culture model to meet the new requirements of healthy development in marine fishery resources. This problem was addressed using marine ranching. This is a new mariculture model that includes two approaches (artificial reefs and stocking) with the goal of achieving environmental and ecological harmony. Artificial reefs are an important component of this marine ranching model since they can help improve the water environment around the reefs, promote nutrient circulation, provide a suitable habitat for marine organisms, and encourage colonization of the reef surface by sessile organisms. The placement of artificial reefs into seawater may serve as a substrate for bacteria to form a biofilm on the surface. Biofilms play a crucial role in the settlement of many marine invertebrate species. However, limited research was conducted into the relationship between bacteria on the surface of artificial reefs, biofilm formation, and the settlement behavior of Mytilus coruscus. This study placed white acrylic plates and tetrahedral structured artificial reefs in Gouqi Island, Zhoushan City, Zhejiang Province, China (122°46′ E; 30°43′ N) . Nine strains of bacteria isolated from the surface of the artificial reefs were used to construct mono-species bacterial biofilms and induce plantigrade settlement of M. coruscus. The aim of the study was to investigate the interactions between marine bacteria and the settlement of M. coruscus on the surface of artificial reefs. The marine biofilms impacted the settlement process of M. coruscus. The bacterial species from the marine biofilm were screened for high and low inducing activity and analyzed for bacterial density, protein, and polysaccharide content to further explore the relationship between different bacterial biofilms and M. coruscus settlement. There were significant differences in the induction activity of biofilms formed by the nine strains of artificial reef bacteria on the settlement of M. coruscus: Mesoflavibacter sp.2 and Phaeobacter sp.2 showed the highest and lowest induction activity, respectively. Bacteria within the same genus exhibited differences in induction activity. This indicated that the induction activity of bacterial biofilms on mussel settlement was independent of bacterial species. Phylogenetic analysis showed that genetically similar strains (such as Pseudoalteromonas sp.31 and Pseudoalteromonas sp.32) and genetically distant strains (such as Mesoflavibacter sp.2 and Jeotgalibacillus sp.1) showed significant differences in the induction activity of M. coruscus settlement. Only four of the nine bacterial strains showed significant correlation between biofilm density and the settlement rate. Sutcliffiella sp.1 and Jeotgalibacillus sp.1 exhibited a positive correlation between bacterial density and induction activity. This indicated that bacterial density may play a role in M. coruscus settlement, although it may be strain specific. Additionally, the trend of induction activity of mussel larvae attachment varied with increasing initial bacterial density. The optimal density for settlement is strain specific. Further analysis of biofilm active substance content in Mesoflavibacter sp.2 and Phaeobacter sp.2 revealed that polysaccharide content negatively correlated with induction activity of M. coruscus and positively correlated with protein content. This suggests that bacterial species may not directly affect M. coruscus settlement, although bacteria may indirectly influence settlement by affecting the secretion of extracellular products. This study showed that nine bacterial strains had significant differences in their ability to induce mussel settlement on the surface of artificial reefs. Interestingly, these differences did not necessarily correlate with the genetic distance between the marine bacteria. Further investigations were conducted on two selected strains of bacteria (Mesoflavibacter sp.2 and Phaeobacter sp.) that exhibited different levels of inductive activity on M. coruscus. The polysaccharide content and protein content negatively and positively correlated with the induction activity of M. coruscus, respectively. This suggests that the presence of specific polysaccharides may negatively affect the settlement of M. coruscus according to cellulose content measurements. This is the first study investigating the effect of bacteria on M. coruscus settlement on the surface of artificial reefs. This has significant theoretical implications for further research on the interactions between biofilms and marine invertebrates on the surface of artificial reefs in natural marine environments. Understanding the settlement mechanisms of marine benthic organisms on artificial reefs is crucial to manage and conserve marine resources since artificial reefs are widely used to enhance marine habitat and biodiversity. The findings of this study have practical implications for the design and construction of artificial reefs. Understanding the role of bacteria in mussel settlement facilitates the optimization of artificial reef structures to promote or inhibit the settlement of target species. This knowledge can help develop effective strategies to manage biofouling on artificial reefs. This can impact the performance and longevity of these structures. Further research in this field will deepen our understanding of the underlying mechanisms and enable development of management strategies for artificial reefs and marine conservation efforts.
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