酶制剂和菌制剂对香螺稚螺生长及肠道菌群的影响

Effects of enzyme preparations and microbial preparations on the growth and gut microbiota of juvenile Neptunea cumingii

  • 摘要:
    目的 对比不同添加剂型人工饲料与天然饵料(缢蛏)对香螺稚螺生长、消化酶活性、营养组成及肠道菌群结构的影响。
    方法 实验设置天然贝类饵料缢蛏组(A组)和添加胃蛋白酶(B组)、枯草芽孢杆菌(C组)及乳酸菌(D组)的人工配合饲料组饲养香螺稚螺,实验进行9周。
    结果 从生长水平来看,A组香螺稚螺的特定生长率最高,其终末体重、壳高及壳宽均显著高于其他3组。C组的存活率高于A组,且在3组实验组中,C组的生长性能表现为最佳。消化酶活性方面,A组脂肪酶活性最高,C组胃蛋白酶和淀粉酶活性最高。肠道菌群α多样性显示,A组Ace指数和Chao1指数最高,C组Shannon指数最高,D组Simpson指数最高。不同投喂组香螺稚螺肠道菌群中的OTU数量由多到少依次为A组、C组、D组、B组,4组稚螺肠道样本共有的OTU数量较少。
    结论 尽管天然贝类饵料(缢蛏)促进香螺稚螺的生长效果最佳,但添加枯草芽孢杆菌的人工饲料在提高稚螺存活率、增强胃蛋白酶与淀粉酶活性以及显著调节肠道菌群结构方面展现出相对优势。香螺目前的人工养殖技术尚处于起步阶段,制约其发展的其中一大难题是尚未研制出适合稚螺的人工饲料。本研究可以为研发满足香螺稚螺营养需求的人工配合饲料提供一定的依据,为香螺养殖业提供了新的饲料选择思路。

     

    Abstract: Neptunea cumingii, a carnivorous snail renowned for its high economic value and rich nutritional content, has long been a favorite among consumers. However, the rampant overfishing of this species has caused a dramatic decline in its natural population, thereby disrupting the ecological balance of marine ecosystems. Under such circumstances, the development of artificial breeding techniques has become an urgent necessity, as it not only helps meet the market demand but also eases the pressure on wild fisheries. Currently, the artificial breeding technology for N. cumingii remains in its early stages, with the low survival rate of juvenile snails being a major bottleneck restricting its development. A critical issue is the lack of an artificial compound feed that can fully meet the nutritional requirements of juvenile snails. To address this, this study compared the effects of different additive types of artificial feed and natural feed (Sinonovacula constricta) on the growth, digestive enzyme activity, nutritional composition, and gut microbiota structure of juvenile N. cumingii.. The experiment was designed with four groups: Group A, which was fed natural shellfish bait S. constricta; Group B, which was given an artificial compound feed supplemented with pepsin; Group C, where the artificial compound feed was added with Bacillus subtilis; and Group D, which received the artificial compound feed containing Lactobacillus plantarum. After a 9-week breeding period, the results revealed that the juvenile snails in Group A exhibited the fastest growth rate, while Group C showed the best performance in terms of both growth and survival rate. In terms of digestive enzyme activities, Group A had the highest lipase activity (P<0.05), whereas Group C recorded the highest pepsin and amylase activities (P<0.05). Regarding the α-diversity of the intestinal flora, Group A had the highest Ace and Chao1 indices, Group C had the highest Shannon index, and Group D had the highest Simpson index. The number of OTUs in the gut microbiota of juvenile snails across different feeding groups, from highest to lowest was as follows: group A, group C, group D, and group B. The number of OTUs common to all four groups of juvenile snail gut samples was relatively low. Overall, although natural shellfish feed promotes the best growth of juvenile N. cumingii, artificial feed supplemented with Bacillus subtilis demonstrated relative advantages in improving survival rates, enhancing pepsin and amylase activity, and significantly regulating gut microbiota structure. Current artificial cultivation techniques for N. cumingii remain in their infancy, with one major constraint being the lack of suitable artificial feed for juveniles. This study provides a foundation for developing compound artificial feed that meets the nutritional requirements of juvenile N. cumingii, offering new feed selection approaches for the aquaculture industry.

     

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