辽东湾饵料微藻粒级区划研究

doi:10.16378/j.cnki.1003-1111.20217

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摘要采用高通量测序—分子鉴定分级技术,研究辽东湾海域微藻粒级结构。研究结果显示,辽东湾4个季节主要以小粒级微藻为主,优势种为抑食金球藻、细小微胞藻、微拟球藻属、葡萄藻属。春、夏、秋、冬季小粒级微藻生物量占比分别高达(51±14)%、(43±14)%、(49±6)%、(42±4)%,中粒级微藻生物量占比分别为(29±7)%、(34±15)%、(24±5)%、(42±4)%,大粒级微藻生物量占比分别为(21±10)%、(23±13)%、(27±3)%、(17±4)%。辽东湾微藻饵料供饵力主要为春、夏季贡献,春季供饵力较高区域主要分布在辽东湾顶部及中部,夏季主要分布在辽东湾东南侧和西侧海域。辽东湾整个海域实际可承载贝类养殖容量:春季为155 g/m²、夏季为203 g/m²、秋季为48 g/m²、冬季为33 g/m²。本研究结果可为滤食性贝类科学增养殖提供技术指导。

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	刘苏萱
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	董少杰

关键词 ：贝类饵料, 粒级结构, 高通量测序—分子鉴定分级技术, 辽东湾

Abstract：The feeding power of microalgae food in Liaodong Bay was studied by high-throughput sequencing-molecular identification and grading technique. The results showed that small-sized microalgae dominated Liaodong Bay in four seasons, with the dominant species of Aureococcus anophagefferens, Microcystis pusilla, Nannochloris sp. and Botrytis sp.. In spring, summer, autumn and winter, the biomass of microalgae of small size was as high as (51±14)%, (43±14)%, (49±6)% and (42±4)%, the biomass of medium size was (29±7)%, (34±15)%, (24±5)% and (42±4)%, and the biomass of large size was (21±10)%, (23±13)%, (27±3)% and (17±4)%, respectively. The feeding power of microalgae in Liaodong Bay was mainly contributed by spring and summer. The areas with higher feeding power in spring were mainly distributed in the upper and middle of Liaodong Bay, while in summer they were mainly distributed in the southeast and west waters of Liaodong Bay. The actual carrying capacity of shellfish in Liaodong Bay was 155 g/m² in spring, 203 g/m² in summer, 48 g/m² in autumn and 33 g/m² in winter. The finding can provide technical guidance for scientific culture and multiplication of filter-feeding shellfish.

Key words： shellfish food size fraction high-throughput sequencing-molecular identification and grading technique Liaodong Bay

收稿日期: 2020-09-30

PACS:

S917.3

基金资助:辽宁省兴辽英才计划项目(XLYC1907109);辽宁省重点研发计划项目(2018228004);辽宁省海洋与渔业科研项目(201828,201824);天津市重点研发计划项目(19YFZCSN00070);大连市杰出青年科技人才项目(2019RJ09).

通讯作者: 宋伦(1980—),男,研究员,博士;研究方向:海洋生态. E-mail:songlun2019@qq.com.

作者简介: 刘苏萱(1998—),女,硕士研究生;研究方向:渔业环境. E-mail:lsx94135413@163.com.

引用本文:

刘苏萱, 宋伦, 胡超魁, 王昆, 刘印, 张明亮, 董少杰. 辽东湾饵料微藻粒级区划研究[J]. 水产科学, 2022, 41(4): 645-651.
LIU Suxuan, SONG Lun, HU Chaokui, WANG Kun, LIU Yin, ZHANG Mingliang, DONG Shaojie. Microalgal Size Gradation of Food in Liaodong Bay. 水产科学, 2022, 41(4): 645-651.

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http://www.shchkx.com/CN/10.16378/j.cnki.1003-1111.20217 或 http://www.shchkx.com/CN/Y2022/V41/I4/645

[1]古彬.秦皇岛扇贝养殖区抑食金球藻褐潮分子生态学研究[D].青岛:中国海洋大学,2014:1-6.
[2]宋伦,吴景,宋永刚,等.褐潮致灾种抑食金球藻在辽东湾的分布[J].环境科学研究,2017,30(4):537-544.
[3]董波,薛钦昭,李军.滤食性贝类摄食生理的研究进展[J].海洋科学,2000,24(7):31-34.
[4]李凤雪.规模化贝类养殖海域浮游植物的粒径结构及微食物环的生态贡献[D].上海:上海海洋大学,2019:53-54.
[5]宋伦,毕相东,宋广军,等.海洋真核微藻粒级结构及其环境影响因素[J].中国环境科学,2020,40(6):2627-2634.
[6]孙军,刘东艳,钟华,等.浮游植物粒级研究方法的比较[J].青岛海洋大学学报(自然科学版),2003,33(6):917-924.
[7]SONG L, WU J, DU J, et al. Comparison of two methods to assess the size structure of phytoplankton community assemblages, in Liaodong bay, China[J].Journal of Ocean University of China,2019,18(5):1207-1215.
[8]宫瑗,姜雪薇,钟明燕,等.以莱州湾海域扇贝养殖为例探讨影响扇贝养殖容量的因素[J].水产养殖,2020,41(7):6-9.
[9]张继红,蔺凡,方建光.海水养殖容量评估方法及在养殖管理上的应用[J].中国工程科学,2016,18(3):85-89.
[10]刘学海,王宗灵,张明亮,等.基于生态模型估算胶州湾菲律宾蛤仔养殖容量[J].水产科学,2015,34(12):733-740.
[11]梁艺.獐子岛海域贝类养殖与营养盐限制的关系研究[D].青岛:中国科学院大学(中国科学院海洋研究所),2019:83-85.
[12]中华人民共和国国家质量监督检验检疫总局,中国国家标准化管理委员会.GB/T 12763.1—2007,海洋调查规范第1部分总则 [S].北京:中国标准出版社,2008.
[13]中华人民共和国国家质量监督检验检疫总局,中国国家标准化管理委员会.GB 17378.3—2007,海洋监测规范第3部分样品采集、贮存与运输 [S].北京:中国标准出版社,2008.
[14]QUAST C, PRUESSE E, YILMAZ P, et al. The SILVA ribosomal RNA gene database project:improved data processing and web-based tools[J].Nucleic Acids Research,2013,41(D1):D590-D596.
[15]ZHU F, MASSANA R, NOT F, et al. Mapping of picoeucaryotes in marine ecosystems with quantitative PCR of the 18S rRNA gene[J].FEMS Microbiology Ecology,2005,52(1):79-92.
[16]PROKOPOWICH C D, GREGORY T R, CREASE T J. The correlation between rDNA copy number and genome size in eukaryotes[J].Genome,2003,46(1):48-50.
[17]GODHE A, ASPLUND M E, HÄRNSTRM K, et al. Quantification of diatom and dinoflagellate biomasses in coastal marine seawater samples by real-time PCR[J].Applied and Environmental Microbiology,2008,74(23):7174-7182.
[18]刘瑞玉.中国海洋生物名录[M].北京:科学出版社,2008:301-870.
[19]XU X, YU Z M, CHENG F J, et al. Molecular diversity and ecological characteristics of the eukaryotic phytoplankton community in the coastal waters of the Bohai Sea, China[J].Harmful Algae,2017,61:13-22.
[20]于杰.浮游生物多样性高效检测技术的建立及其在渤海褐潮研究中的应用[D].青岛:中国海洋大学,2014:29-32.
[21]江雪娇.北黄海微微型浮游植物的丰度及微微型真核浮游生物分子多样性研究[D].青岛:中国海洋大学,2009:42-44.
[22]PARSONS T R, TAKAHASHII M. Biological oceanographi processes[M]. New York: Pergamon Press,1973:186.
[23]宋广军,张雪,宋伦,等.鸭绿江口浅海海域菲律宾蛤仔养殖容量估算[J].水产科学,2013,32(1):36-40.
[24]董波,薛钦昭,李军.环境因子对菲律宾蛤仔摄食生理生态的影响[J].海洋与湖沼,2000,31(6):636-642.
[25]SONG L, WU J, DU J, et al. The characteristics and distribution of eukaryotic phytoplankton community in Liaodong bay, China[J].Ocean Science Journal,2019,54(2):183-203.
[26]宋伦,吴景,刘卫东,等.渤海长兴岛海域微型和微微型浮游植物多样性[J].环境科学研究,2016,29(11):1635-1642.
[27]刘印,宋伦,刘苏萱.海洋微藻小粒级化趋势的环境驱动机制浅析[J/OL].水产科学:1-10.(2021-07-26)[2021-08-01].https://navi.cnki.net/knavi/iournais/CHAN/detail.doi.o:10.16378/j.cnki.1003-1111.20290.
[28]苟万里,李自英,武心华,等.混合无机氮源下6株微藻对亚硝态氮、氨氮净化规律初探[J].水产科学,2020,39(5):685-693.
[29]宋伦,吴景,宋广军,等.基于环境DNA技术的辽东湾真核微藻群落结构特征[J].生态学报,2020,40(17):6243-6257.
[30]张建乐,王全颖,张永丰,等.秦皇岛海域褐潮生消过程中营养盐特征[J].应用生态学报,2020,31(1):282-292.
[31]宋伦,吴景,李楠,等.辽东湾潜在褐潮生物时空分布及环境关联[J].中国环境科学,2018,38(8):3060-3071.
[32]张雪,宋伦,付杰,等.黄海北部滤食性贝类供饵力区划研究[J].水产科学,2021,40(3):416-421.