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青海湖裸鲤自主摄食节律与生长特性研究
卫宇星,么宗利,来琦芳,祁洪芳,戴阳,高鹏程,杨建新,周凯,孙真,李燕
1.上海海洋大学 水产科学国家级实验教学示范中心 上海 201306;2.中国水产科学研究院东海水产研究所 农业农村部低洼盐碱地水产养殖重点实验室 中国水产科学研究院盐碱水域渔业工程技术研究中心(上海) 上海 200090;3.青海湖裸鲤救护中心 青海 西宁 810016;4.中国水产科学研究院东海水产研究所 农业农村部低洼盐碱地水产养殖重点实验室 中国水产科学研究院盐碱水域渔业工程技术研究中心(上海) 上海 200091;5.中国水产科学研究院东海水产研究所 农业农村部低洼盐碱地水产养殖重点实验室 中国水产科学研究院盐碱水域渔业工程技术研究中心(上海) 上海 200092
摘要:
为探究盐碱环境中鱼类的摄食和生长特性,为耐盐碱鱼类增殖保护和盐碱水养殖提供基础数据,本研究以青海湖裸鲤(Gymnocypris przewalskii)为代表,研究其在盐碱水(青海湖湖水)环境中的自主摄食节律,设置自然光照(14L:10D)湖水组和全黑暗(24D)湖水组,以自然光照(14L:10D)淡水组为对照。结果显示,青海湖裸鲤为白昼摄食类型鱼类。在自然光照条件下,淡水环境中,青海湖裸鲤的摄食高峰期为08:00—11:00,摄食低谷期则为05:00—08:00;湖水环境中,青海湖裸鲤在08:00—19:00呈现较高且持续的摄食现象,其平均每小时摄食量显著高于05:00—08:00和19:00—05:00时段。而在全暗环境中,青海湖裸鲤摄食的节律性减弱,各时段的平均每小时摄食量较为接近。经63 d的自主摄食养殖,在自然光照下,湖水组的青海湖裸鲤在高盐碱环境中的体长增长率为(1.19±0.17)%、体重增长率为(10.66±0.98)%、特定生长率为(0.16±0.02)%/d,均分别显著低于淡水组青海湖裸鲤的体长增长率[(18.66±0.41)%]、体重增长率[(67.32±3.05)%]和特定生长率[(0.82±0.03)%/d],表明生长受到抑制。湖水组和淡水组青海湖裸鲤的体长–体重关系参数(b)均小于3,表明青海湖裸鲤为负异速生长鱼类,其中,湖水组b值小于淡水组,即湖水组体重增长速率低于淡水组,在一定程度上说明高盐碱环境导致青海湖裸鲤的生长特性发生变化。本研究通过探寻青海湖裸鲤在青海湖水环境以及淡水人工养殖中的摄食节律及生长规律,为青海湖裸鲤人工增殖投喂策略的制定提供理论依据,同时,为盐碱生境中鱼类的摄食习性研究提供基础数据。
关键词:  盐碱环境  青海湖裸鲤  自主摄食节律  生长特性
DOI:10.19663/j.issn2095-9869.20221211001
分类号:
基金项目:
Self feeding rhythm and growth characteristics of Gymnocypris przewalskii
WEI Yuxing1,2,3,4, YAO Zongli5,2,6, LAI Qifang7,2,8, QI Hongfang9, DAI Yang2,3, GAO Pengcheng2,3, YANG Jianxin9, ZHOU Kai2,3, SUN Zhen2,3, LI Yan2,3
1.National Demonstration Center for Experimental Fisheries Science Education, Shanghai Ocean University, Shanghai 201306, China;2.East China Sea Fisheries Research Institute, Chinese Academy of Fishery Sciences;3.Key Laboratory of Inland Saline-Alkaline Aquaculture, Ministry of Agriculture and Rural Affairs;4.Engineering Research Center for Saline-Alkaline Fisheries (Shanghai), CAFS, Shanghai 200090, China;5.National Demonstration Center for Experimental Fisheries Science Education, Shanghai Ocean University, Shanghai 201307, China;6.Key Laboratory of Inland Saline-Alkaline Aq䈴䀀䓬쀀䐝Ꙁᙤ䬭ᙟ슰ᙎ䍶䈠䍺Ꙁᙤ亍ᙟ䅰ᙪ䈴䓰䀀䐥Ꙁᙤ再ᙟ슰ᙎ䋚쀀䐨䊺䇸Ꙁᙤ哭ᙟ䅰ᙪ䆀쀀䐨䍸䇸Ꙁᙤ珝;7.National Demonstration Center for Experimental Fisheries Science Education, Shanghai Ocean University, Shanghai 201308, China;8.Key Laboratory of Inland Saline-Alkaline Aq뿿䑫耀䎠䌏䊌Ꙁᙤ䬩ᙟ䅰ᙪ䈴䀀䓬쀀䐝Ꙁᙤ亍ᙟ슰ᙎ䍶䈠䍺Ꙁᙤ再ᙟ䅰ᙪ䈴䓰䀀䐥Ꙁᙤ哭ᙟ슰ᙎ䋚쀀䐨䊺䇸Ꙁᙤ珝;9.Rescue Center for Naked Carp of Lake Qinghai, Xining 810016, China
Abstract:
The total saline-alkaline land area in China is about 99.13 million hectares distributed across northern China, coastal areas, and areas along the bank of the Huanghe River. About 46 million hectares of saline-alkaline water areas are distributed around these saline-alkaline lands, most of which are thalassic and characterized by a high pH value in excess of 8.8 associated with high-carbonate alkalinity concentrations and various types of ion imbalances. Saline-alkaline waters are stressful environments in which only relatively few organisms are able to survive. Consequently, most of the saline-alkaline water resources have been desolate for a long time. The effective utilization of saline-alkaline water resources will benefit restoration of saline-alkaline habitats and the expansion of aquaculture space. Naked carp (Gymnocypris przewalskii) are endemic to the austere saline-alkaline environment of Qinghai Lake. Due to overfishing in the 1960s and environmental changes in the lake area, the resources necessary for naked carp survival in Qinghai Lake declined substantially. At present, the major measures to protect the naked carp and maintain the ecological balance of Qinghai Lake are through a fishing ban and artificial stocking and releasing. The feeding behavior of fish under natural conditions has obvious rhythm characteristics, which is an important research topic for healthy aquaculture. To explore the characteristics of self-feeding rhythm and growth performance of fish in a saline-alkaline environment and provide basic data for the protection of native saline-alkaline fish, naked carp were taken as representative in this study. First, the freshwater and lake water group with natural photoperiod (14L:10D) and the lake water group with darkness (24D) were set. The artificial lake water was prepared according to the ionic composition of Qinghai Lake, with the contents of Na+ 23.05%, K+ 1.34%, Ca2+ 0.11%, Mg2+ 6.88%, HCO3– 7.09%, CO32– 5.07%, Cl– 40.39%, and SO42– 16.07%. The measured salinity of the artificial lake water was 15.08, and the carbonate alkalinity was 27.53 mmol/L. According to the local photoperiod of Qinghai Province, the whole day was divided into five periods as 05:00–08:00, 8:00–11:00, 11:00–15:00, 15:00–19:00, and 19:00–05:00. The feeding rhythm experiment lasted for 5 d, and the average food intake of each period was calculated. The results showed that naked carp had an obvious daily feeding rhythm during their natural photoperiod. In the natural photoperiod, the feeding peak was from 08:00 to 11:00, and the low feeding period was from 05:00 to 08:00 in freshwater. In the lake water, naked carp showed high and continuous feeding from 08:00 to 19:00, and their average hourly feed intake was significantly higher than that from 05:00 to 08:00 and 19:00 to 05:00. Therefore, naked carp were determined to be the daytime feeding fish type. In addition, the high proportion and the continuous feeding in daytime in lake water indicated that the osmotic and acid-base regulation of naked carp in saline-alkaline water may enhance their diurnal feeding rhythm. Whereas in the continuous dark environment, the feeding rhythm of naked carp was weakened, and the average hourly food intake of each period was similar. To explore the growth performance of naked carp under a self-feeding rhythm, the lake water group and the freshwater control group with natural photoperiod were set up. After 63 days of self-feeding, the individual body length and weight of the naked carp were measured after being anesthetized with MS-222. The length growth rate (1.19±0.17)%, weight growth rate (10.66±0.98)%, and specific growth rate (0.16±0.02)%/d of naked carp in the lake water group were significantly lower than those in the freshwater group [length growth rate (18.66±0.41)%, weight growth rate (67.32±3.05)%, and specific growth rate (0.82±0.03)%/d)], indicating that the growth of naked carp was inhibited by high salinity and carbonate alkalinity environment. The parameter b of body length-weight relationship curve of the naked carp in both the lake water group and the freshwater group was less than three, which showed that the naked carp was a negative allometric growth fish. The b value of the lake water group was lower than that of the freshwater group, and the body length of naked carp increased faster than body weight in the lake water. The growth characteristics of naked carp were affected by the high saline-alkaline environment. The self-feeding rhythm and growth performance of naked carp provided a basic knowledge for creating a feeding strategy for fish cultured in a saline-alkaline environment and recovering endangered native saline-alkaline fish.
Key words:  Saline-alkaline environment  Gymnocypris przewalskii  Self feeding rhythm  Growth performance