Interaction of temperature and salinity on the expression of immunity factors in different tissues of juvenile turbot Scophthalmus maximus based on response surface methodology

文献类型: 外文期刊

第一作者: Huang Zhihui

作者: Huang Zhihui;Huang Zhihui;Ma Aijun;Wang Xin'an;Lei Jilin;Li Weiye;Wang Ting;Yang Zhi;Qu Jiangbo

作者机构:

关键词: turbot (Scophthalmus maximus);response surface methodology (RSM);Central Composite Design (CCD);Hsp70;immunoglobulin M (IgM)

期刊名称:CHINESE JOURNAL OF OCEANOLOGY AND LIMNOLOGY ( 影响因子:1.068; 五年影响因子:0.983 )

ISSN: 0254-4059

年卷期: 2015 年 33 卷 1 期

页码:

收录情况: SCI

摘要: Central Composite Design (CCD) and response surface methodology were used in the experiment to examine the combined effect of temperature (16-28 degrees C) and salinity (18-42) on Hsp70 and IgM genes expression levels in turbot (Scophthalmus maximus) liver and kidney. The results showed that the coefficients of determination (R-2 = 0.965 2 for liver Hsp70, 0.972 9 for kidney Hsp70, 0.921 for liver IgM and 0.962 1 for kidney IgM) and probability values (P<0.01) were significant for the regression model. The interactive effect between temperature and salinity on liver Hsp70, kidney Hsp70 and liver IgM were not significant (P>0.05), while the interactive effect between temperature and salinity on kidney IgM was significant (P<0.01). The model equation could be used in practice for forecasting Hsp70 and IgM genes expression levels in the liver and kidney of juvenile turbot via applying statistical optimization of the response of interest, at which the maximum liver Hsp70, kidney Hsp70, liver IgM and kidney IgM of 1.48, 1.49, 2.48, and 1.38, respectively, were reached. The present model may be valuable in assessing the feasibility of turbot farming at different geographic locations and, furthermore, could be a useful reference for scientists studying the immunity of turbot.

分类号:

  • 相关文献

[1]Improvement of xylanase production by Aspergillus niger XY-1 using response surface methodology for optimizing the medium composition. Xu, Yao-Xing,Li, Yan-li,Xu, Shao-chun,Liu, Yong,Wang, Xin,Tang, Jiang-wu. 2008

[2]Molecular characterization and quantification of estrogen receptors in turbot (Scophthalmus maximus). Hu, Peng,Meng, Zhen,Jia, Yudong. 2018

[3]Biochemical composition and quality of turbot (Scophthalmus maximus) eggs throughout the reproductive season. Jia, Yudong,Meng, Zhen,Liu, Xinfu,Lei, Jilin,Jia, Yudong,Meng, Zhen,Liu, Xinfu,Lei, Jilin. 2014

[4]Molecular components related to egg quality during the reproductive season of turbot (Scophthalmus maximus). Jia, Yudong,Meng, Zhen,Liu, Xinfu,Lei, Jilin.

[5]Molecular cloning and multifunctional characterization of GRIM-19 (gene associated with retinoid-interferon-induced mortality 19) homologue from turbot (Scophthalmus maximus). Wang, Na,Wang, Tianzi,Chen, Songlin,Wang, Xianli,Yang, Changgeng,Zhao, Xiaojie,Zhang, Yuxi.

[6]Changes in protein composition of epidermal mucus in turbot Scophthalmus maximus (L.) under high water temperature. Ma Ai-Jun,Huang Zhi-hui,Wang Xin-An.

[7]Cloning, molecular characterization and expression analysis of heat shock cognate 70 (Hsc70) cDNA from turbot (Scophthalmus maximus). Wang, T. T.,Wang, N.,Liao, X. L.,Meng, L.,Liu, Y.,Chen, S. L.,Wang, T. T..

[8]Molecular characterization and quantification of the follicle-stimulating hormone receptor in turbot (Scophthalmus maximus). Jia, Yudong,Sun, Ai,Meng, Zhen,Liu, Baoliang,Lei, Jilin,Jia, Yudong,Sun, Ai,Meng, Zhen,Liu, Baoliang,Lei, Jilin.

[9]Molecular cloning, subcelluar location and expression profile of signal transducer and activator of transcription 2 (STAT2) from turbot, Scophthalmus maximus. Wang, Na,Chen, Song-Lin,Wang, Xian-Li,Yang, Chang-Geng.

[10]MHC polymorphism and disease-resistance to Edwardsiella tarda in six turbot (Scophthalmus maximus) families. Du Min,Chen SongLin,Yang JingFeng,Zhang Bo,Du Min,Liu YanHong,Niu BaoZhen,Du Min. 2012

[11]Characterization of field scale soil variability using remotely and proximally sensed data and response surface method. Guo, Yan,Wang, Laigang,Guo, Yan,Shi, Zhou,Zhou, Lianqing,Zhou, Yin,Huang, Jingyi,Shi, Zhou. 2016

[12]Ethanol extraction of flavonoids from Mungbean Skin after twin-screw extrusion process. Du, Bing,Jiao, Yanli,Huang, Zhiqiang,Mao, Liankai,Fan, Yuanyuan,Yang, Gongming,Wu, Haixiong,Jiang, Longbo. 2012

[13]Process optimization for the enrichment of alpha-linolenic acid from silkworm pupal oil using response surface methodology. Wang, Jun,Wu, Fu-An,Liang, Yao,Wang, Meng,Wu, Fu-An. 2010

[14]Lonic Liquids-based Ultrasonic -assisted Extraction of Total Flavonoids from Manilkara Zapota Leaves. Ma, Fei-Yue,Fu, Qiong,Zhang, Xiu-Mei,Liu, Yu-Ge,Ma, Fei-Yue,Fu, Qiong,Zhang, Xiu-Mei,Liu, Yu-Ge. 2016

[15]Phytase production by fermentation of recombinant Pichia pastoris in monosodium glutamate wastewater. Bai, Yingguo,Yang, Peilong,Wang, Yaru,Shi, Pengjun,Luo, Huiying,Meng, Kun,Wu, Bo,Yao, Bin.

[16]Extraction and radicals scavenging activity of polysaccharides with microwave extraction from mung bean hulls. Zhong, Kui,Lin, Weijing,Wang, Qiang,Zhou, Sumei.

[17]The interaction of temperature, salinity and body weight on growth rate and feed conversion rate in turbot (Scophthalmus maximus). Huang Zhi-Hui,Ma Ai-Jun,Wang Xin-An,Lei Ji-Lin,Huang Zhi-Hui.

[18]Ultrasonic extraction of phenolics from longan seed by response surface methodology. Lin, Lijing,Huang, Xiaobing,Li, Jihua,Tang, Yongfu. 2013

[19]Microwave-assisted approach for the rapid enzymatic digestion of rapeseed meal. Li, Ju-Fang,Wei, Fang,Dong, Xu-Yan,Guo, Lu-Lu,Yuan, Gang-You,Huang, Feng-Hong,Jiang, Mu-Lan,Li, Guang-Ming,Chen, Hong,Zhao, Yuan-Di. 2010

[20]Optimization of ultrasonic extraction of polysaccharides from dried longan pulp using response surface methodology. Zhong, Kui,Wang, Qiang,Zhong, Kui.

作者其他论文 更多>>

微信小程序