中国水产科学
中國水產科學
중국수산과학
Journal of Fishery Sciences of China
2014年
1期
75-83
,共9页
夏耘%邱立疆%郁二蒙%谢骏%王广军%余德光%吉红
夏耘%邱立疆%鬱二矇%謝駿%王廣軍%餘德光%吉紅
하운%구립강%욱이몽%사준%왕엄군%여덕광%길홍
生物絮团%PCR-DGGE%草鱼%原核微生物%真核微生物%总氮
生物絮糰%PCR-DGGE%草魚%原覈微生物%真覈微生物%總氮
생물서단%PCR-DGGE%초어%원핵미생물%진핵미생물%총담
Bio-floc%PCR-DGGE%Ctenopharyngodon idellus%prokaryotic microorganisms%eukaryotic microor-ganisms%total nitrogen
在草鱼(Ctenopharyngodon idella)养殖系统中维持碳氮比为20︰1、水温(26.0±2.3)℃、pH7.2~7.8,24 h不间断供氧以形成生物絮团,监测培养过程中养殖水体总氮(TN)、总固体悬浮物(TSS)浓度、碱度的动态变化及分析生物絮团的营养组分,并应用PCR-DGGE技术研究生物絮团的原核及真核微生物组成和动态变化。养殖水体TN变化范围为6.65~11.15 mg/L,第9天达到峰值(10.11±1.05) mg/L,第12天后和第0天时的TN水平无显著性差异(P>0.05);TSS浓度在第9天达到最大值(419.67±11.5) mg/L,第15天后TSS稳定维持在244.67 mg/L;碱度变化范围为136.68~239.20 mg CaCO3/L,第6天达到峰值后逐渐下降并趋于平稳。生物絮团的粗蛋白含量为30%(干重)。生物絮团原核微生物主要由变形菌门(Proteobacterium)、放线菌门(Actinobacteria)、拟杆菌门(Bacteroidetes)和某些未知不可培养的细菌组成,蓝细菌(Cyanobacterium)只存在于生物絮团培养前期(第0、5、10天),产碱菌科细菌(Alcaligenaceae)存在于生物絮团形成的整个过程,且是第5、10、15天的优势菌。组成生物絮团的真核微生物隶属于原生动物门的斜叶虫属(Loxophyllum)、隐藻纲的隐鞭藻科(Cryptomonadaceae)及Goniomonas属、硅藻纲的双头菱形藻属(Nitzschia)。其中双头菱形藻属为絮团培养初始第0天到15天特有;斜叶虫属在絮团培养后期分布较多。结论认为,生物絮团系统在养殖的15 d左右达到稳定运行的状态,能有效调节养殖系统菌藻分布,控制养殖水质,维持整个系统的平衡与良性发展。
在草魚(Ctenopharyngodon idella)養殖繫統中維持碳氮比為20︰1、水溫(26.0±2.3)℃、pH7.2~7.8,24 h不間斷供氧以形成生物絮糰,鑑測培養過程中養殖水體總氮(TN)、總固體懸浮物(TSS)濃度、堿度的動態變化及分析生物絮糰的營養組分,併應用PCR-DGGE技術研究生物絮糰的原覈及真覈微生物組成和動態變化。養殖水體TN變化範圍為6.65~11.15 mg/L,第9天達到峰值(10.11±1.05) mg/L,第12天後和第0天時的TN水平無顯著性差異(P>0.05);TSS濃度在第9天達到最大值(419.67±11.5) mg/L,第15天後TSS穩定維持在244.67 mg/L;堿度變化範圍為136.68~239.20 mg CaCO3/L,第6天達到峰值後逐漸下降併趨于平穩。生物絮糰的粗蛋白含量為30%(榦重)。生物絮糰原覈微生物主要由變形菌門(Proteobacterium)、放線菌門(Actinobacteria)、擬桿菌門(Bacteroidetes)和某些未知不可培養的細菌組成,藍細菌(Cyanobacterium)隻存在于生物絮糰培養前期(第0、5、10天),產堿菌科細菌(Alcaligenaceae)存在于生物絮糰形成的整箇過程,且是第5、10、15天的優勢菌。組成生物絮糰的真覈微生物隸屬于原生動物門的斜葉蟲屬(Loxophyllum)、隱藻綱的隱鞭藻科(Cryptomonadaceae)及Goniomonas屬、硅藻綱的雙頭蔆形藻屬(Nitzschia)。其中雙頭蔆形藻屬為絮糰培養初始第0天到15天特有;斜葉蟲屬在絮糰培養後期分佈較多。結論認為,生物絮糰繫統在養殖的15 d左右達到穩定運行的狀態,能有效調節養殖繫統菌藻分佈,控製養殖水質,維持整箇繫統的平衡與良性髮展。
재초어(Ctenopharyngodon idella)양식계통중유지탄담비위20︰1、수온(26.0±2.3)℃、pH7.2~7.8,24 h불간단공양이형성생물서단,감측배양과정중양식수체총담(TN)、총고체현부물(TSS)농도、감도적동태변화급분석생물서단적영양조분,병응용PCR-DGGE기술연구생물서단적원핵급진핵미생물조성화동태변화。양식수체TN변화범위위6.65~11.15 mg/L,제9천체도봉치(10.11±1.05) mg/L,제12천후화제0천시적TN수평무현저성차이(P>0.05);TSS농도재제9천체도최대치(419.67±11.5) mg/L,제15천후TSS은정유지재244.67 mg/L;감도변화범위위136.68~239.20 mg CaCO3/L,제6천체도봉치후축점하강병추우평은。생물서단적조단백함량위30%(간중)。생물서단원핵미생물주요유변형균문(Proteobacterium)、방선균문(Actinobacteria)、의간균문(Bacteroidetes)화모사미지불가배양적세균조성,람세균(Cyanobacterium)지존재우생물서단배양전기(제0、5、10천),산감균과세균(Alcaligenaceae)존재우생물서단형성적정개과정,차시제5、10、15천적우세균。조성생물서단적진핵미생물대속우원생동물문적사협충속(Loxophyllum)、은조강적은편조과(Cryptomonadaceae)급Goniomonas속、규조강적쌍두릉형조속(Nitzschia)。기중쌍두릉형조속위서단배양초시제0천도15천특유;사협충속재서단배양후기분포교다。결론인위,생물서단계통재양식적15 d좌우체도은정운행적상태,능유효조절양식계통균조분포,공제양식수질,유지정개계통적평형여량성발전。
A 30-day experiment was conducted to investigate the effectiveness of bio-floc technology for main-taining good water quality in Ctenopharyngodon idellus with average weight of (121.61±14.23) g farming ponds. The total suspended solids(TSS), total nitrogen (TN) and alkalinity (CaCO3) were determined every 3 days and microbial communities of the bio-floc were analyzed using the PCR-DGGE (PCR-denaturing gradient gel elec-trophoresis) every 5 days, respectively. The results showed that water TSS concentration reached a peak value of (419.67±11.5) mg/L on the 9th day, which was significantly (P<0.05) higher than that of the other time points. From the 15th day on, the TSS remained at a relatively stable level of 244.67 mg/L. The TN ranged from 6.65 to 11.15 mg/L, and it reached the peak value of (10.11±1.05) mg/L on the 9th day. There was no significant differ-ence in TN between water after the 12th day and water at the beginning of the farming trial (P>0.05). Alkalinity in the farming system ranged from 136.68 to 239.20 mg(CaCO3)/L, which reached maximum peak value of (238.22±5.44) mg (CaCO3)/L on the 6th day, after which it decreased gradually and then remained stable. Bio-floc had a crude protein content of 30%dry weight. The acquired sequences of 20 bands in 16S rDNA DGGE gel and six bands in 18S rDNA DGGE gel were analyzed by BLAST searches against the NCBI GenBank database. The main prokaryotic microorganisms represented by the 20 main bands in 16S rDNA DGGE gel were Alphaproteo-bacteria, Betaproteobacteria, Gammaproteobacteria, Deltaproteobacteria, Actinobacteria, and Bacteroidetes. Alca-ligenaceae throughout the process of formation of the bio-floc, and was the dominant bacteria on the 5th, 10th, and 15th days. The existence of Alcaligenaceae had some influence on the increase in water alkalinity during this pe-riod. We also found that bands 7 and12 represented Cyanobacteria, which appeared on the 0th, 5th and 10th days;they disappeared in the late culture period, which indicated that the application of bio-floc technology can control algal growth to some extent. The main Eukaryotic microorganisms represented by the six main bands in 18S rDNA DGGE gel were Loxophyllum sp., Nitzschia amphibian, Goniomonas sp., and Cryptomonadaceae. Nitzschia am-phibian belongs to the diatoms, and was present from the 1stto 15th days of bio-floc culture. A larger number of Loxophyllum sp. existed at the later stage of the bio-floc culture. The results demonstrated that the bio-floc system achieved stable operation state after 15 days. Bio-floc could regulate the water quality and the distribution of bac-teria and algae effectively;it could also maintain the balance and development of the whole aquaculture system.
