盐碱胁迫下产ACC脱氨酶促生菌对绿豆叶片脂质代谢的影响

为探讨盐碱胁迫下产ACC脱氨酶促生菌对绿豆叶片脂质代谢的影响,采用液相色谱质谱联用技术分析盐碱胁迫下接种产ACC脱氨酶促生菌（DQJC1）后绿豆叶片内脂类代谢产物的变化。结果表明：盐碱胁迫下接种DQJC1可以促进绿豆生长,显著提高了绿豆植株的株高（34.87%）、地上部鲜质量和干质量（44.07%和46.43%）、地下部鲜质量和干质量（30.56%和23.68%）及叶绿素含量（41.61%）。同时在绿豆叶片中共筛选到61个具有显著性差异的代谢产物,其中包括32种甘油磷脂类、14种固醇类、4种甘油糖脂类、3种鞘脂类和8种其他脂类;其中上调的代谢物主要为甘油磷脂（PC、PG、LPC、PI、PE、LPG）、甘油糖脂（SQDG47∶11）及鞘脂（CerG1d18∶2/16∶0+O）,下调的代谢物主要为固醇（TG）,甘油糖脂（SQDG：16∶0/16∶0）及鞘脂（CerG1d34∶2+O）。KEGG通路富集分析发现筛选出的差异代谢物中有6种代谢物被富集到9条代谢通路中,包括甘油磷脂代谢通路、甘油脂代谢通路、自噬性溶酶体代谢通路、糖基磷脂酰肌醇代谢通路、醚脂质代谢通路、亚油酸代谢通路、磷脂酰肌醇代谢通路、α-亚油酸代谢通路和花生四烯酸代谢通路。     

方格星虫中培苗对温度、盐度和干露的耐受性试验

研究了方格星虫中培苗对盐度突变、温度突变和盐度渐变、温度渐变及干露的耐受性。试验结果表明,方格星虫中培苗耐受盐度的范围比较广泛,为10~45,适宜的盐度为15~40;适宜温度为15~30℃,对低温有较强的耐受力。方格星虫中培苗在低温保湿干露48h未发生死亡,大量死亡集中在72~96h。根据试验结果可知,方格星虫中培苗对环境的适应性较强,耐温、耐盐范围较广,且具有较强的耐干露能力,便于苗种运输。     

pH、盐度对文蛤呼吸与排泄的影响

以文蛤(Meretrix meretrix)为受试生物,采用静态法研究了不同pH和盐度下文蛤耗氧率、排氨率、排磷率及氧氮比(O∶N)的变化规律。结果表明:pH为8.7试验组文蛤耗氧率、排氨率及排磷率显著高于6.7、7.7、9.7及10.7试验组(P0.05),pH为7.7和8.7试验组O∶N值显著高于6.7、9.7及10.7试验组(P0.05);pH在6.7~10.7范围内,文蛤耗氧率、排氨率、排磷率及O∶N均随pH的升高呈先升后降的变化趋势,pH为8.7时文蛤耗氧率、排氨率、排磷率以及O∶N均为最大值,依次为5.46 mg·(g·h)-1、0.17 mg·(g·h)-1、0.19 mg·(g·h)~(-1)、27.17。盐度为20试验组文蛤耗氧率、排氨率、排磷率及O∶N显著高于16、18、22及24试验组(P0.05);盐度在16~24范围内,文蛤耗氧率、排氨率、排磷率及O∶N均随盐度的增加呈先升后降的变化趋势,盐度为20时文蛤耗氧率、排氨率、排磷率及O∶N均为最大值,分别为5.66 mg·(g·h)~(-1)、0.20 mg·(g·h)~(-1)、0.30 mg·(g·h)~(-1)和27.40。本实验研究范围内,文蛤生长的最适pH在8.7左右,最适盐度在20左右,为文蛤的人工养殖提供了重要的数据支持。     

盐度胁迫及昼夜变化对鲻鱼幼鱼消化酶活力的影响

研究了S0（盐度为0）、S10、S20、S33（对照）和S40 5个盐度梯度14d内盐度胁迫及其昼夜变化对鲻鱼（Mugil cephalus）幼鱼蛋白酶和淀粉酶比活力的影响。结果显示：1）盐度胁迫对鲻鱼幼鱼的消化酶活力有显著影响（P〈0．05）。不同盐度的蛋白酶和淀粉酶活力的变化规律都是在第0天～第7天升高,第7天～第14天降低,最终时（第14天）S0～S33蛋白酶活力呈上升趋势,S33～S40下降;S0～S20淀粉酶活力差异不显著（P〉0．05）,S20～S33呈上升,S33～S40下降,且差异显著（P〈0．05）;2）对鲻鱼幼鱼消化酶活性昼夜变化的测定表明,蛋白酶和淀粉酶活性的最高值分别在12：00和15：00,最低值均出现在6：00。因此,夜间设置定时投喂,可促进鱼类快速健康生长。     

Histological alterations in gills of shrimp Litopenaeus vannamei in low‐salinity waters under different stocking densities: Potential relationship with nitrogen compounds

Two experimental modules with different stocking densities (M1 = 70 and M2 = 120 shrimp /m²) were examined weekly over a culture cycle in tanks with low‐salinity water (1.9 g/L) and zero water exchange. Results showed survival rates of 87.7 and 11.9% in M1 and M2, respectively. Water temperature, pH, dissolved oxygen, electrical conductivity and chlorophyll a were not significantly (p > .05) different between modules. In contrast, the concentrations of nitrogen compounds were significantly (p < .05) different between modules, except nitrite‐N (M2 were 2.31 ± 1.38 mg/L N‐TAN, 0.18 ± 0.49 mg/L N‐NO₂^? and 6.83 ± 6.52 mg/L N‐NO₃^?; in M1: 0.97 ± 0.73 mg/L N‐TAN, 0.05 ± 0.21 mg/L N‐NO₂^? and 0.63 ± 0.70 mg/L N‐NO₃^?). When waters of both modules reached higher levels of ammonia and nitrite, histological alterations were observed in gills. The histological alterations index (HAI) was higher in M2 (5‐112) than in M1 (2‐22).     

盐度对澳洲宝石鲈幼鱼3个免疫因子活力的影响

实验室条件下测定了在盐度0、5、8、11、13、16下胁迫20d,澳洲宝石鲈（Scortum barcoo）幼鱼内脏组织中超氧化物歧化酶（SOD）、碱性磷酸酶（AKP）及酸性磷酸酶（ACP）共3个免疫相关因子的活力变化。结果表明,盐度胁迫对澳洲宝石鲈3个免疫因子均有一定的影响,在不同盐度的胁迫下,随着盐度的升高,其SOD活性先下降、再升高;碱性磷酸酶（AKP）活性在低盐度胁迫下有短暂升高的过程,然后随着盐度的升高,其活性又明显下降;而酸性磷酸酶（ACP）则是随盐度的升高逐渐增大。试验结果说明低盐度胁迫能引起宝石鲈的应激反应,适当提高其免疫力,而大幅度升高盐度可显著影响其免疫力。     

水温和盐度对大菱鲆稚鱼存活的影响

采用突然改变温度和盐度的方法,试验不同水温和盐度对大菱鲆稚鱼存活的影响。试验结果表明,水温为15.0~18.0℃、盐度为28~32,大菱鲆稚鱼存活率最高;用曲线回归的方法求出24 h内存活率与温度的关系式,其回归方程为y=-0.5506x2 18.4970x-53.13,依此得到大菱鲆稚鱼的高、低起始致死温度为26.54℃和7.06℃。依同样方法得到24h内存活率与盐度的回归方程为y=-0.4353x2 23.4226x-213.81,高、低起始致死盐度为37.76和16.05。经t检验显著相关(P<0.01)。     

黄河口刺参苗种的盐度适宜性研究

通过设置不同的盐度梯度(20‰,25‰,30‰,35‰),对黄河三角洲地区养殖的刺参稚参在不同盐度下的生长状况进行了研究。结果表明,黄河三角洲地区刺参生长最适盐度范围在25‰~30‰。过高或过低的盐度对刺参生长产生影响的原因可能是:第一,在呼吸树的作用下,耗氧率增加以调节渗透压,消耗了能量,影响了刺参的生长;第二,刺参体内环境的改变影响了消化酶活性,进而影响刺参的摄食和消化。     

斑节对虾GLUT1基因cDNA的克隆与表达分析

该研究利用RACE技术克隆获得了斑节对虾(Penaeus monodon) GLUT1 (glucose transporter type 1)的cDNA全长序列;采用实时荧光定量的方法研究了PmGLUT1在斑节对虾幼体发育过程中、各个组织中及低盐胁迫下的差异表达情况。该基因cDNA开放阅读框(ORF)全长1 476 bp,可编码491个氨基酸。检测PmGLUT1基因从受精卵至仔虾期发育过程的表达情况,结果显示,PmGLUT1在幼体发育各期的表达量有所波动,但总体呈现上升趋势。组织表达分析发现,PmGLUT1在鳃组织中的表达量最高,肝胰腺次之,在卵巢中的表达量最低。急性低盐胁迫后,PmGLUT1在肝胰腺中的表达水平显著高于对照组(P<0.05),但在鳃中的表达水平显著低于对照组(P<0.05)。研究结果表明,Pm GLUT1可能在斑节对虾幼体发育及机体应对低盐胁迫过程中具有重要作用,这为进一步研究葡萄糖转运蛋白基因在斑节对虾幼体发育调控和耐低盐胁迫应答中的分子机制提供了理论依据。     

Effect of salinity on growth and energy budget of red and green colour variant sea cucumber Apostichopus japonicus (Selenca)

Sea cucumber, Apostichopus japonicus (Selenca), tolerates salinity fluctuations inhabiting intertide zone. This study deals with growth, food intake, food conversion and the bioenergetic responses of the red variant (wet weight of 2.60 ± 0.11g) and green variant (wet weight of 2.56 ± 0.08 g) A. japonicus to different salinities of 22, 26, 30, 34, and 38 psu at 16.5 ± 0.5°C. The results showed that salinity had a significant effect on specific growth rate (SGR) of both green and red variants A. japonicus (P < 0.05). Both colour variants of sea cucumber had highest SGR at 30 psu, and then decreased when salinity below or above this point. Maximum SGR (the green 1.07 ± 0.08% day^?1, the red 1.14 ± 0.09% day^?1 respectively) is related with maximum food intake (FI) and highest food conversion efficiency (FCE) (P < 0.05) occurring at 30 psu. Only under 22 psu, the green variant grew faster than the red variant (P < 0.05), and under other four salinity treatments there was no significant difference between SGR of two colour variant holothruians (P > 0.05). Values of adaptable salinity scope for green and red variants sea cucumber survival are 18.5~39 psu and 20.9~38.6 psu respectively. The average energy budget formula of sea cucumber at 30 psu was: 100C = 6G +42F +3U+49R (C, energy ingested; G, energy for growth; F, energy loss as faeces; U, energy used for ammonia excretion; R, energy loss for respiration). The sea cucumber had maximum energy ingested (C) and highest proportion of energy for growth (G) at 30 psu, and then decreased when salinity is above or below this salinity. Both red and green variants of A. japonicus deposited for growth were very low, and the energy loss in faeces and energy for respiration accounted for the majority of assimilation energy. The result clearly showed that the optimum condition for farming green and red variants A. japonicus, both with respect growth and energy allocation, is the salinity scope of 26 ~ 30 psu.