根腐病菌侵染对黄芪苯丙烷途径关键酶活性的影响

以蒙古黄芪-根腐病菌（Fusarium solani和F. acuminatum）为互作体系,测定苯丙烷途径关键酶苯丙氨酸解氨酶(PAL)、肉桂酸-4-羟化酶(C4H)及4-香豆酸-辅酶A连接酶(4CL)活性的变化,以期获得黄芪抗根腐病菌侵染机制的信息,为抗病育种工作提供参考。试验采用幼苗浸根法接种病菌,分光光度法测定3种酶的动态变化。结果表明,F. solani侵染黄芪后,PAL和C4H活性与对照相比明显升高,并在7、21天出现2个酶活高峰;4CL活性则随着时间的延长持续上升,7、21天时也显著高于对照。F. acuminatum侵染黄芪后,PAL、C4H和4CL的活性均在21天显著高于对照。可见2种病原菌在侵染黄芪过程中,苯丙烷途径的关键酶被不同程度地激活,但2种病菌激活各酶的时间和规律有所差异,表明黄芪对这2种病菌的抗性机制明显不同。     

AMF促进植物吸收矿质元素的生理机制及对土壤硫素的影响

由于人口不断增长,人们要快速得到高产高质粮食的要求迫切,大量使用化肥,导致了有害物质残留,土壤或水污染,土壤板结或某些营养元素相对匮乏等一系列环境问题。丛枝菌根(Arbuscular mycorrhiza, AM)是土壤内常见的共生结构,由AM真菌(AMF)与土壤根系形成。已有研究表明其可通过分泌代谢物,增大根系与土壤接触面积,调节某些土壤元素存在形式等多种途径,影响植物对土壤元素的吸收转运。硫是维持植物生长发育的必需元素之一,可由于植物对S的需要并不如N,P,K大量,现代农业在对土壤进行施肥过程中往往将其忽略,因此土壤缺S正逐渐成为中国农业发展的限制因素。为了解决以上问题,本文将主要对AMF影响植物吸收土壤元素的途径及生理机制进行总结分析。并根据其作用方式特点进一步分析AM共生对植物吸收转运硫素的影响,指出AMF作为生物化肥的可行性,以期为解决现代化肥的替代问题以及土壤缺硫问题提供新的思路。     

鹅羽绒发生发育的分子调控机理研究进展

简要概述了鹅羽绒毛囊形态发生和生长周期的循环过程,对Wnt/β-catenin信号传导途径、Shh传导途径、部分相关基因功能及其调控羽绒发生发育的分子机理进行了综述,并提出了目前研究中仍存在的问题。     

Effect of dietary carbohydrate-to-lipid ratios on growth, lipid deposition and metabolic hepatic enzymes in juvenile Senegalese sole (Solea senegalensis, Kaup)

A study was undertaken to determine the effect of various dietary carbohydrate‐to‐lipid ratios on growth performance, whole‐body composition and tissue lipid content in Senegalese sole (Solea senegalensis) juveniles. Data on the dietary regulation of key hepatic enzymes of the lipogenic and glycolytic pathways (glucose‐6‐phosphate dehydrogenase, G6PD; malic enzyme, ME; fatty acid synthetase, FAS; pyruvate kinase, PK and glucokinase, GK) were also generated. Four isonitrogenous (crude protein: 52% dry matter (DM)) diets were formulated to contain one of two lipid levels (11% and 21% DM). Within each dietary lipid level, the nature of the carbohydrate fraction (raw or extruded peas) was varied. Triplicate groups of 54 sole (initial body weight: 23.6±1.2 g) were grown in recirculated seawater over 67 days. Fish were fed using automated feeders. At the end of the study, whole‐body, liver, viscera and muscle samples were withdrawn for analyses. During the experimental period, the mean fish weight about doubled in all treatments. No significant differences were found in growth performance (ranging from 1.1% to 1.4% body weight day^?1) among dietary treatments. High‐fat diets increased whole‐body fat content. Similarly, daily fat gain ranged from 0.54 to 0.78 g kg^?1 day^?1 and highest values were found in fish fed high‐lipid diets. Dietary treatments also affected tissue lipid content (liver, viscera and muscle), with highest values in fish fed high‐fat diets. The nature of dietary carbohydrates had little influence on performance criteria, but affected tissue lipid deposition. The activities of G6PD, ME and FAS were depressed by elevated levels of dietary lipid, confirming the inhibitory effect of dietary fats on lipid biosynthesis. At both dietary lipid levels, ME and FAS activities were little affected by dietary carbohydrate. Activities of PK and GK were not affected by the starch level of the diets. In Senegalese sole juveniles, the lipogenic pathway is more susceptible to modulation by dietary means (particularly through lipid intake) than the glycolytic pathway.     

Routine metabolism of larval green sturgeon (Acipenser medirostris Ayres)

Routine metabolic rates of green sturgeon (Acipenser medirostris) from hatching to 31 days post hatch (dph) were determined under normoxic conditions. During the endogenous feeding stage that comprised period from hatching to 15 dph, the oxygen consumption rate (MO₂, μg O₂ larva⁻¹ h⁻¹) increased 5-fold before yolk reserves became exhausted and MO₂ rates steady. The allometric relationships between MO₂ and body mass had mass exponents greater than 1.0 (b=1.64±0.21) and equal to 1.0 (b=1.04±0.07) during the endogenous and exogenous feeding phases, respectively. The magnitude and changes of MO₂ rates in green sturgeon larvae reflected their early ontogeny, especially during the endogenous feeding phase when the increase in metabolic rates was associated with organogenesis, acquisition of organ functions, and the conversion of yolk sac into new tissues. This revised version was published online in August 2006 with corrections to the Cover Date.     

斑节对虾Toll9受体基因免疫功能的研究与表达分析

Toll受体蛋白(Toll receptors)是一类重要的模式识别受体,在无脊椎动物先天性免疫系统中发挥重要作用。文章对斑节对虾(Penaeus monodon)新型Toll9受体基因(Pm Toll9)进行了研究:以人源胚胎肾细胞(HEK293T)成功构建体外细胞免疫模型,通过免疫印迹方法证实Pm Toll9重组真核蛋白可在HEK293T中成功表达。双荧光素酶报告系统检测发现在200 ng转染浓度处Pm Toll9对NF-κB报告基因的激活效果显著。q RT-PCR数据证明PmToll9成功激活HEK293T细胞Toll-like receptor(TLR)信号通路,促进通路下游髓样分化因子(My D88)、肿瘤坏死因子(TNF-α)和白介素(IL-10)的上调表达,同时酶联免疫吸附测定结果证明Pm Toll9可促进TNF-α蛋白表达水平显著上调。斑节对虾体内细菌刺激实验结果显示无乳链球菌(Streptococcus agalactiae)可激活Pm Toll9在肝胰腺、肠、淋巴和鳃中的表达,哈维氏弧菌(Vibrio harveyi)可显著抑制Pm Toll9在肝胰腺中的表达。提示无乳链球菌可通过Pm Toll9激活Toll信号通路,引起机体免疫防御反应,而哈维氏弧菌对此过程具有一定的抑制作用。     

海洋贝类Toll样受体及信号通路的研究进展

Toll样受体(Toll-like receptor,TLR)是模式识别受体家族(PRR)中重要的一员,它可以特异地识别病原体相关的分子模式(PAMP),激活信号级联、诱发固有免疫反应,在抵御病原微生物过程中发挥重要作用。TLRs最早在果蝇胚胎中发现,是一类进化高度保守的免疫受体家族,在果蝇及脊椎动物中研究得较为透彻。海洋贝类具有较高的经济价值及重要系统进化地位,近年来,大量贝类的Toll样受体及信号通路相关因子被发现。本文综述了Toll样受体的结构、信号通路和海洋贝类TLR及信号通路相关因子的研究进展,有助于丰富海洋贝类固有免疫理论研究。     

急性温度胁迫对银鲳幼鱼代谢酶、离子酶活性及血清离子浓度的影响

为探明急性温度胁迫对银鲳(Pampus argenteus)幼鱼生化指标的影响,该实验设计了3个温度梯度,即22℃、27℃和32℃,以27℃为对照组,胁迫时间48 h,分别测定胁迫前后其代谢酶、离子酶活性以及血清中离子浓度。结果显示,2个实验组的血清谷丙转氨酶(GPT)的变化趋势相反,肝脏谷草转氨酶(GOT)的变化趋势也不同;2个实验组的碱性磷酸酶(AKP)变化趋势相反,而酸性磷酸酶(ACP)变化趋势相同,乳酸脱氢酶(LDH)在22℃实验组出现波浪式变化(P0.05);血清钠(Na+)、钾(K+)、氯(Cl-)、钙(Ca2+)在各组呈现不同的变化趋势;鳃Na+/K+-ATP酶活性在32℃实验组出现下降趋势,肾脏Na+/K+-ATP酶活性在22℃实验组出现先升高后降低趋势(P0.05);2个实验组鳃Ca2+/Mg2+-ATP酶活性和肾脏Ca2+/Mg2+-ATP酶活性皆出现相反的变化趋势。结果表明,急性温度胁迫可显著影响银鲳幼鱼的正常代谢,因此在养殖过程中应尽量避免温度胁迫,以使其有一个良好的生长环境。