松墨天牛幼虫体内神经毒性酯酶和乙酰胆碱酯酶对甲胺磷敏感性的比较

松墨天牛Monochamus alternatus Hope是传播松材线虫Bursaphelenchus xylophilus Nickle的主要媒介昆虫,在其化学防治中经常使用有机磷杀虫剂,而这类杀虫剂有些可通过作用于神经毒性酯酶（neurotoxic esterase, NTE）使敏感的脊椎动物产生迟发性神经毒性。为了深入理解有机磷杀虫剂对害虫毒杀作用机理,增强对昆虫体内NTE活性的了解,我们在松墨天牛中开展了相关的研究。通过差异测定法和经典的乙酰胆碱酯酶（acetylcholinesterase, AChE）活性测定方法,分别测定了松墨天牛幼虫体内NTE和AChE的活性。结果发现,在松墨天牛体内存在NTE活性,其头部的NTE活力为2.80±0.30 nmol·min^-1·mg^-1,比脂肪体高出了近10倍,但仍较鸟类等脊椎动物为低。体内实验显示,松墨天牛体内NTE可被甲胺磷所抑制; 但在体外实验条件下,甲胺磷对来自松墨天牛头部的NTE活性并没有产生明显抑制作用,而此浓度下的甲胺磷对AChE表现出较高水平的抑制作用。表明松墨天牛体内NTE和AChE对甲胺磷的敏感性完全不同。     

茉莉酸甲酯处理对棉铃虫生长和解毒能力的影响

【目的】为明确茉莉酸甲酯（methyl jasmonate, MeJA）的不同处理方式对昆虫生长和解毒代谢能力的影响,以及MeJA熏蒸处理昆虫对植物防御和昆虫解毒代谢之间关系的影响。【方法】本文比较了取食MeJA和MeJA熏蒸等两种处理对棉铃虫Helicoverpa armigera 3龄末幼虫生长和解毒代谢酶活性的影响,并系统研究了经MeJA熏蒸处理的棉铃虫3龄末幼虫,再取食经MeJA喷雾处理的棉叶,其中肠解毒酶活性的变化。【结果】取食MeJA和MeJA熏蒸两种不同处理,对棉铃虫幼虫的生长及解毒能力的影响有所不同。取食含2.9 μg/g MeJA的人工饲料显著抑制了棉铃虫的生长,同时诱导棉铃虫幼虫P450活性增加了1.92倍,而MeJA熏蒸虽然没有影响棉铃虫幼虫的生长,但MeJA熏蒸处理使棉铃虫幼虫P450活性和羧酸酯酶活性分别增加了2.94倍和1.16倍。经MeJA熏蒸处理后的棉铃虫幼虫,再取食正常的或经MeJA喷雾处理的棉叶,其幼虫P450活性显著增加,其中经MeJA熏蒸处理的棉铃虫,再取食经MeJA喷雾处理的棉叶,其P450酶显示了最高活性。【结论】MeJA熏蒸处理棉铃虫,不仅使棉铃虫中与P450酶相关的解毒能力显著增加,而且增加了棉铃虫对于MeJA所诱导的棉花防御反应的解毒能力。     

真菌新型激活蛋白对Bt制剂的增效作用

激活蛋白是从交链孢属 (Alternaria)真菌分离的新型多功能蛋白 ,以棉铃虫和小菜蛾幼虫为供试昆虫 ,用饲料染毒法、浸叶法和浸虫法测定了激活蛋白对Bt的增效作用。结果表明 ,用Bt∶激活蛋白为 1∶0 0 3的含毒饲料饲喂 2龄棉铃虫幼虫 ,其增效指数为 2 2倍。Bt∶激活蛋白以 1∶0 0 95和 1∶0 6混合后分别浸叶后 ,饲喂棉铃虫和小菜蛾幼虫 ,其增效指数分别为 2 7和 5 5倍。单独用激活蛋白饲喂棉铃虫幼虫无致死活性 ,但当Bt与激活蛋白以 1∶0 75混合后 ,毒杀效果显著增强 ,对Bt的增效指数为 18 5倍。     

不同生态环境中铜绿丽金龟幼虫肠道细菌 产消化酶活性比较

目的测定不同生态环境中铜绿丽金龟幼虫肠道细菌产消化酶活性。方法采用平板透明圈法和分光光度计法。结果平板透明圈法测得废弃菜园和花生田中铜绿丽金龟幼虫肠道细菌产蛋白酶和淀粉酶活性差异无统计学意义(F=1.089、0.4963,P0.05),而细菌的产纤维素酶活性有显著差异,其中花生田铜绿丽金龟幼虫肠道中分离到的粘质沙雷菌产酶活性显著高于其他菌株;分光光度计测得的不同生态环境中铜绿丽金龟幼虫肠道细菌的产蛋白酶、淀粉酶和纤维素酶活性差异均有统计学意义(F=461.565、42.349、18.7673,P0.05)。从变异系数来看,分光光度计法测得的蛋白酶、淀粉酶和纤维素酶的变异程度较低,而脂肪酶测定时平板透明圈法的变异系数较低。结论平板透明圈法和分光光度计法均可用于铜绿丽金龟幼虫肠道细菌产消化酶活性测定。通过分析研究比较,分光光度计法适于测定细菌的产蛋白酶、淀粉酶和纤维素酶活性,平板透明圈法适于测定细菌的产脂肪酶活性。     

棉铃虫幼虫自相残杀习性与其龄期和食物营养的相关性（英文）

【目的】 昆虫自相残杀行为可以促进特定病原体的传播,这在利用昆虫病原体防治害虫方面有潜在的应用价值。本研究旨在探究棉铃虫 Helicoverpa armigera 幼虫自相残杀习性与其龄期及食物营养之间的相关性。【方法】 分别饲喂室内品系和野外品系的棉铃虫幼虫含不同Na⁺浓度的人工饲料,并在饲养至3龄、4龄、5龄和6龄时,将取食相同饲料的10头幼虫为一群组移入同一培养皿中,通过测定各处理幼虫存活率,评估幼虫龄期和饲料中的Na⁺含量对自相残杀行为的影响。【结果】 当以3龄和4龄为群组的起始龄期时,棉铃虫幼虫存活率显著低于起始龄期为5龄和6龄的群组。此外,取食正常人工饲料的幼虫存活率最高,取食缺钠饲料时,幼虫存活率明显下降。最后,幼虫群组起始龄期和食物Na⁺含量对幼虫化蛹率无明显影响。【结论】结果说明,棉铃虫4和5龄幼虫与3和6龄幼虫相比,自相残杀行为发生的概率更大,而Na⁺含量较低的食物在一定程度上促进自相残杀行为发生的可能性。本研究为在这一领域的进一步工作提供了基础。     

乙基多杀菌素对棉铃虫解毒酶和乙酰胆碱酯酶活性的影响

【目的】乙基多杀菌素(Spinetoram)是一种新型杀虫剂,为深入了解其对棉铃虫Helicoverpa armigera(Hübner)的作用效果和作用机制,本研究测定了我国不同地区田间棉铃虫种群对乙基多杀菌素的敏感基线,并比较了不同剂量(LC15、LC40、LC60和LC80)处理后棉铃虫体内解毒酶和乙酰胆碱酯酶活性的变化。【方法】采用药膜法,对采自不同地区的田间棉铃虫幼虫进行了毒力测定;采用酶标板动力学方法测定了乙基多杀菌素处理对棉铃虫幼虫4种酶活性的影响。【结果】乙基多杀菌素对棉铃虫有很好的胃毒效果,与阿维菌素相比,乙基多杀菌素杀虫活性高、见效快、不同地区间差异小;乙基多杀菌素处理后棉铃虫羧酸酯酶和谷胱甘肽-S-转移酶活性显著降低,且随着处理剂量的增加活性下降明显,各剂量处理后棉铃虫两种酶活性抑制率分别为52.14%~89.46%和8.09%~49.81%;而棉铃虫在取食含乙基多杀菌素的饲料后,各处理组棉铃虫多功能氧化酶活性表现为先升高、再降低、再升高的趋势,LC15剂量处理时活性最高,比对照增加147.75%;乙酰胆碱酯酶活性随处理剂量增加逐渐升高,活性最高比对照增加96.69%。【结论】乙基多杀菌素对棉铃虫的杀虫效果明显优于阿维菌素,具有广阔的应用前景;乙基多杀菌素处理棉铃虫引起羧酸酯酶和谷胱甘肽-S-转移酶活性降低、乙酰胆碱酯酶和多功能氧化酶活性升高。     

小分子热激蛋白基因HaHSP19.8在棉铃虫抗逆反应中的作用

【目的】小分子热激蛋白(small heat shock protein, sHSP)在昆虫抵御外界环境压力中至关重要。本研究旨在探究小分子热激蛋白sHSP19.8基因在棉铃虫Helicoverpa armigera生长发育、抵御高温胁迫和对Cry1Ac杀虫蛋白抗性机制中的作用,为更深入探析该基因作用机理及棉铃虫的防治奠定基础。【方法】通过PCR结合RACE克隆棉铃虫sHSP19.8基因序列,利用生物信息学软件对该基因序列进行分析;通过qRT-PCR测定Cry1Ac敏感棉铃虫5龄幼虫在40℃高温下处理1 h和2 h及饲喂含30 μg/mL Cry1Ac的人工饲料1 h和2 h后该基因的表达量,并测定抗感Cry1Ac棉铃虫不同发育阶段(1-5龄幼虫、蛹及成虫)和5龄幼虫不同组织(前肠、中肠、后肠、马氏管及表皮)中该基因的表达模式。【结果】获得了棉铃虫sHSP19.8基因的全长cDNA序列,命名为HaHSP19.8(GenBank登录号: XP_021195228.1),长608 bp,开放阅读框长528 bp,编码175个氨基酸残基,具有小分子热激蛋白的典型α-晶体结构域(α-crystallin domain, ACD)。该基因受40℃高温和30 μg/mL Cry1Ac杀虫蛋白诱导时在Cry1Ac敏感棉铃虫5龄幼虫中均过量表达;在Cry1Ac敏感棉铃虫整个发育阶段和5龄幼虫各组织中均表达,其中在成虫和5龄幼虫以及5龄幼虫表皮、马氏管和中肠内表达量较高;但是该基因在Cry1Ac抗性品系各个发育阶段和5龄幼虫各组织中表达量相比敏感品系都显著较低。【结论】结果说明HaHSP19.8参与棉铃虫生长发育和生理生化的过程,帮助昆虫抵御外界环境压力,并可能参与到棉铃虫对Cry1Ac的抗性机制中。     

转Bt cry1Ah基因抗虫玉米对亚洲玉米螟、棉铃虫和黏虫的抗性评价

利用农杆菌介导法将Bt cry1Ah基因转入玉米自交系综31,获得对玉米螟有显著抗性的转基因玉米HGK60,为了研究其对鳞翅目害虫的杀虫活性,在室内和田间分别用亚洲玉米螟、棉铃虫和黏虫幼虫对HGK60玉米的杀虫效果进行检测。室内生物活性检测结果表明,取食HGK60玉米心叶的亚洲玉米螟幼虫在3 d后死亡率达100%;HGK60玉米对棉铃虫幼虫有毒杀作用,玉米不同部位对棉铃虫幼虫的杀虫效果存在差异;与非转基因玉米对照相比,取食HGK60玉米叶片一周后的黏虫幼虫体重增长明显受到抑制。田间生物活性检测结果表明,HGK60玉米对于亚洲玉米螟和棉铃虫有很强的杀虫活性,达到高抗级别,对于黏虫有一定的杀虫活性,为抗性级别。     

荧光增白剂对伊朗核型多角体病毒分离株对棉铃虫幼虫的杀虫活性的增效作用（英文）

在室内条件下调查了几种荧光增白剂对采自伊朗East Azarbaijan的棉铃虫Helicoverpa armigera核型多角体病毒两个地域株(EAZ-I 和EAZ-II)对棉铃虫2龄幼虫的杀虫活性, 以提高这两个地域株的生物学活性。结果表明：与EAZ-II相比, EAZ-I的杀虫活性强,其对棉铃虫幼虫的LC₅₀和 LT₅₀ 值低（分别为1.98×103 OB/mL和122.7 h）。本研究所用的所有荧光增白剂均能有效增强病毒的生物学活性,特别是0.2% 的Tinopal F-3543与EAZ-I 混用对棉铃虫幼虫的LC50值最低(5.16×102 OB/mL),与病毒单独应用相比活性增强了3.84倍。幼虫致死的相对速率测定结果表明,荧光增白剂提高了菌株的LT₅₀值,其中Tinopal F-3543 的效果最佳。这些结果说明,在害虫综合治理中影响围食膜通透性的荧光增白剂与核型多角体病毒制剂混用是一种可供选择的重要方法。     

单宁酸对棉铃虫谷胱甘肽S转移酶的影响

通过培养基混药法,研究了植物次生物质单宁酸对棉铃虫Helicoverpa armigera（Hübner）谷胱甘肽S-转移酶活性的影响。谷胱甘肽S-转移酶活性随棉铃虫发育期的进程而变化,在卵期最低,5龄、6龄幼虫和成虫期最高。用含0.005%单宁酸的饲料饲喂棉铃虫后,5龄和6龄幼虫的谷胱甘肽S-转移酶活性明显降低,分别为对照的59%和67%。单宁酸低剂量、短时间处理棉铃虫幼虫,可诱导中肠和脂肪体中的谷胱甘肽S-转移酶的活性增加,高剂量或低剂量长时间处理没有诱导增加作用,甚至还有抑制作用。单宁酸连续处理4代,对棉铃虫6龄幼虫中肠谷胱甘肽S 转移酶均有抑制作用,对脂肪体谷胱甘肽S-转移酶活性无明显影响或有抑制作用。单宁酸处理的第4代幼虫对溴氰菊酯的敏感度有增加的趋势,对甲基对硫磷的敏感度没有明显改变。     

Stabilization of recombinant adenovirus: site-directed mutagenesis of key asparagine residues in the hexon protein

Bioelectrochemical analysis of neuropathy target esterase (NTE) and its inhibitors is based on the combination of the NTE-catalyzed hydrolysis of phenyl valerate and phenol detection by a tyrosinase carbon-paste electrode. The use of the tyrosinase electrode improves 10-fold the sensitivity of NTE detection in comparison with a spectrophotometric method. The tyrosinase electrode was found to be suitable for measurements in whole human blood where spectrophotometric detection is considerably restricted. The specificity of NTE in blood for mipafox and di-2-propyl phosphorofluoridate was close to that for neuronal NTE. The NTE-like activity in blood was determined to be 0.19 +/- 0.02 nmol/min/mg of protein.     

Peripheral biochemical marker for organophosphate-induced delayed neurotoxicity.

Neurotoxicesterase (NTE) activity was assayed in platelets of human and mice as well as in the brain of mice in vitro and in vivo. Mipafox, a well known organophosphate, to induce delayed neurotoxicity, at doses of 5, 10 and 15 mg/kg, subcutaneously, was used to examine the relationship between inhibition of brain and platelet NTE activity in mice. It was observed that the platelet NTE activity of mice was less than in humans. The optimum pH for both brain and platelet NTE of mice, and human platelets, was 8. The results indicate that mipafox produces a dose dependent inhibition of brain and platelet NTE activity in vivo and concentration dependent inhibition in vitro. It can be concluded that assay of platelet NTE can be a useful peripheral biochemical marker for organophosphate-induced delayed neurotoxicity.     

Soluble and Particulate Organophosphorus Neuropathy Target Esterase in Brain and Sciatic Nerve of the Hen, Cat, Rat, and Chick

Considerable evidence exists suggesting that the so-called neuropathy target esterase (NTE) is involved in the mechanisms responsible for organophosphorus-induced delayed polyneuropathy (OPIDP). Earlier studies in the adult hen, the habitually employed experimental model in OPIDP, have shown that most NTE activity in the brain is centered in paniculate fractions, whereas approximately 50% of this activity in the sciatic nerve is encountered in soluble form, with the rest being paniculate NTE. In the present work, we have studied the paniculate and soluble fractional distribution of paraoxon-resistant phenylvalerate esterase activity (B activity), parabxon- and mipafox-resistant phenylvalerate esterase activity (C activity), and NTE activity (B - C) according to ultracentrifugation criteria (100,000 g for 1 h). To this effect, two sensitive (adult hen and cat) and two scarcely sensitive (rat and chick) models were used. In all four experimental models, the distribution pattern was qualitatively similar: B activity and total NTE were much greater in brain (900–2, 300 nmol/min/g of tissue) than in sciatic nerve (50–100 nmol/min/g of tissue). The proportion of soluble NTE in brain was very low (<2%), whereas its presence in sciatic nerve was substantial (30–50%). The NTE/B ratio in brain was high for the particulate fraction (>60%) and low in the soluble fraction (7–30%); in sciatic nerve the ratio was about 50% in both fractions. Slight quantitative differences were observed in terms of OPIDP sensitivity: the proportion of soluble NTE in sciatic nerve was slightly higher in the sensitive animals (hen and cat: 49 and 44%, respectively) than in the rat and chick (41 and 37%, respectively), although no differences were noted in terms of concentration (in nanomoles per minute per gram of tissue). It is concluded that the distribution pattern of the activities studied is similar in all four experimental models, with no important quantitative differences directly related to species sensitivity or age.     

Recovery of neuropathy target esterase activity after inhibition with mipafox and O-hexyl O-2,5-dichlorophenyl phosphoramidate in bovine chromaffin cell cultures

Neuropathy target esterase (NTE) is a membrane protein present in various tissues whose physiological function has been recently suggested to be the maintenance of phosphatidylcholine homeostasis. Inhibition and further modification of NTE by certain organophosphorus compounds (OPs) were related to the induction of the "organophosphorus induced delayed neuropathy". Bovine chromaffin cells were cultured at 75,000cells/well in 96-well plates and exposed to 25microM mipafox or 3microM O-hexyl O-2,5-dichlorophenyl phosphoramidate (HDCP) for 60min. Inhibitors were removed by washing cells three times with Krebs solution. Then NTE activity was assayed at 0, 24, 48 and 120h after exposure using the Biomek 1000 workstation. Immediately after mipafox treatment NTE activity represented 3% of the control (6.7+/-1.9mU/10(6) cells). At 24, 48 and 120h after removing inhibitor, recorded activities were 33%, 42% and 111% of their respective controls (5.7+/-3.1; 5.7+/-1.9; 5.4+/-0.0mU/10(6) cells, respectively). Treatment with HDCP also displayed a time-dependent pattern of NTE recovery. As NTE inhibited by phosphoramidates is not reactivated in homogenized tissues, these results confirm a time-dependent regeneration of NTE after inhibition by neuropathic OPs.     

Degradation of neuropathy target esterase by the macroautophagic lysosomal pathway

AimsNeuropathy target esterase (NTE) was proposed as the initial target during the process of organophosphate-induced delayed neuropathy (OPIDN) in humans and some sensitive animals. NTE was recently identified as a novel phospholipase B that is anchored to the cytoplasmic side of the endoplasmic reticulum. However, little is known about the degradation of NTE. In this study, we have investigated the role of the macroautophagic-lysosomal pathway in NTE degradation in neuronal and non-neuronal cells.Main methodsMacroautophagy inhibitors and activators were used to interrupt the lysosomal pathway, and NTE protein level was followed using western blotting analysis. A fluorescent microscopy assay was used to determine the co-localization of NTE and lysosomes.Key findingsWestern blotting analysis showed that the macroautophagy inhibitors 3-methyladenine and ammonium chloride increased the levels of a heterologously expressed NTE-GFP fusion protein as well as endogenous NTE. Starvation had the opposite effect. The role of macroautophagy in NTE degradation was further supported by the co-localization of exogenous NTE with lysosomes in starved COS7 cells. Furthermore, the contribution of NTE activity and protein domains to the degradation of NTE by macroautophagy was investigated, showing that both the transmembrane and regulatory domains played a role in the degradation of NTE and that the catalytic domain, and thus NTE activity, was not involved.SignificanceOur findings clearly demonstrate, for the first time, that the macroautophagy/lysosome pathway plays a role in controlling NTE quantity, providing a further understanding of the function of NTE.     

Inhibition of neuropathy target esterase expressing by antisense RNA does not affect neural differentiation in human neuroblastoma (SK-N-SH) cell line

Neuropathy target esterase (NTE) is phosphorylated and aged by oraganophosphorus compounds (OP) that induce delayed neuropathy in human and some animals. NTE has been proposed to play a role in neurite outgrowth and process elongation during neural differentiation. However, to date, there is no direct evidence of the relevance of NTE in neural differentiation under physiological conditions. In this study we have investigated a possible role for NTE in the all-trans retinoic acid (ATRA)-induced differentiation of neuroblastoma cells by antisense RNA. A NTE antisense RNA construct was generated and then transfected into human neuroblastoma SK-N-SH cells. A positive cell clone that can stably express NTE antisense RNA was obtained by G418 selection and then identified by western blotting. NTE activity was depressed in the transfected cells with only about 50% activity of the enzyme in the control cells. ATRA-induced differentiation of the neuroblastoma cells with lowered NTE activity revealed that inhibition of NTE expression does not affect neural differentiation in SK-N-SH cells. The result suggested that organophosphates may inhibit neural differentiation by initially acting on other targets other than NTE.     

Target size of neurotoxic esterase and acetylcholinesterase as determined by radiation inactivation.

The target size of neurotoxic esterase (NTE), the putative target site for the initiation of organophosphorus-compound-induced delayed neurotoxicity, and acetylcholinesterase (AChE) from hen brain were examined by determining the rate at which the activities of the esterases were destroyed by ionizing irradiation. Samples of hen brain were prepared by slowly drying a microsomal preparation under vacuum. The dried samples were then irradiated with electrons from a 1 MeV Van de Graaff generator. The doses ranged from 0 to 28 Mrad. The radiation doses were calibrated by the rate of inactivation of T1-bacteriophage plaque induction. Following the irradiation procedure, the samples were resuspended in buffer and enzymic activity was measured. The target size of NTE from hen brain was determined to be about 105 kDa, whereas hen brain AChE was found to have a target size of about 53 kDa. The target size of NTE was found to be similar in experiments with rat brain and cat brain. In addition, commercial preparations of electric-eel electric-organ AChE and horse serum butyrylcholinesterase were found to have target sizes that were identical with each other, and also were very similar to that of AChE from hen brain.     

Neuropathy Target Esterase: Rates of Turnover In Vivo Following Covalent Inhibition with Phenyl Di-n-Pentylphosphinate

Phenyl di-n-pentylphosphinate is a reasonably stable easily synthesized inhibitor of neuropathy target esterase (NTE) with low anticholinesterase activity. Like phenylmethylsulphonyl fluoride it protects hens against neuropathic effects of compounds such as diisopropylphosphorofluoridate. At intervals up to 15 days after dosing hens (10 mg/kg s.c. to inhibit 90% NTE) assays were made of catalytically active and of phosphinylated NTE in autopsy tissue. The sum of these components was always within the range of catalytic activity in undosed controls. However, the half-life of reappearance of active NTE was 2.07 days +/- 0.13 (SD, n = 6) for brain and 3.62 days +/- 0.23 (SD, n = 6) for spinal cord--shorter than after dosing with phenylmethylsulphonyl fluoride. It is proposed that: (1) The physiological turnover mechanism cannot distinguish between catalytically active and di-n-pentylphosphinylated NTE although initiation of organophosphate-induced delayed polyneuropathy might involve recognition of aged di-alkyl-phosphorylated NTE as "foreign". (2) The short half-lives indicate a slow spontaneous dephosphinylation of inhibited NTE occurs in vivo as well as de novo synthesis. The difference in half-lives for brain and spinal cord NTE may be due to different rates of synthesis de novo or (more likely) to different rates of spontaneous reactivation of the inhibited NTE in the two tissues.     

G protein beta2 subunit interacts directly with neuropathy target esterase and regulates its activity

Neuropathy target esterase (NTE) was identified as the primary target of organophosphate compounds that cause a delayed neuropathy with degeneration of nerve axons. NTE is a novel phospholipase B anchored to the cytoplasmic face of endoplasmic reticulum and essential for embryonic and nervous development. However, little is known about the regulation of NTE. A human fetal brain cDNA library was screened for proteins that interact with NTE, Gbeta2 and Gbeta2-like I subunits were found to be able to bind the C-terminal of NTE in yeast. The interaction of Gbeta2 and NTE was confirmed by in vivo co-immunoprecipitation analysis in COS7 cells. Furthermore, depletion of Gbeta2 by RNA interference down regulated the activity of NTE but not its expression level. In addition, the activity of NTE was down regulated by the G protein signal pathway influencing factor, pertussis toxin, treatment in vivo. These findings suggest that Gbeta2 may play a significant role in maintaining the activity of NTE.