转抗虫基因植物对蜜蜂的影响

苏云金杆菌 (Bacillusthuringiensis,Bt)毒蛋白基因、蛋白酶抑制剂基因是广泛用于植物抗虫基因工程的两大类基因。Bt毒蛋白对蜜蜂没有明显毒害作用 ,但对草蛉、瓢虫等有益昆虫的繁殖、发育具有不良影响 ,而且在花粉中表达 ,因此转Bt基因植物对蜜蜂的影响有待于进一步研究。蛋白酶抑制剂浓度高时 ,对蜜蜂具有明显的毒害作用。随着基因工程技术的发展 ,蛋白酶抑制剂基因表达水平的提高 ,转基因植物必将对蜜蜂产生一些不良影响。蜜蜂仅取食植物的花蜜和花粉 ,可以采用不同的启动子 ,使抗虫基因只在害虫取食部位表达 ,而在花蜜和花粉中不表达 ,以确保既能抗虫 ,又对蜜蜂安全     

水稻半胱氨酸蛋白酶抑制剂基因的克隆及其mRNA在水稻中的组成型表达

从40年代发现豆科植物中存在蛋白酶蛋白抑制剂以来,在动物、植物和微生物体内已发现普遍存在着多种类型的蛋白酶抑制剂(PI)。人们往往是为了研究某种蛋白酶的作用机制或出于某种应用目的去分离和研究PI的,对PI的真正生理功能尚不十分清楚。一般认为除防止体内不必要的蛋白降解作用、调节蛋白代谢及调节各种蛋白酶的生理活性外,很多植物的PI还具有抑制某些病源微生物及某些昆虫体内蛋白酶的作用,从而对植物有防卫功能。Hilder等和Johnson等已分别将属于丝氨酸蛋白酶抑制剂的豇豆蛋白酶抑制剂及马铃薯PⅠⅠ和PⅠⅡ基因转入烟草,结果转基因烟草对烟芽夜蛾(He-     

昆虫消化酶抑制剂与害虫防治

生物源昆虫消化酶抑制剂主要包括蛋白酶抑制剂和淀粉酶抑制剂。昆虫消化酶抑制剂能通过降低或抑制昆虫蛋白酶或淀粉酶的活性,而影响昆虫的正常生长发育,使其生长缓慢,虚弱,甚至导致死亡。本文就生物源昆虫消化酶抑制剂对昆虫生化、生理代谢和生长发育的影响,消化酶抑制剂的作用机理,植物中昆虫消化酶抑制剂的诱导产生等进行了介绍。同时,探讨了生物源蛋白酶和淀粉酶抑制剂在害虫防治中的应用前景。     

植物蛋白酶抑制剂及其在抗虫植物基因工程中的应用

植物蛋白酶抑制剂（proteinase inhibitors,PI)能与昆虫蛋白酶的活性部位或变构部位结合,抑制酶的催化活性,导致昆虫发育不正常甚至死亡。蛋白酶抑制剂基因是抗虫基因工程中一类重要的目的基因,具有作用位点独特,抗虫谱广等独持优点。本文从蛋白酶抑制剂的分类,作用机制,转基因研究及其应用前景等方面进行了综述。     

植物蛋白酶抑制剂在植物抗虫与抗病中的作用

综述了植物蛋白酶抑制剂抗虫与抗病作用的研究进展.蛋白酶抑制剂广泛存在于植物体内,与植物抗虫抗病密切相关.植物蛋白酶抑制剂能抑制昆虫肠道蛋白酶,使昆虫生长发育缓慢,甚至死亡.但取食蛋白酶抑制剂后,昆虫能迅速分泌对抑制剂不敏感的蛋白酶,而使蛋白酶抑制剂无效.食物蛋白的含量和质量也影响植物蛋白酶抑制剂的抗虫效果.病原菌的感染能诱导植物产生蛋白酶抑制剂,诱导产生的蛋白酶抑制剂能抑制病原菌的生长.     

抗虫转基因植物的研究进展及前景

虫害对农业生产的危害日益严重。目前对害虫的防治主要依赖于化学药物,但化学药物的副作用不容忽视。利用植物基因工程获得抗虫转基因植物是更具前景的途径。目前主要利用的抗虫基因是苏云金杆菌的δ－内毒素基因和植物来源的抗虫基因（如蛋白酶抑制剂基因、淀粉酶抑制剂基因、凝集素基因等）,各种抗虫基因在转基因应用中各有其优缺点,如苏云金杆菌δ－内毒素基因是植物中表达水平低。随着抗虫转基因植物在大田中的应用,昆虫的抗     

抗虫转基因植物的研究进展及前景

虫害对农业生产的危害日益严重。目前对害虫的防治主要依赖于化学药物,但化学药物的副作用不容忽视。利用植物基因工程获得抗虫转基因植物是更具前景的途径。目前主要利用的抗虫基因是苏云金杆菌的δ－内毒素基因和植物来源的抗虫基因（如蛋白酶抑制剂基因、淀粉酶抑制剂基因、凝集素基因等）,各种抗虫基因在转基因应用中各有其优缺点,如苏云金杆菌δ－内毒素基因在植物中表达水平低。随着抗虫转基因植物在大田中的应用,昆虫的抗性或适应性问题也随之产生,这将是转基因植物发展道路上又一挑战。     

蛋白酶抑制剂及其在抗虫基因工程中的应用

蛋白酶抑制剂可以抑制昆虫的生长和发育,近年来在抗虫基因工程得广泛的应用。本文综述了蛋白酶抑制剂及其抗虫性,蛋白酶抑制剂转基因植物的研究概况,同时探讨了蛋白酶抑制剂在抗虫基因工程中的利用前景、存在问题和解决途径。     

转基因抗虫烟草研究进展

烟草为模式植物,也是外源杀虫基因最早转化成功的植物。文章从转Bt内毒素基因,植物凝集素GNA,Plec,AHA基因,蛋白酶抑制剂PIⅠ,PIⅡ,MTI,SKTI基因,昆虫特异性神经毒素基因,几丁质酶基因,畸形细胞分泌蛋白基因以及双抗虫基因等方面综述了转基因抗虫烟草的抗虫性、转基因抗虫烟草的经济性状等,展望了转基因抗虫烟草的研究和应用前景,以期对烟草害虫的治理尤其是对其他转基因抗虫作物的培育和研究有借鉴作用。     

慈菇蛋白酶抑制剂研究进展

蛋白酶抑制剂是一类能够抑制蛋白水解酶活性的物质。根据它们抑制的蛋白酶类型可分为丝氨酸、半胱氨酸、天冬氨酸、和金属蛋白酶抑制剂[1] 。由于它们能抑制昆虫肠道内以及一些病原微生物体内的蛋白酶[2～ 6 ] ,因此蛋白酶抑制剂在植物对昆虫和病原体的侵染防御系统中具有重要的作用。慈菇蛋白酶抑制剂Ａ、Ｂ是从慈菇球茎中分离纯化的双头多功能蛋白酶抑制剂 ,除了具备其他蛋白酶抑制剂在抗虫抗病方面的特点外 ,还有很多独特的优点。如 ,含量丰富、比活力高而且稳定 ;广谱性强 ;对胰蛋白酶、胰凝乳蛋白酶、激肽释放酶等多种蛋白酶有较强的抑…     

The multiple functions of plant serine protease inhibitors: Defense against herbivores and beyond

Plant protease inhibitors (PIs) are a diverse group of proteins which have been intensely investigated due to their potential function in protecting plants against herbivorous insects by inhibiting digestive proteases. Although this mechanism has been well documented for a number of single PIs and their target enzymes, whether this mechanism protects plants in nature remains unclear. Moreover, many plants express a number of different PIs and it was unknown if these proteins work synergistically as defenses or if they also have other functions. We recently identified four serine PIs (SPI) of Solanum nigrum and demonstrated that they differ substantially in substrate specificity, accumulation patterns, and their effect against different natural herbivorous insects in field- and glasshouse experiments. These differences suggest that SPIs have at least partially diversified to provide protection against different attackers. Although we could not detect effects on plant development or growth when silencing SPIs, gene- and tissue-specific expression patterns suggest multiple functions in generative tissues, including a possible involvement in development.Key words: plant protease inhibitors, plant defense, Solanum nigrum, neo-functionalization     

The adaptation of insects to plant protease inhibitors

Plants and herbivores have been co-evolving for thousands of years, and as a result, plants have defence mechanisms that offer protection against many herbivores such as nematodes, insects, birds and mammals. Only when a herbivore has managed to adapt to these defence mechanisms does it have the potential to become a pest. One such method of plant defence involves the production of protease inhibitors (PIs). These inhibitors are proteins that may be found constitutively in various parts of the plant, or may be induced in response to herbivore attack. PIs work at the gut level, by inhibiting the digestion of plant protein. This review focuses on insect herbivores and looks at the mechanisms involved in the role and function of PIs in plant defense against insects, as well as at the ability of well adapted species to overcome the effects of these plant PIs.     

Effects of class-specific,synthetic, and natural proteinase inhibitors on life-history traits of the cotton bollworm Helicoverpa armigera

Herbivorous insects have more difficulty obtaining proteins from their food than do predators and parasites. The scarcity of proteins in their diet requires herbivores to feed voraciously, thus heavily damaging their host plants. Plants respond to herbivory by producing defense compounds, which reduce insect growth, retard development, and increase mortality. Herbivores use both pre- and postdigestive response mechanisms to detect and avoid plant defense compounds. Proteinase inhibitors (PIs) are one example of plant compounds produced as a direct defense against herbivory. Many insects can adapt to PIs when these are incorporated into artificial diets. However, little is known about the effect of PIs on diet choice and feeding behavior. We monitored the diet choice, life-history traits, and gut proteinase activity of Helicoverpa armigera larvae using diets supplemented with synthetic and natural PIs. In choice experiments, both neonates and fourth-instar larvae preferred the control diet over PI-supplemented diets, to varying degrees. Larvae that fed on PI-supplemented diets weighed less than those that fed on the control diet and produced smaller pupae. Trypsin-specific PIs had a stronger effect on mean larval weight than did other PIs. A reduction of trypsin activity but not of chymotrypsin activity was observed in larvae fed on PI-supplemented diets. Therefore, behavioral avoidance of feeding on plant parts high in PIs could be an adaptation to minimize the impact of this plant's defensive strategy.     

Herbivore damage-induced production and specific anti-digestive function of serine and cysteine protease inhibitors in tall goldenrod, Solidago altissima L. (Asteraceae)

Plant protease inhibitors (PIs) are among the most well-studied and widely distributed resistance traits that plants use against their herbivore attackers. There are different types of plant PIs which putatively function against the different types of proteases expressed in insect guts. Serine protease inhibitors (SPIs) and cysteine protease inhibitors (CPIs) are hypothesized to differentially function against the predominant gut proteases in lepidopteran and coleopteran herbivores, respectively. Here, we test the hypothesis that tall goldenrod, Solidago altissima, can specifically respond to damage by different herbivores and differentially induce SPIs and CPIs in response to damage by lepidopteran and coleopteran herbivores. Moreover, we ask if the concerted induction of different types of PIs accounts for variation in induced resistance to herbivory. We altered and optimized a rapid and effective existing methodology to quantitatively analyze both SPI and CPI activity simultaneously from a single tissue sample and to use the same plant extracts directly for characterization of inhibitory effects on insect gut protease activity. We found that both SPIs and CPIs are induced in S. altissima in response to damage, regardless of the damaging herbivore species. However, only SPIs were effective against Spodoptera exigua gut proteases. Our data suggest that plant PI responses are not necessarily specific to the identity of the attacking organism but that different components of generally induced defense traits can specifically affect different herbivore species. While providing an efficient and broadly applicable methodology to analyze multiple PIs extracted from the same tissue, this study furthers our understanding of specificity in induced plant resistance.     

植物蛋白酶抑制素抗虫作用的研究进展

植物自身为抵抗昆虫等的为害,在长期进化过程中形成了复杂的化学防御体系,其中起主导作用的是一些植物化学物质。这些化合物能影响昆虫（或其它有机体）的生长、行为和群体生物学,因而又称为它感素（allelochemics）[1～3]。大多数它感素为植物的利己素,可以单一或协同对害虫起作用,构成植物的抗虫性。根据植物对昆虫取食的反应,可将植物的化学防御概括为两类：一类是组成型防御[4],即抗虫物质不依赖于昆虫的取食而存在于植物组织中;另一类是诱导型防御[5～9],即植物仅当昆虫取食时才大量合成抗虫物质。诱导型抗虫物质当然亦可以组…     

Structural and functional characteristics of plant proteinase inhibitor-II (PI-II) family

Plant proteinase inhibitor-II (PI-II) proteins are one of the promising defensive proteins that helped the plants to resist against different kinds of unfavorable conditions. Different roles for PI-II have been suggested such as regulation of endogenous proteases, modulation of plant growth and developmental processes and mediating stress responses. The basic knowledge on genetic and molecular diversity of these proteins has provided significant insight into their gene structure and evolutionary relationships in various members of this family. Phylogenetic comparisons of these family genes in different plants suggested that the high rate of retention of gene duplication and inhibitory domain multiplication may have resulted in the expansion and functional diversification of these proteins. Currently, a large number of transgenic plants expressing PI-II genes are being developed for enhancing the defensive capabilities against insects, bacteria and pathogenic fungi. Much emphasis is yet to be given to exploit this ever expanding repertoire of genes for improving abiotic stress resistance in transgenic crops. This review presents an overview about the current knowledge on PI-II family genes, their multifunctional role in plant defense and physiology with their potential applications in biotechnology.     

Expression profile of jasmonic acid-induced genes and the induced resistance against the root-knot nematode (Meloidogyne incognita) in tomato plants (Solanum lycopersicum) after foliar treatment with methyl jasmonate

We investigated what gene(s) in the plant roots have the positive role against repressing root-knot nematode (RKN) infection. We investigated the interaction between RKN infection and gene expression in the plant roots induced by methyl jasmonate (MeJA). We focused on the induced resistance response and the duration after foliar treatment with MeJA of 0.1, 0.5, 1.0, and 5.0mM at 1, 24, 48, and 72h prior to the inoculation of RKN. As a result, the foliar treatment with MeJA at 0.5mM or higher concentrations significantly reduced the infection of RKN in plants and the effect lasted for about 1 week. The repressing effect on RKN population declined to the lowest level in two weeks after MeJA treatment. The expression of proteinase inhibitors (PIs) and multicystatin (MC) were induced while the repressing effect on RKN was valid and a negative correlation was found between the expression of PIs or MC and RKN infection. In addition, when tomato plants no longer expressing MC and PIs were treated again with MeJA, the repressing effect revived. These phenomena appeared to be regardless of the existence of Mi-genes or isolate of RKN. Our results indicate that the expression level of MC and PIs may be effective as marker genes for estimating the induced resistance response against RKN infection.     

Protease inhibitors: use to increase plant tolerance to insects and pathogens

The review deals with analysis of the possibility of the use of genes of inhibitors of proteolytic enzymes of plants to increase plant tolerance to insect pests and phytopathogens. The idea of using protease inhibitors for plant defense is strongly supported, first, by their wide distribution in plant tissues and high activity towards various proteolytic enzymes of insects, bacteria and fungi. The results obtained for the last years indicate that the genetic engineering approach is perspective for solving of this kind of problems. The main losses and advantages of the discussed approach are also considered. The described approach for increase of plant tolerance to insects and pathogens has few advantages as compared to traditional ones and belongs to ecologically pure technologies.     

Colorado potato beetles show differential digestive compensatory responses to host plants expressing distinct sets of defense proteins

Herbivorous insects fed plants expressing proteinase inhibitors (PIs) compensate for the loss of digestive proteolytic functions by producing novel proteinases. We assessed here whether such compensatory responses represent a general, non-specific adaptation to defense-related proteins in host plant tissues, or if distinct responses occur depending on the stress exerted on the plant. As a model, growth, development, and digestive proteases of the Colorado potato beetle (Leptinotarsa decemlineata Say) were monitored after feeding larvae with plants pre-treated with either methyl jasmonate or arachidonic acid, two compounds inducing different sets of defense genes in potato. In brief, larvae fed plants treated with jasmonate or arachidonate were negatively affected compared to larvae fed non-treated plants, suggesting the potency of both molecules to induce partial resistance to potato beetles in potato. On the other hand, larvae fed treated plants partially compensated for the presence of defense-related proteins by adapting their digestive proteolytic system, both quantitatively and qualitatively. These compensatory processes varied depending on the treatment, the larvae fed arachidonate-treated plants showing the most dramatic response. Compensation to jasmonate and arachidonate was also influenced by a cysteine PI from rice expressed in the plant, pointing out the possible indirect effects of recombinant defense proteins on naturally-occurring plant-insect interactions. These observations, while showing the potential of jasmonate and arachidonate as inducers of partial resistance to the potato beetle in potato, also suggest that digestive compensation in herbivorous insects is determined, at least in part, by defense-related compounds found in the plant in response to different stress stimuli or as a result of ectopic expression in transgenic plants.