A Built-In Strategy to Mitigate Transgene Spreading from Genetically Modified Corn

Transgene spreading is a major concern in cultivating genetically modified (GM) corn. Cross-pollination may cause the spread of transgenes from GM cornfields to conventional fields. Occasionally, seed lot contamination, volunteers, mixing during sowing, harvest, and trade can also lead to transgene escape. Obviously, new biological confinement technologies are highly desired to mitigate transgene spreading in addition to physical separation and isolation methods. In this study, we report the development of a built-in containment method to mitigate transgene spreading in corn. In this method, an RNAi cassette for suppressing the expression of the nicosulfuron detoxifying enzyme CYP81A9 and an expression cassette for the glyphosate tolerant 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) gene G10 were constructed and transformed into corn via Agrobacterium-mediated transformation. The GM corn plants that were generated were found to be sensitive to nicosulfuron but resistant to glyphosate, which is exactly the opposite of conventional corn. Field tests demonstrated that GM corn plants with silenced CYP81A9 could be killed by applying nicosulfuron at 40 g/ha, which is the recommended dose for weed control in cornfields. This study suggests that this built-in containment method for controlling the spread of corn transgenes is effective and easy to implement.     

RNAi and microRNA: breakthrough technologies for the improvement of plant nutritional value and metabolic engineering

This article raises the complex issue of improving plant nutritional value through metabolic engineering and the potential of using RNAi and micro RNA technologies to overcome this complexity, focusing on a few key examples. It also highlights current knowledge of RNAi and microRNA functions and discusses recent progress in the development of new RNAi vectors and their applications. RNA interference (RNAi) and microRNA (miRNA) are recent breakthrough discoveries in the life sciences recognized by the 2006 Nobel Prize in Physiology or Medicine. The importance of these discoveries relates not only to elucidating the fundamental regulatory aspects of gene expression, but also to the tremendous potential of their applications in plants and animals. Here, we review recent applications of RNAi and microRNA for improving the nutritional value of plants, discuss applications of metabolomics technologies in genetic engineering, and provide an update on the related RNAi and microRNA technologies.     

高灵敏度电化学发光PCR方法检测花椰菜花叶病毒35 S启动子

大多数转基因植物中使用花椰菜花叶病毒(cauliflower mosaic virus,CaMV)35 S作为启动子,因此可通过检测该启动子来判断植物样品中是否含有转基因成分。实验将高灵敏度电化学发光PCR方法用于检测转基因烟草中的CaMV35 S启动子,将该启动子的PCR产物与生物素标记的探针杂交,可以起到特异性筛选产物的作用;与发光标记物——三联吡啶钌标记的探针杂交,从而实现电化学发光检测。两种探针同时与待测样品的PCR产物进行杂交,进一步对样品进行特异性筛选,从而提高了检测的准确性,避免了假阳性结果的产生。实验结果表明:该法可以准确的区分待测样品中是否含有35 S启动子,从而区别转基因烟草和非转基因烟草。电化学发光PCR方法灵敏度高,可靠性强,操作简便,结果准确,有望成为一种高效的转基因植物检测方法。     

RNA干扰作用(RNAi)研究进展

RNA干扰作用 (RNAi)是生物界一种古老而且进化上高度保守的现象 ,是基因转录后沉默作用 (PTGS)的重要机制之一 .RNAi主要通过dsRNA被核酸酶切割成 2 1～ 2 5nt的干扰性小RNA即siRNA ,由siRNA介导识别并靶向切割同源性靶mRNA分子而实现 .RNAi要有多种蛋白因子以及ATP参与 ,而且具有生物催化反应特征 .RNAi是新发现的一种通过dsRNA介导的特异性高效抑制基因表达途径 ,在后基因组时代的基因功能研究和药物开发中具有广阔应用前景     

A built-in mechanism to mitigate the spread of insect-resistance and herbicide-tolerance transgenes into weedy rice populations

Background

The major challenge of cultivating genetically modified (GM) rice (Oryza sativa) at the commercial scale is to prevent the spread of transgenes from GM cultivated rice to its coexisting weedy rice (O. sativa f. spontanea). The strategic development of GM rice with a built-in control mechanism can mitigate transgene spread in weedy rice populations.

Methodology/Principal Findings

An RNAi cassette suppressing the expression of the bentazon detoxifying enzyme CYP81A6 was constructed into the T-DNA which contained two tightly linked transgenes expressing the Bt insecticidal protein Cry1Ab and the glyphosate tolerant 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS), respectively. GM rice plants developed from this T-DNA were resistant to lepidopteran pests and tolerant to glyphosate, but sensitive to bentazon. The application of bentazon of 2000 mg/L at the rate of 40 mL/m², which is approximately the recommended dose for the field application to control common rice weeds, killed all F₂ plants containing the transgenes generated from the Crop-weed hybrids between a GM rice line (CGH-13) and two weedy rice strains (PI-63 and PI-1401).

Conclusions/Significance

Weedy rice plants containing transgenes from GM rice through gene flow can be selectively killed by the spray of bentazon when a non-GM rice variety is cultivated alternately in a few-year interval. The built-in control mechanism in combination of cropping management is likely to mitigate the spread of transgenes into weedy rice populations.     

Biochemical mechanisms of suppression of RNA interference by plant viruses

RNA interference (RNAi) plays an important biological role in regulation of gene expression of eukaryotes. In addition, RNAi was shown to be an adaptive protective molecular immune mechanism against viral diseases. Antiviral RNAi initiates from generation of short interfering RNAs used in the subsequent recognition and degradation of the viral RNA molecules. As a response to protective reaction of plants, most of the viruses encode specific proteins able to counteract RNAi. This process is known as RNAi suppression. Viral suppressors act on various stages of RNAi and have biochemical properties that enable viruses to effectively counteract the protective system of plants. Modern molecular and biochemical investigations of a number of viral suppressors have significantly expanded our understanding of the complexity of the nature of RNAi suppression as well as mechanisms of interaction between viruses and plants.     

Vectors for RNAi technology in poplar

Abstract: The potential of double-stranded RNA interference (RNAi) technology was studied for down-regulation of gene expression in poplar. A set of vectors was constructed generating RNAs capable of duplex formation of sequences specific for the β-glucuronidase (GUS) reporter gene system. These gene cassettes are driven by the CaMV-35S promoter. To address the question of gene silencing, we tested the functionality of these vectors, both in transient assays by transforming protoplasts with the RNAi constructs, and in stably transformed GUSexpressing poplar plants. Agrobacterium -mediated transformation of those GUS-expressing plants with a GUS-specific RNAi construct showed a strong down-regulation of the reporter gene. From these results we conclude that RNAi is also functional in poplar.     

Argonaute蛋白与小RNA的作用机制

RNA干扰(RNA interference, RNAi)是在植物、动物、线虫、真菌以及昆虫等生物体中普遍存在的通过双链RNA(double strand RNA, dsRNA)诱导的抑制同源基因表达的一种保守的调控机制.小分子RNA通过特异性地识别结合RNA诱导的沉默复合体（RNA-induced silencing complex, RISC）对目标mRNA的表达在转录和翻译水平进行抑制.作为RISC的重要组成成分,Argonaute蛋白（Ago）发挥了至关重要的作用.为了进一步阐明Ago蛋白在RNA干扰中对小分子RNA的作用机制,本文介绍了Ago蛋白的结构、分类及其在RNA干扰机制中的作用,并着重阐述了目前已知的植物Ago蛋白对小分子RNA的几种作用机制,以及目前研究发现的Ago蛋白的功能作用,从而更进一步证实Ago蛋白对小分子RNA的作用是一个复杂的过程.     

RNA干扰抗病毒感染

RNA干扰是由双链RNA诱导的、关闭同源序列基因表达的机制。它是一种自然存在于植物、线虫、果蝇等真核细胞生物中的抵抗病毒感染方式。随着在哺乳动物细胞培养中成功地诱导RNA干扰,利用RNA干扰预防、治疗病毒感染已成为新的研究热点,并取得了有希望的成果。在未来,有望成为抗病毒感染的有效方法。     

基于RNAi技术的转基因植物研究进展

RNA干扰（RNA interference,RNAi）是指由双链RNA（double-stranded RNA,dsRNA）诱发同源mRNA高效特异性降解的现象,在真核生物中普遍存在且进化保守。RNAi技术作为21世纪初的重大科学成就,目前被广泛应用于疾病防治、基因功能研究、植物改良育种等领域。RNAi技术常与转基因技术结合用于植物改良育种,通过不同的载体设计或作用途径来研发满足生产需要的农业生物技术产品。为了明确现阶段基于RNAi技术的转基因植物育种技术进展,综述了RNAi现象的发现和作用机制、转基因载体设计、小RNA（small RNA,sRNA）的递送方式等方面的研究进展,并阐述了基于RNAi技术的转基因植物的研究实例和商业化情况,以期为相关研究提供参考,从而发挥RNAi技术的最大应用价值,使之服务于新时代的农业发展。     

基于RNAi技术的转基因植物监管现状及其面临的育种领域的挑战

RNA干扰（RNA interference,RNAi）在植物、动物和真菌的生长、发育、病毒防御和转座子失活中起着至关重要的作用。目前已成功利用RNAi技术培育出抗病虫和品质改良等具有优良性状的生物技术产品,为农业绿色发展提供了强有力的支撑。然而,目前RNAi的相关机制尚未完全明确,基于RNAi技术的转基因植物面临着一些亟待解决的问题,同时,对于RNAi转基因植物应用的安全高效监管也需进一步完善。基于此,对RNAi转基因植物的监管现状及其面临的育种上的挑战进行了综述,并对存在的问题提出了解决建议,以期为RNAi技术进一步应用于农业植物改良育种提供新思路,并为其监管评价提供依据。     

Cisgenics - A Sustainable Approach for Crop Improvement

The implication of molecular biology in crop improvement is now more than three decades old. Not surprisingly, technology has moved on, and there are a number of new techniques that may or may not come under the genetically modified (GM) banner and, therefore, GM regulations. In cisgenic technology, cisgenes from crossable plants are used and it is a single procedure of gene introduction whereby the problem of linkage drag of other genes is overcome. The gene used in cisgenic approach is similar compared with classical breeding and cisgenic plant should be treated equally as classically bred plant and differently from transgenic plants. Therefore, it offers a sturdy reference to treat cisgenic plants similarly as classically bred plants, by exemption of cisgenesis from the current GMO legislations. This review covers the implications of cisgenesis towards the sustainable development in the genetic improvement of crops and considers the prospects for the technology.     

Orgenic plants: Gene‐manipulated plants compatible with organic farming

Based on recent advances in plant gene technology, I propose to develop a new category of GM plants, orgenic plants, that are compatible with organic farming. These orgenic plants do not contain herbicide resistance genes to avoid herbicide application in agriculture. Furthermore, they either contain genes that are naturally exchanged between species, or are sterile to avoid outcrossing if they received a transgene from a different species. These GM plants are likely to be acceptable to most sceptics of GM plants and facilitate the use of innovative new crops.     

Multitrophic interactions involving genetically modified potatoes, nontarget aphids, natural enemies and hyperparasitoids

Genetically modified (GM) potatoes expressing a cysteine proteinase inhibitor (cystatin) have been developed as an option for the management of plant parasitic nematodes. The relative impact of such plants on predators and parasitoids (natural enemies) of nontarget insects was determined in a field trial. The trial consisted of GM plants, control plants grown in soil treated with a nematicide and untreated control plants. The quantity of nontarget aphids and their quality as hosts for natural enemies were studied. Aphid density was significantly reduced by nematicide treatment and few natural enemies were recorded from treated potatoes during the study. In contrast, similar numbers of aphids and their more abundant predators were recorded from the untreated control and the GM potatoes. The size of aphids on GM and control plants was recorded twice during the study. During the first sampling period (2-9 July) aphids clip-caged on GM plants were smaller than those on control plants. During the second sampling period (23-30 July) there was no difference in aphid size between those from the GM and control plants. Host size is an important component of host quality. It can affect the size and fecundity of parasitoid females and the sex ratio of their offspring. However, neither the fitness of females of Aphidius ervi, the most prevalent primary parasitoid, nor the sex ratio of their progeny, were affected when the parasitoids developed on aphids feeding on GM plants. Two guilds of secondary parasitoid were also recorded during the study. The fitness of the most abundant species, Aspahes vulgaris, was not affected when it developed on hosts from GM plants. The transgene product, OC I Delta D86, was not detected in aphids that had fed on GM plants in the field, suggesting that there is minimal secondary exposure of natural enemies to the inhibitor. The results indicate that transgenic nematode resistance is potentially more compatible with aphid biological control than is current nematicide use.