A Highly Efficient Method for Construction of Rice Artificial MicroRNA Vectors

Artificial microRNA (amiRNA) has become a powerful tool for gene silencing in plants. A new method for easy and rapid construction of rice artificial miRNA vector is described. The procedure involved modification of the pCAMBIA1300-UR vector by insertion of a ‘vector modification fragment’. This was prepared from the precursor of Os-amiR528 by eliminating the central miRNA-containing region while simultaneously creating an AfeI restriction site. The fragment was then introduced to the destination vector to produce a multipurpose ‘Highly Efficient gene Silencing Compatible vector’ (HESC vector). AfeI was used to produce linearized HESC vectors, and a blunt end PCR product that included amiRNA sequence was cloned into this site by a single ligation reaction to create the completed amiRNA vector. Tests showed that the method was highly efficient, and greatly reduced the time needed for vector construction and resulted in a DNA sequence identical to that of the current method, making it particularly suitable for use in a systems biology approach to functional genomic research.     

MicroRNAs with analogous target complementarities perform with highly variable efficacies in Arabidopsis

In plants, the silencing efficacy of microRNAs (miRNAs) is thought to be predominantly determined by the degree of complementarity to their target genes. Here, silencing efficacy was determined for Arabidopsis miR159 and four artificial miRNAs (amiRNAs) that all target MYB33/MYB65 with analogous complementarities. As determined through complementation of a loss-of-function mir159 mutant, the amiRNAs displayed highly variable efficacies, none of which was as strong as endogenous miR159. This was despite amiRNA expression levels being many fold-higher than miR159 in wild-type. The results highlight the variable nature of miRNA silencing efficacy in plants, where it appears that factors additional to complementarity strongly impact silencing.     

A high-efficiency gene silencing in plants using two-hit asymmetrical artificial MicroRNAs

MicroRNAs (miRNAs) are small non-coding RNA molecules that play a crucial role in gene regulation. They are produced through an enzyme-guided process called dicing and have an asymmetrical structure with two nucleotide overhangs at the 3′ ends. Artificial microRNAs (amiRNAs or amiRs) are designed to mimic the structure of miRNAs and can be used to silence specific genes of interest. Traditionally, amiRNAs are designed based on an endogenous miRNA precursor with certain mismatches at specific positions to increase their efficiency. In this study, the authors modified the highly expressed miR168a in Arabidopsis thaliana by replacing the single miR168 stem-loop/duplex with tandem asymmetrical amiRNA duplexes that follow the statistical rules of miRNA secondary structures. These tandem amiRNA duplexes, called “two-hit” amiRNAs, were shown to have a higher efficiency in silencing GFP and endogenous PDS reporter genes compared to traditional “one-hit” amiRNAs. The authors also demonstrated the effectiveness of “two-hit” amiRNAs in silencing genes involved in miRNA, tasiRNA, and hormone signalling pathways, individually or in families. Importantly, “two-hit” amiRNAs were also able to over-express endogenous miRNAs for their functions. The authors compare “two-hit” amiRNA technology with CRISPR/Cas9 and provide a web-based amiRNA designer for easy design and wide application in plants and even animals.     

转人工miRNA抗玉米粗缩病毒载体玉米的培育及其抗病能力

玉米是重要的粮食作物,水稻黑条矮缩病毒(RBSDV)是玉米粗缩病的病原,由其引起的玉米粗缩病给玉米生产造成重大损失。利用人工mi RNA构建抗病毒植物的技术已经在多种植物中被证明有效,但是在玉米中的尝试未见报道。实验根据玉米zea-mi R159a的前体序列和RBSDV基因组中编码功能蛋白的基因和基因沉默抑制子的序列信息设计引物,构建了用于沉默RBSDV编码基因和基因沉默抑制子的ami RNA(Artificial mi RNA)基因。构建p CAMBIA3301-121-ami RNA植物表达载体,利用农杆菌介导法转化玉米自交系综31(Z31)。对转基因玉米进行分子检测,选择mi RNA表达量高的纯合体株系进行自然发病实验,按0-4的分级标准调查玉米粗缩病的严重度。结果表明,转抗粗缩病毒人工mi RNA载体玉米纯合体株系的抗病表现好于野生型玉米,其中针对基因组6的S6-mi R159转基因玉米抗病情况较好。研究表明利用人工mi RNA技术构建抗病毒病玉米新品种是可行的。     

Artificial miRNA-mediated silencing of ecdysone receptor (EcR) affects larval development and oogenesis in Helicoverpa armigera

The insect pests are real threat to farmers as they affect the crop yield to a great extent. The use of chemical pesticides for insect pest control has always been a matter of concern as they pollute the environment and are also harmful for human health. Bt (Bacillus thuringensis) technology helped the farmers to get rid of the insect pests, but experienced a major drawback due to the evolution of insects gaining resistance towards these toxins. Hence, alternative strategies are high on demand to control insect pests. RNA-based gene silencing is emerging as a potential tool to tackle with this problem. In this study, we have shown the use of artificial microRNA (amiRNA) to specifically target the ecdysone receptor (EcR) gene of Helicoverpa armigera (cotton bollworm), which attacks several important crops like cotton, tomato chickpea, pigeon pea, etc and causes huge yield losses. Insect let-7a precursor miRNA (pre-miRNA) backbone was used to replace the native miRNA with that of amiRNA. The precursor backbone carrying the 21 nucleotide amiRNA sequence targeting HaEcR was cloned in bacterial L4440 vector for in vitro insect feeding experiments. Larvae fed with Escherichia coli expressing amiRNA-HaEcR showed a reduction in the expression of target gene as well as genes involved in the ecdysone signaling pathway downstream to EcR and exhibited mortality and developmental defects. Stem-loop RT-PCR revealed the presence of amiRNA in the insect larvae after feeding bacteria expressing amiRNA-HaEcR, which was otherwise absent in controls. We also found a significant drop in the reproduction potential (oogenesis) of moths which emerged from treated larvae as compared to control. These results demonstrate the successful use of an insect pre-miRNA backbone to express amiRNA for gene silencing studies in insects. The method is cost effective and can be exploited as an efficient and alternative tool for insect pest management.     

Expression of artificial microRNAs in tomato confers efficient and stable virus resistance in a cell-autonomous manner

Expression of artificial microRNAs (amiRNAs) in plants can target and degrade the invading viral RNA, consequently conferring virus resistance. Two amiRNAs, targeting the coding sequence shared by the 2a and 2b genes and the highly conserved 3′ untranslated region (UTR) of Cucumber mosaic virus (CMV), respectively, were generated and introduced into the susceptible tomato. The transgenic tomato plants expressing amiRNAs displayed effective resistance to CMV infection and CMV mixed with non-targeted viruses, including tobacco mosaic virus and tomato yellow leaf curl virus. A series of grafting assays indicate scions originated from the transgenic tomato plant maintain stable resistance to CMV infection after grafted onto a CMV-infected rootstock. However, the grafting assay also suggests that the amiRNA-mediated resistance acts in a cell-autonomous manner and the amiRNA signal cannot be transmitted over long distances through the vascular system. Moreover, transgenic plants expressing amiRNA targeting the 2a and 2b viral genes displayed slightly more effective to repress CMV RNA accumulation than transgenic plants expressing amiRNA targeting the 3′ UTR of viral genome did. Our work provides new evidence of the use of amiRNAs as an effective approach to engineer viral resistance in the tomato and possibly in other crops.     

Multi‐targeting of viral RNAs with synthetic trans‐acting small interfering RNAs enhances plant antiviral resistance

RNA interference (RNAi)‐based tools are used in multiple organisms to induce antiviral resistance through the sequence‐specific degradation of target RNAs by complementary small RNAs. In plants, highly specific antiviral RNAi‐based tools include artificial microRNAs (amiRNAs) and synthetic trans‐acting small interfering RNAs (syn‐tasiRNAs). syn‐tasiRNAs have emerged as a promising antiviral tool allowing for the multi‐targeting of viral RNAs through the simultaneous expression of several syn‐tasiRNAs from a single precursor. Here, we compared in tomato plants the effects of an amiRNA construct expressing a single amiRNA and a syn‐tasiRNA construct expressing four different syn‐tasiRNAs against Tomato spotted wilt virus (TSWV), an economically important pathogen affecting tomato crops worldwide. Most of the syn‐tasiRNA lines were resistant to TSWV, whereas the majority of the amiRNA lines were susceptible and accumulated viral progenies with mutations in the amiRNA target site. Only the two amiRNA lines with higher amiRNA accumulation were resistant, whereas resistance in syn‐tasiRNA lines was not exclusive of lines with high syn‐tasiRNA accumulation. Collectively, these results suggest that syn‐tasiRNAs induce enhanced antiviral resistance because of the combined silencing effect of each individual syn‐tasiRNA, which minimizes the possibility that the virus simultaneously mutates all different target sites to fully escape each syn‐tasiRNA.     

Improving panicle exsertion of rice cytoplasmic male sterile line by combination of artificial microRNA and artificial target mimic

The adoption of hybrid rice caused the second leap in rice yield after the ‘green revolution’ and contributes substantially to food security of China and the world. However, almost all cytoplasmic male sterile lines (A lines) as females of hybrid rice have a natural deficiency of ‘panicle enclosure’, which blocks pollination between the A line and the fertility restorer line as the male (R line) of hybrid rice and decreases seed yield. In hybrid rice seed production, exogenous ‘920’ (the active ingredient is gibberellin A₃) must be applied to eliminate or alleviate panicle enclosure of the A line; however, this not only increases production cost and pollutes the environment, it also decreases seed quality. In this study, we designed a transgenic approach to improve plant height and panicle exsertion of the A line to facilitate hybrid rice production and maintain the semi‐dwarf plant type of the hybrid. This approach comprising two components—artificial microRNA (amiRNA) and artificial target mimicry—can manipulate the differential expression of the endogenous Eui1 gene that is associated with rice internode elongation in the A line and the hybrid. amiRNA is a recently developed gene silencing method with high specificity, while target mimicry is a natural mechanism inhibiting the miRNA function that was also recently characterized. This approach provides a paradigm to tune the expression of endogenous genes to achieve the desired phenotype by combining amiRNA and artificial target mimicry technologies.     

Identification of novel microRNA-like-coding sites on the long-stem microRNA precursors in Arabidopsis

Plant microRNA (miRNA) is a crucial regulator of gene expression. It has been reported that more than one miRNA/miRNA* duplex could be produced from a microRNA precursor (pre-miRNA). In this study, we performed a comprehensive search for the novel miRNA candidates on the pre-miRNAs of Arabidopsis. AGO1 enrichment, co-existence of the miRNA*-like coordinates, and unique genome-wide match sites were taken into consideration for candidate screening. As a result, 43 miRNA-like candidates derived from 25 pre-miRNAs were identified. Among these candidates, 31 strong candidates from 22 pre-miRNAs passed all the filtering steps. Interestingly, some of these miRNA-like candidates showed organ-specific expression patterns. After target prediction and degradome sequencing data-based validation, five miRNA candidate–target pairs (ath-miR863-5p.2–AT1G76550.1, ath-miR822.2–AT5G03552.1, ath-miR822.3–AT5G02350.1, sRNA4–AT1G66290.1 and sRNA6–AT1G66310.1) were identified, providing a basis for in-depth functional analysis of these miRNA candidates. These results could update the current understanding of the biogenesis and the action of the plant miRNAs.     

A novel approach for the construction of plant amiRNA expression vectors

Artificial microRNA (amiRNA) technology has been applied in Arabidopsis thaliana and other plants to efficiently silence target genes of interest. Here we described a novel approach to construct plant amiRNA expression vectors with seamless enzyme-free cloning (SEFC) and mating-assisted genetically integrated cloning (MAGIC). Two pairs of primers were designed when the loop of amiRNA precursor was longer than 60 bp while three oligonucleotides were used to amplify the linearized vector containing the amiRNA precursor whose loop was smaller than 60 bp. The PCR products were transformed into Escherichia coli to generate the donor plasmid containing the amiRNA expression cassette through homologous recombination in vivo. The amiRNA expression cassette was then transferred to the recipient plasmid via MAGIC and an amiRNA expression plasmid was created. More than 200 amiRNA expression vectors were generated with this approach, three of which have been transformed into A. thaliana and successfully silence the target genes. Given its low-cost and simplicity, this novel approach of plant amiRNA expression vectors construction will benefit the study of individual gene function and establishment of plant amiRNA libraries.     

Molecular Evolution of a Viral Non-Coding Sequence under the Selective Pressure of amiRNA-Mediated Silencing

Plant microRNAs (miRNA) guide cleavage of target mRNAs by DICER-like proteins, thereby reducing mRNA abundance. Native precursor miRNAs can be redesigned to target RNAs of interest, and one application of such artificial microRNA (amiRNA) technology is to generate plants resistant to pathogenic viruses. Transgenic Arabidopsis plants expressing amiRNAs designed to target the genome of two unrelated viruses were resistant, in a highly specific manner, to the appropriate virus. Here, we pursued two different goals. First, we confirmed that the 21-nt target site of viral RNAs is both necessary and sufficient for resistance. Second, we studied the evolutionary stability of amiRNA-mediated resistance against a genetically plastic RNA virus, TuMV. To dissociate selective pressures acting upon protein function from those acting at the RNA level, we constructed a chimeric TuMV harboring a 21-nt, amiRNA target site in a non-essential region. In the first set of experiments designed to assess the likelihood of resistance breakdown, we explored the effect of single nucleotide mutation within the target 21-nt on the ability of mutant viruses to successfully infect amiRNA-expressing plants. We found non-equivalency of the target nucleotides, which can be divided into three categories depending on their impact in virus pathogenicity. In the second set of experiments, we investigated the evolution of the virus mutants in amiRNA-expressing plants. The most common outcome was the deletion of the target. However, when the 21-nt target was retained, viruses accumulated additional substitutions on it, further reducing the binding/cleavage ability of the amiRNA. The pattern of substitutions within the viral target was largely dominated by G to A and C to U transitions.     

Improved method for constructing plant amiRNA vectors with blue-white screening and MAGIC

Artificial microRNA (amiRNA) technology is a novel tool in reverse genetic research for discovering or validating gene functions in plants. A convenient cloning strategy has been developed to construct plant amiRNA vectors based on lacO reconstruction and mating-assisted, genetically-integrated cloning (MAGIC). The amiRNA precursor fragment was generated by PCR and inserted into a small donor plasmid through reconstruction of integrated lacO sequence. Blue recombinants were selected on plates containing X-gal and the efficiency of successful clones was 100%. The amiRNA expression cassette was transferred from the donor plasmid to the recipient plasmid p1301-gfp through MAGIC and an amiRNA expression plasmid was created. More than 40 plant amiRNA vectors were generated through this method, one of which was transformed into Arabidopsis thaliana and the target gene was silenced efficiently. The approach will be useful for amiRNA expression vectors construction in plants.     

MIGS: miRNA-induced gene silencing

Gene silencing is an important tool in the study of gene function. Virus-induced gene silencing (VIGS) and hairpin RNA interference (hpRNAi), both of which rely on small interfering RNAs, together with artificial microRNAs (amiRNA), are amongst the most popular methods for reduction of gene activity in plants. However, all three approaches have limitations. Here, we introduce miRNA-induced gene silencing (MIGS). This method exploits a special 22-nucleotide miRNA of Arabidopsis thaliana, miR173, which can trigger production of another class of small RNAs called trans-acting small interfering RNAs (tasiRNAs). We show that fusion of gene fragments to an upstream miR173 target site is sufficient for effective silencing of the corresponding endogenous gene. MIGS can be reliably used for the knockdown of a single gene or of multiple unrelated genes. In addition, we show that MIGS can be applied to other species by co-expression of miR173.