Preferential spreading of RNA silencing into the 3’ downstream region of the transgene in tobacco

The amplification mechanism of short interfering RNAs (siRNAs) along the transgene sequence exists in RNA interference (RNAi). The RNA-dependent RNA polymerase synthesizes complementary RNAs by using the transgene mRNA as a template, and the secondary siRNAs are generated from the outside of primary RNAi target. Four independent RNAi vectors which produced primary siRNAs against distinct regions of the tobacco endoplasmic reticulum ω-3 fatty acid desaturase gene (NtFAD3) were transiently expressed in leaves of theNtF4D3-overexpressed transgenic plants. Regardless of the RNAi vector used, the secondaryNtFAD3 siRNAs were generated preferentially from the 3’ downstream region of the transgene. Secondary siRNAs from the 5’ upstream region adjacent to the annealing site of primary siRNAs accumulated under the detection level. Our results suggest that different regulatory mechanisms are involved in the spreading of RNA silencing into 5’ upstream and 3’ downstream regions of the target sequence, respectively.     

Transgene overexpression with cognate small interfering RNA in tobacco

Small interfering RNAs (siRNAs) are a key component of RNA silencing, including cosuppression. Here, we show an example in which siRNA does not serve in the downregulation of target genes. A tobacco endoplasmic reticulum omega-3 fatty acid desaturase (NtFAD3) catalyzes the formation of alpha-linolenate (18:3). Introduction of the NtFAD3 gene into tobacco plants caused strong reduction of 18:3 content in leaf tissues, which is associated with the production of the NtFAD3 siRNAs. However, this silencing effect was lacking in the root tissues. Both the introduced NtFAD3 and endogenous NtFAD3 genes were expressed successfully, and the roots showed increased 18:3 phenotype. Surprisingly, the NtFAD3 siRNAs were produced even in the root tissues. Expression of a hairpin double-stranded RNA against the NtFAD3 gene caused efficient reduction of 18:3 content in root tissues. Therefore, cosuppression of the NtFAD3 gene in tobacco appears to include an as yet unidentified developmental stage and tissue-specific mechanism of regulation of siRNA function.     

Molecular Characteristics and Efficacy of 16D10 siRNAs in Inhibiting Root-Knot Nematode Infection in Transgenic Grape Hairy Roots

Root-knot nematodes (RKNs) infect many annual and perennial crops and are the most devastating soil-born pests in vineyards. To develop a biotech-based solution for controlling RKNs in grapes, we evaluated the efficacy of plant-derived RNA interference (RNAi) silencing of a conserved RKN effector gene, 16D10, for nematode resistance in transgenic grape hairy roots. Two hairpin-based silencing constructs, containing a stem sequence of 42 bp (pART27-42) or 271 bp (pART27-271) of the 16D10 gene, were transformed into grape hairy roots and compared for their small interfering RNA (siRNA) production and efficacy on suppression of nematode infection. Transgenic hairy root lines carrying either of the two RNAi constructs showed less susceptibility to nematode infection compared with control. Small RNA libraries from four pART27-42 and two pART27-271 hairy root lines were sequenced using an Illumina sequencing technology. The pART27-42 lines produced hundred times more 16D10-specific siRNAs than the pART27-271 lines. On average the 16D10 siRNA population had higher GC content than the 16D10 stem sequences in the RNAi constructs, supporting previous observation that plant dicer-like enzymes prefer GC-rich sequences as substrates for siRNA production. The stems of the 16D10 RNAi constructs were not equally processed into siRNAs. Several hot spots for siRNA production were found in similar positions of the hairpin stems in pART27-42 and pART27-271. Interestingly, stem sequences at the loop terminus produced more siRNAs than those at the stem base. Furthermore, the relative abundance of guide and passenger single-stranded RNAs from putative siRNA duplexes was largely correlated with their 5′ end thermodynamic strength. This study demonstrated the feasibility of using a plant-derived RNAi approach for generation of novel nematode resistance in grapes and revealed several interesting molecular characteristics of transgene siRNAs important for optimizing plant RNAi constructs.     

Resistance to Phytophthora pathogens is dependent on gene silencing pathways in plants

RNA silencing is one of the main defence mechanisms employed by plants to fight pathogens. p19 protein encoded by the tomato bushy stunt virus (TBSVp19) is known as a suppressor of RNA silencing via siRNA sequestration to prevent the assembly of RISC. To better understand the impact of TBSVp19 on silencing and its roles in Phytophthora pathogens, we used the transient expression assay in Nicotiana benthamiana and found that the leaves expressing TBSVp19 were more susceptible to Phytophthora parasitica. Furthermore, we demonstrated that TBSVp19‐mediated plant susceptibility in N. benthamiana is dependent on RNA‐dependent RNA polymerase 6 (RDR6). We also tested the role of RNA silencing in resistance of soybean hairy roots to Phytophthora. The lesion size induced by P. sojae on TBSVp19‐expressing soybean hairy roots was slightly, but significantly larger than GFP‐expressing soybean hairy roots. Finally, the Arabidopsis gene silencing mutants ago1‐27, zip‐1, sgs3‐11 and rdr6‐11 were also examined for their resistance to P. parasitica. The results clearly showed that resistance levels of the mutants were visibly reduced compared with the wild type. Taken together, these results suggest that the gene silencing system in plants is essential for resistance to Phytophthora pathogens.     

Analysis of RNA Silencing in Agroinfiltrated Leaves of <Emphasis Type="Italic">Nicotiana Benthamiana</Emphasis> and <Emphasis Type="Italic">Nicotiana Tabacum</Emphasis>

In this study we analyse several aspects of cytoplasmic RNA silencing by agroinfiltration of DNA constructs encoding single- and double-stranded RNAs derived from a GFP transgene and from the endogenous Virp1 gene. Both types of inductors resulted after 2–4 days in much higher concentration of siRNAs in the agroinfiltrated zone than normally seen during systemic silencing. More specifically, infiltration of two transgene hairpin constructs resulted in elevated levels of siRNAs. However, differences between the two constructs were observed: the antisense–sense arrangement was more effective than the sense–antisense order. For both double-stranded forms, we observed a relative increase of the 24-mer size class of siRNAs. When a comparable hairpin construct of the endogenous Virp1 gene was assayed, the portion of the 24-mer siRNA class remained low as observed for all kinds of single-stranded inducers. The lack of increase of Virp1-derived 24-mers was independent of the expression level, as demonstrated by agroinfiltration into a transgenic plant that overexpressed Virp1 and showed the same pattern. Using transducer constructs, we could detect within a week transitive silencing from GFP to GUS sequences in the infiltrated zone and in either direction 5′–3′ and 3′–5′. Conversely, for the endogenous Virp1 gene neither transitive silencing nor the induction of systemic silencing could be observed. These results are discussed in view of the current models of RNA silencing.     

Gene silencing by expression of hairpin RNA in Lotus japonicus roots and root nodules

We investigated the efficacy of self-complementary hairpin RNA (hpRNA) expression to induce RNA silencing in the roots and nodules of model legume Lotus japonicus, using hairy root transformation mediated by Agrobacterium rhizogenes. Transgenic lines that express beta-glucuronidase (GUS) by constitutive or nodule-specific promoters were supertransformed by infection of A. rhizogenes harboring constructs for the expression of hpRNAs with sequences complementary to the GUS coding region. GUS activity in more than 60% of the hairy roots was decreased or silenced almost completely. Silencing of the GUS gene was also observed in symbiotic nodules formed on hairy roots in both early and late stages of nodule organogenesis. These results indicate that transient RNA silencing by hairy root transformation provides a powerful tool for loss-of-function analyses of genes that function in roots and root nodules.     

A tobacco calmodulin-related protein suppresses sense transgene-induced RNA silencing but not inverted repeat-induced RNA silencing

A tobacco calmodulin-related protein, rgs-CaM, interacts with viral suppressors of RNA silencing and modulates host RNA silencing. Plants overexpressing the rgs-CaM gene were crossed with plants exhibiting sense transgene-induced RNA silencing (S-PTGS) or inverted repeat-induced RNA silencing (IR-PTGS). S44 plants harboring a sense transgene encoding a tobacco microsomal ω-3 fatty acide desaturase (NtFAD3) exhibited the S-PTGS phenotype. The frequency of the S-PTGS phenotype incidence was nearly 100 % in the hemizygous S44 plants, but was reduced to 30 % in crossbred plants with an rgs-CaM-overexpressing transgenic line. The remaining 70 % of crossbred plants successfully overexpressed the NtFAD3 transgene, and the amount of NtFAD3 small interfering RNAs (siRNAs) was largely decreased. In contrast, overexpression of rgs-CaM did not suppress siRNA production in the IR-PTGS that targeted the NtFAD3 gene. These results indicated that rgs-CaM suppresses RNA silencing at a step upstream of siRNA production and does not interfere with the later steps of RNA silencing, including siRNA-mediated RNA degradation.     

Post-transcriptional gene silencing in the root system of the actinorhizal tree Allocasuarina verticillata

In recent years, RNA interference has been exploited as a tool for investigating gene function in plants. We tested the potential of double-stranded RNA interference technology for silencing a transgene in the actinorhizal tree Allocasuarina verticillata. The approach was undertaken using stably transformed shoots expressing the beta-glucuronidase (GUS) gene under the control of the constitutive promoter 35S; the shoots were further transformed with the Agrobacterium rhizogenes A4RS containing hairpin RNA (hpRNA) directed toward the GUS gene, and driven by the 35S promoter. The silencing and control vectors contained the reporter gene of the green fluorescent protein (GFP), thus allowing a screening of GUS-silenced composite plantlets for autofluorescence. With this rapid procedure, histochemical data established that the reporter gene was strongly silenced in both fluorescent roots and actinorhizal nodules. Fluorometric data further established that the level of GUS silencing was usually greater than 90% in the hairy roots containing the hairpin GUS sequences. We found that the silencing process of the reporter gene did not spread to the aerial part of the composite A. verticillata plants. Real-time quantitative polymerase chain reaction showed that GUS mRNAs were substantially reduced in roots and, thereby, confirmed the knock-down of the GUS transgene in the GFP(+) hairy roots. The approach described here will provide a versatile tool for the rapid assessment of symbiotically related host genes in actinorhizal plants of the Casuarinaceae family.     

Constructs and methods for high-throughput gene silencing in plants

Gene silencing can be achieved by transformation of plants with constructs that express self-complementary (termed hairpin) RNA containing sequences homologous to the target genes. The DNA sequences encoding the self-complementary regions of hairpin (hp) RNA constructs form an inverted repeat. The inverted repeat can be stabilized in bacteria through separation of the self-complementary regions by a "spacer" region. When the spacer sequence encodes an intron, the efficiency of gene silencing is very high. There are at least three ways in which hpRNA constructs can be made. The construct may be generated from standard binary plant transformation vectors in which the hairpin-encoding region is generated de novo for each gene. Alternatively, generic gene-silencing vectors such as the pHANNIBAL and the pHELLSGATE series can be used. They simply require the insertion of PCR products, derived from the target gene, into the vectors by conventional cloning or by using the Gateway directed recombination system. In this article, we describe and evaluate the advantages of these vectors and then provide the protocols for their efficient use.     

Rapid in planta evaluation of root expressed transgenes in chimeric soybean plants

Production of stable transgenic plants is one factor that limits rapid evaluation of tissue specific transgene expression. To hasten the assessment of transgenes in planta, we evaluated the use of chimeric soybean seedlings expressing transgenic products in roots. Tap roots from four-day old seedlings (cultivars ‘Jack’ and KS4704) were excised and hairy roots were induced from hypocotyls via Agrobacterium rhizogenes-mediated transformation. Inoculated hypocotyls were screened on a MS-based medium containing either 200 mg/L kanamycin or 20 mg/L hygromycin. Beta-glucuronidase (GUS) activity assay indicated that highest GUS expression was observed in hypocotyls exposed to a 4-d pre-inoculation time, a neutral pH (7.0) for the co-cultivation medium. A 170-bp of the Fib-1 gene and 292-bp of the Y25C1A.5 gene fragments, both related to nematode reproduction and fitness, were cloned independently into pANDA35HK vector using a Gateway cloning strategy. The resulting RNAi constructs of the genes fragments were transformed into soybean using the chimeric hairy root system and evaluated for its effect on soybean cyst nematode (Heterodera glycines) fecundity. Confirmation of transformation was attained by polymerase chain reaction and Southern-blot analysis, and some potential for suppression of H. glycines reproduction was detected for the two constructs. This method takes on average four weeks to produce chimeric plants ready for transgene analysis.     

Transformation through agroinfection on decapitated shoot apex of field-growing <Emphasis Type="Italic">Phyllanthus amarus</Emphasis>

A simple and easy transformation strategy was accomplished on field growing plants of Phyllanthus amarus, an anti-hepatitis B drug plant. Infection of Agrobacterium rhizogenes strains A₄M70GUS and ATCC 15834 on decapitated shoots of field growing P. amarus induced hairy roots and crown gall, respectively. Infection with A₄M70GUS yielded a mean of 23.2 roots from 40% plants in 40-day period. The crown gall induced on 30% plants after infection with ATCC 15834 grew to 5–10 mm in diameter. The roots and crown galls established in vitro on Murashige and Skoog (MS) basal medium grew well. The hairy roots yielded fivefold (6.91 g) biomass in half-strength MS liquid medium to that of the adventitious roots derived from internode explants in MS medium with 8.0 μM α-naphthaleneacetic acid (1.39 g). Histochemical assay and PCR analysis using the primers of uidA coding region confirmed the hairy roots induced by A₄M70GUS. The crown galls induced by ATCC 15834 were confirmed by PCR analysis using rolB gene primers. The protocol enables an easy and early accomplishment of hairy roots.     

Engineering novel traits in plants through RNA interference

RNA interference (RNAi) is a homology-dependent gene silencing technology that involves double-stranded RNA directed against a target gene or its promoter region. Using hairpin constructs, double-stranded RNA can be expressed in plants relatively easily, enabling this technology to be applied to a wide range of species to silence the expression of both specific endogenous genes and genes of invading pathogens. RNAi has also been used to engineer metabolic pathways to overproduce secondary products with health, yield or environmental benefits. The application of tissue-specific or inducible gene silencing, with the use of appropriate promoters, and the ability to silence several genes simultaneously should enhance our ability to create novel traits in plants.