High frequency induction of RNA-mediated resistance against Cucumber mosaic virus using inverted repeat constructs

The application of RNA-mediated resistance against Cucumber mosaic virus (CMV) by using single transgene constructs generally results in only a small portion of resistant individuals. Inverted repeat constructs encoding self-complementary double-stranded RNA have been demonstrated a potential way to obtain RNA-mediated resistance at high efficiency. To test this observation as a possible method for high frequency induction of CMV resistance, Nicotiana benthamiana plants were transformed with transgenes designed to produce double strand RNA molecules of CMV RNA 2 or coat protein (CP) gene sequences. Seventy-five percent of the tested R₀ plants transformed with an RNA 2-derived inverted repeat construct (1534 nt CMV sequence) showed extreme resistance to CMV, while a lower percentage of resistance (30%) was observed in R₀ lines transformed with a similar construct of a shorter viral RNA 2 sequence (490 nt). The resistance level conferred by CP sequences was also efficient by using a dsRNA construct, reaching a level of 50%. Self-pollinated (S₁) progenies obtained from most resistant R₀ plants all showed resistance levels of 100%, perfectly correlating with the expression of transgenic siRNAs. The results indicate that the use of inverted repeat viral transgenes is a highly efficient approach to obtain CMV resistant transgenic plants. Consequently, only a handful of transgenic plants will have to be generated using such constructs for successful resistance, which enables the implementation of this protocol for crops that are difficult to transform, such as ornamental plants in which CMV is an important pathogen.     

Engineering resistance to geminiviruses--review and perspectives

Following the conceptual development of virus resistance strategies ranging from coat protein-mediated interference of virus propagation to RNA-mediated virus gene silencing, much progress has been achieved to protect plants against RNA and DNA virus infections. Geminiviruses are a major threat to world agriculture, and breeding resistant crops against these DNA viruses is one of the major challenges faced by plant virologists and biotechnologists. In this article, we review the most recent transgene-based approaches that have been developed to achieve durable geminivirus resistance. Although most of the strategies have been tested in model plant systems, they are ready to be adopted for the protection of crop plants. Furthermore, a better understanding of geminivirus gene and protein functions, as well as the native immune system which protects plants against viruses, will allow us to develop novel tools to expand our current capacity to stabilize crop production in geminivirus epidemic zones.     

Homology-dependent resistance: transgenic virus resistance in plants related to homology-dependent gene silencing

Tobacco plants transformed with the RNA polymerase (RdRp) gene of potato virus X (PVX) that are extremely resistant to infection by potato virus X have previously been described. The PVX-resistant plants accumulated the RdRp protein at a lower level than fully susceptible plants transformed with the same RdRp construct. In this paper the difference between the PVX-resistant and susceptible transformed plants is investigated and it is demonstrated that there are three associated phenotypes of the RdRp transgene that vary in parallel between transformed lines. These phenotypes are: accumulation of the transgenic RdRp RNA at a low level; strain-specific resistance to PVX; and the ability of the transgene to trans -inactivate homologous transgenes. This gene-silencing potential of the transgenes conferring PVX resistance was illustrated by analysis of progeny from a cross between a transformant that was extremely resistant to PVX and a second PVX-susceptible transformant. In other transformants, in which the resistance was less extreme, the same three phenotypes were associated but in a transgene dosage-dependent manner. The same association of strain-specific resistance and low-level accumulation of the transgenic RdRp RNA was observed with plants that were transformed with mutant or wild-type versions of the RdRp gene. Strain-specific resistance was also produced in plants transformed with untranslatable versions of the RdRp transgene. Based on these data it is proposed that homology-dependent gene silencing and transgenic resistance to PVX may be due to the same RNA-based mechanism. An undefined genomic feature is proposed to account for the variation in the resistance and trans -inactivation phenotypes of different transformants. It is further proposed that this genome feature influences a cytoplasmic mechanism that degrades RNA with sequence homology to the silencing transgene.     

Engineering broad-spectrum resistance against RNA viruses in potato

RNA silencing technology has become the tool of choice for inducing resistance against viruses in plants. A significant discovery of this technology is that double-stranded RNA (dsRNA), which is diced into small interfering RNAs (siRNAs), is a potent trigger for RNA silencing. By exploiting this phenomenon in transgenic plants, it is possible to confer high level of virus resistance by specific targeting of cognate viral RNA. In order to maximize the efficiency and versatility of the vector-based siRNA approach, we have constructed a chimeric expression vector containing three partial gene sequences derived from the ORF2 gene of Potato virus X, Helper Component Protease gene of Potato virus Y and Coat protein gene of Potato leaf roll virus. Solanum tuberosum cv. Desiree and Kuroda were transformed with this chimeric gene cassette via Agrobacterium tumefaciens-mediated transformation and transgenic status was confirmed by PCR, Southern and double antibody sandwich ELISA detection. Due to simultaneous RNA silencing, as demonstrated by accumulation of specific siRNAs, the expression of partial triple-gene sequence cassette depicted 20% of the transgenic plants are immune against all three viruses. Thus, expression of a single transgene construct can effectively confer resistance to multiple viruses in transgenic plants.     

Characterization of the recombinant forms arising from a Potato virus X chimeric virus infection under RNA silencing pressure

Recombination is a frequent phenomenon in RNA viruses whose net result is largely influenced by selective pressures. RNA silencing in plants acts as a defense mechanism against viruses and can be used to engineer virus resistance. Here, we have investigated the influence of RNA silencing as a selective pressure to favor recombinants of PVX-HCT, a chimeric Potato virus X (PVX) vector carrying the helper-component proteinase (HC-Pro) gene from Plum pox virus (PPV). All the plants from two lines expressing a silenced HC-Pro transgene were completely resistant to PPV. However a significant proportion became infected with PVX-HCT. Analysis of viral RNAs accumulating in silenced plants revealed that PVX-HCT escaped silencing-based resistance by removal of the HC-Pro sequences that represented preferential targets for transgene-promoted silencing. The virus vector also tended to lose the HC-Pro insert when infecting transgenic plants containing a nonsilenced HC-Pro transgene or wild-type (wt) Nicotiana benthamiana plants. Nevertheless, loss of HC-Pro sequences was faster in nonsilenced transgenic plants than in wt plants, suggesting the transgene plays a role in promoting a higher selective pressure in favor of recombinant virus versions. These results indicate that the outcome of recombination processes depends on the strength of selection pressures applied to the virus.     

Plum pox potyvirus resistance associated to transgene silencing that can be stabilized after different number of plant generations

Nicotiana benthamiana plants were transformed with a fragment of the plum pox potyvirus (PPV) genome that encodes the nuclear inclusion a (NIa) and b (NIb) proteins and the N-terminus of the capsid protein (NIa–NIb–CP*). Lines transformed with this PPV genomic fragment harboring mutations in the GDD replicase-motif were also obtained. Plants of NIaΔV lines that carry a GDD to VDD mutation in the PPV transgene, were immune to PPV infection. The resistance was highly specific, since it was only partially overcome by a PPV strain different to that from which the transgene was derived, and no resistance was observed after inoculation with a second potyvirus. PPV was not able to replicate in protoplasts isolated from NIaΔV transgenic plants, indicating that the resistance was functional at the single cell level. Only a fraction of plants from lines transformed with the NIa–NIb–CP* fragment harboring a GDD to ADD mutation (NIaΔA lines), were resistant to PPV infection. This same phenotype was observed in plants expressing the wild-type construction (NIaΔ), although the progeny of some non-infected plants seemed to be completely resistant to PPV, independently of the allelic status of the parental plant. In all cases, the resistance phenotype correlated positively with low levels of transgene mRNA accumulation, suggesting that it was mainly due to a gene silencing mechanism. Our results show that, although the transgene was not silenced in all R1 plants from some individual lines, a stable silenced status could be reached in the following generations.     

Gene stacking in <Emphasis Type="Italic">Phalaenopsis</Emphasis> orchid enhances dual tolerance to pathogen attack

Cymbidium Mosaic Virus (CymMV) and Erwinia carotovora have been reported to cause severe damage to orchid plants. To enhance the resistance of orchids to both viral and bacterial phytopathogens, gene stacking was applied on Phalaenopsis orchid by double transformation. PLBs originally transformed with CymMV coat protein cDNA (CP) were then re-transformed with sweet pepper ferredoxin-like protein cDNA (Pflp) by Agrobacterium tumefaciens, to enable expression of dual (viral and bacterial) disease resistant traits. A non-antibiotic selection procedure in the second transformation minimized the potential rate of ‘stacking’ antibiotic genes in the orchid gene pool. Transgene integration in transgenic Phalaenopsis lines was confirmed by Southern blot analysis for both CP and pflp genes. Expression of transgenes was detected by northern blot analysis, and disease resistant assays revealed that transgenic lines exhibited enhanced resistance to CymMV and E. carotovora. This is the first report describing a transgenic Phalaenopsis orchid with dual resistance to phytopathogens.     

转基因番木瓜的抗病性及分子鉴定

对T1代转番木瓜环斑病毒(PRV)复制酶(RP)突变体基因的两个番木瓜株系,进行了抗病性和分子生物学分析。结果表明,转基因番木瓜对PRV抗性达到高抗或免疫,目的基因RP遗传至转基因后代并在RNA水平表达,PCR可检测到CaMV35S启动子序列、标记基因NPTII。 Abstract:Virus resistance in field and molecular biological characterizations of the transgenes were analyzed for two lines of T1 generation of transgenic papaya with the replicase mutant gene from papaya ringspot virus (PRV).The transgenic plants showed highly resistant or immune against PRV.Results indicated that the transgenes inherited to and expressed at RNA level in the progenies.     

Antiviral strategies in plants based on RNA silencing

One of the challenges being faced in the twenty-first century is the biological control of plant viral infections. Among the different strategies to combat virus infections, those based on pathogen-derived resistance (PDR) are probably the most powerful approaches to confer virus resistance in plants. The application of the PDR concept not only revealed the existence of a previously unknown sequence-specific RNA-degradation mechanism in plants, but has also helped to design antiviral strategies to engineer viral resistant plants in the last 25 years. In this article, we review the different platforms related to RNA silencing that have been developed during this time to obtain plants resistant to viruses and illustrate examples of current applications of RNA silencing to protect crop plants against viral diseases of agronomic relevance. This article is part of a Special Issue entitled: MicroRNAs in viral gene regulation.     

Genetically modified plants and plant protection problems: Progress and estimation of potential risks

In this review, the achievements and perspectives for the creation of transgenic plants are analyzed. Until now, virtually all commercially cultivated genetically modified plants have been developed for the purpose of getting a solution to the problem of plant protection: such plants carry transgenes conferring resistance to herbicides, pests, and viruses. Approaches used for the development of commercial genetically modified varieties resistant to herbicides, insects, and viruses were considered; strategic approaches and perspectives for the development of commercial genetically modified plants resistant to fungal and bacterial pathogens and nematodes were also examined. The ecological (including agronomic issues) and social risks connected with commercial cultivation of transgenic crops were discussed.     

Expression of an extracellular ribonuclease gene increases resistance to Cucumber mosaic virus in tobacco

Background

The apoplast plays an important role in plant defense against pathogens. Some extracellular PR-4 proteins possess ribonuclease activity and may directly inhibit the growth of pathogenic fungi. It is likely that extracellular RNases can also protect plants against some viruses with RNA genomes. However, many plant RNases are multifunctional and the direct link between their ribonucleolytic activity and antiviral defense still needs to be clarified. In this study, we evaluated the resistance of Nicotiana tabacum plants expressing a non-plant single-strand-specific extracellular RNase against Cucumber mosaic virus.

Results

Severe mosaic symptoms and shrinkage were observed in the control non-transgenic plants 10 days after inoculation with Cucumber mosaic virus (CMV), whereas such disease symptoms were suppressed in the transgenic plants expressing the RNase gene. In a Western blot analysis, viral proliferation was observed in the uninoculated upper leaves of control plants, whereas virus levels were very low in those of transgenic plants. These results suggest that resistance against CMV was increased by the expression of the heterologous RNase gene.

Conclusion

We have previously shown that tobacco plants expressing heterologous RNases are characterized by high resistance to Tobacco mosaic virus. In this study, we demonstrated that elevated levels of extracellular RNase activity resulted in increased resistance to a virus with a different genome organization and life cycle. Thus, we conclude that the pathogen-induced expression of plant apoplastic RNases may increase non-specific resistance against viruses with RNA genomes.

     

Silencing of Plum pox virus 5′UTR/P1 sequence confers resistance to a wide range of PPV strains

An effective disease-control strategy should protect the host from the major economically important and geographically widespread variants of a pathogen. Plum pox virus (PPV) is the causal agent of sharka, the most devastating viral disease of Prunus species. We have shown previously that the hairpin RNA expression driven by h-UTR/P1, h-P1/HCPro, h-HCPro and h-HCPro/P3 constructs, derived from the PPV-M ISPaVe44 isolate, confers resistance to the homologous virus in Nicotiana benthamiana plants. Since the production of transgenic stone fruits and their evaluation for PPV resistance would take several years, the ISPaVe44-resistant plant lines were used to evaluate which construct would be the best candidate to be transferred to Prunus elite cultivars. To do that, nine PPV isolates of the D, M, Rec, EA and C strains originally collected from five Prunus species in different geographical areas, were typed by sequencing and used to challenge the transgenic N. benthamiana lines; 464 out of 464 virus-inoculated plants of lines h-UTR/P1, h-HCPro and h-HCPro/P3 showed complete and long-lasting resistance to the seven PPV isolates of D, M and Rec strains. Moreover, the h-UTR/P1 plants were also fully resistant to PPV-C and -EA isolates. Our data suggest that the h-UTR/P1 construct is of particular practical interest to obtain stone fruit plants resistant to the sharka disease.     

The chitinase gene (Bbchit1) from Beauveria bassiana enhances resistance to Cytospora chrysosperma in Populus tomentosa Carr.

The Chinese white poplar (Populus tomentosa Carr.) is susceptible to infection by plant diseases which severely affect its growth and substantially decrease its economic value. A chitinase gene (Bbchit1) from Beauveria bassiana was introduced into Chinese white poplar (Populus tomentosa Carr.) by Agrobacterium-mediated transformation. The T-DNA of plant transformation vector contained the β-glucuronidase reporter gene (GUS) under the control of CaMV 35S promoter and the neomycin phosphotransferase selection marker gene (NPTII) driven by the nos promoter. GUS activity was detected in most of the kanamycin-resistant plants tested. Stable integration of transgenes in the plant genome was confirmed using PCR. RT-PCR analysis showed that the Bbchit1 gene was transcribed in the transformed plants. When evaluated for resistance to poplar fungal pathogens with an in vitro assay, crude extracts from leaves and shoots of transgenic lines were inhibitory against the pathogenic fungus Cytospora chrysosperma (Pers.) Fr. Similarly, Bbchit1 overexpression enhanced disease resistance to C. chrysosperma in the transformed poplar plants, indicating that is gene is potentially useful to protect the trees against fungal diseases.     

Ectopic expression of <Emphasis Type="Italic">Dahlia merckii</Emphasis> defensin <Emphasis Type="Italic">DmAMP</Emphasis>1 improves papaya resistance to <Emphasis Type="Italic">Phytophthora palmivora</Emphasis> by reducing pathogen vigor

Phytophthora spp., some of the more important casual agents of plant diseases, are responsible for heavy economic losses worldwide. Plant defensins have been introduced as transgenes into a range of species to increase host resistance to pathogens to which they were originally susceptible. However, the effectiveness and mechanism of interaction of the defensins with Phytophthora spp. have not been clearly characterized in planta. In this study, we expressed the Dahlia merckii defensin, DmAMP1, in papaya (Carica papaya L.), a plant highly susceptible to a root, stem, and fruit rot disease caused by Phytophthora palmivora. Extracts of total leaf proteins from transformed plants inhibited growth of Phytophthora in vitro and discs cut from the leaves of transformed plants inhibited growth of Phytophthora in a bioassay. Results from our greenhouse inoculation experiments demonstrate that expressing the DmAMP1 gene in papaya plants increased resistance against P. palmivora and that this increased resistance was associated with reduced hyphae growth of P. palmivora at the infection sites. The inhibitory effects of DmAMP1 expression in papaya suggest this approach has good potential to impart transgenic resistance against Phytophthora in papaya.