Academic literature on the topic 'Peas Plant viruses Virus-induced enzymes'

Plant immune activators can protect crops from plant virus pathogens by activating intrinsic immune mechanisms in plants and are widely used in agricultural production. In our previous work, we found that curcumin analogs exhibit excellent biological activity against plant viruses, especially protective activity. Inspired by these results, the active substructure of pentadienone and quinazoline were spliced to obtain curcumin analogs as potential exogenously induced resistant molecule. Bioassay results showed that compound A13 exhibited excellent protective activity for tobacco to against Tobacco mosaic virus (TMV) at 500 μg/mL, with a value of 70.4 ± 2.6% compared with control treatments, which was better than that of the plant immune activator chitosan oligosaccharide (49.0 ± 5.9%). The protective activity is due to compound A13 inducing tobacco resistance to TMV, which was related to defense-related enzymes, defense-related genes, and photosynthesis. This was confirmed by the up-regulated expression of proteins that mediate stress responses and oxidative phosphorylation.

Insect vectors and insect-borne plant viruses seriously endanger the safety of agricultural production. An insecticide is one of the main methods to prevent insect-borne virus transmission. However, the curious relationship between the resistance of insect vectors and arboviruses has been less studied. In this study, the effect of Tomato chlorosis virus (ToCV) on the insecticide resistance of Bemisia tabaci MED was studied. It was found that the detoxification cytochrome P450, glutathione S-transferase, and carboxylesterase-related genes in ToCV-infected B. tabaci were upregulated. The activity of the three detoxification enzymes all increased at the same time, after 48 h of virus acquisition, with the activity of carboxylesterase being the most pronounced. It was found that cytochrome P450 and glutathione S-transferase activity was the least. ToCV led to the reduced sensitivity of B. tabaci MED to pyrethroids and flupyradifurone. Therefore, it was proven that the insect-borne plant virus ToCV shows the possibility of enhancing insect-borne insecticide resistance.

Insect-vectored plant viruses pose a serious threat to sustainable production of economically important crops worldwide. This demands a continuous search for environmentally-friendly, sustainable and efficient approaches based on biological agents to address the mounting challenges of viral disease management. To date, the efficacy of actinomycetes bacteria against DNA plant viruses remains unknown. Here, through comparative analyses, we demonstrate that the RFS-23 strain of Streptomyces cellulase possesses protective activity as it positively regulated the plant growth and development. and diminished the severity, of disease symptoms, together with reduced accumulation of Tomato yellow leaf curl virus (TYLCV) DNA. The RFS-23 strain maintained relative chlorophyll contents by promoting the expression of genes (CLH1, HEMA1 and PORA) associated with chlorophyll biogenesis. As compared to another strain, CTF-20, the RSF-23 induced a significantly higher expression of plant defense-related genes (NbCIS and NbNCED) associated with biogenesis and accumulation of salicylic acid and abscisic acid. Additionally, the activity of antioxidant enzymes (SOD, CAT, POD and MDA) was significantly enhanced by RSF-23 treatment, despite the presence of viral infection. These findings suggest that RSF-23 is a novel biocontrol agent with protective activity, and it could be a potential candidate for the management of plant viral infections.

ABSTRACTPeas carrying thecyv1recessive resistance gene are resistant to clover yellow vein virus (ClYVV) isolates No.30 (Cl-No.30) and 90-1 (Cl-90-1) but can be infected by a derivative of Cl-90-1 (Cl-90-1 Br2). The main determinant for the breaking ofcyv1resistance by Cl-90-1 Br2 is P3N-PIPO produced from theP3gene via transcriptional slippage, and the higher level of P3N-PIPO produced by Cl-90-1 Br2 than by Cl-No.30 contributes to the breaking of resistance. Here we show that P3N-PIPO is also a major virulence determinant in susceptible peas that possess another resistance gene,Cyn1, which does not inhibit systemic infection with ClYVV but causes hypersensitive reaction-like lethal systemic cell death. We previously assumed that the susceptible pea cultivar PI 226564 has a weak allele ofCyn1. Cl-No.30 did not induce cell death, but Cl-90-1 Br2 killed the plants. Our results suggest that P3N-PIPO is recognized byCyn1and induces cell death. Unexpectedly, heterologously strongly expressed P3N-PIPO of Cl-No.30 appears to be recognized byCyn1in PI 226564. The level of P3N-PIPO accumulation from theP3gene of Cl-No.30 was significantly lower than that of Cl-90-1 Br2 in aNicotiana benthamianatransient assay. Therefore,Cyn1-mediated cell death also appears to be determined by the level of P3N-PIPO. The more efficiently a ClYVV isolate brokecyv1resistance, the more it induced cell death systemically (resulting in a loss of the environment for virus accumulation) in susceptible peas carryingCyn1, suggesting that antagonistic pleiotropy of P3N-PIPO controls the resistance breaking of ClYVV.IMPORTANCEControl of plant viral disease has relied on the use of resistant cultivars; however, emerging mutant viruses have broken many types of resistance. Recently, we revealed that Cl-90-1 Br2 breaks the recessive resistance conferred bycyv1, mainly by accumulating a higher level of P3N-PIPO than that of the nonbreaking isolate Cl-No.30. Here we show that a susceptible pea line recognized the increased amount of P3N-PIPO produced by Cl-90-1 Br2 and activated the salicylic acid-mediated defense pathway, inducing lethal systemic cell death. We found a gradation of virulence among ClYVV isolates in acyv1-carrying pea line and two susceptible pea lines. This study suggests a trade-off between breaking of recessive resistance (cyv1) and host viability; the latter is presumably regulated by the dominantCyn1gene, which may impose evolutionary constraints uponP3N-PIPOfor overcoming resistance. We propose a working model of the host strategy to sustain the durability of resistance and control fast-evolving viruses.

The faba bean plant (Vicia faba L.) is one of the world’s most important legume crops and can be infected with various viral diseases that affect its production. One of the more significant viruses in terms of economic impact is bean yellow mosaic virus (BYMV). The current study used the molecularly identified Rhizobium leguminosarum bv. viciae strain 33504-Borg1, a nitrogen-fixing bacteria, to biosynthesize silver nanoparticles (AgNPs) to control BYMV disease in faba bean plants. Scanning electron microscopy (SEM), a particle size analyzer (PSA) with dynamic light scattering (DLS), transmission electron microscopy (TEM), energy dispersive X-ray spectroscopy (EDX), and Fourier transform infrared spectroscopy (FTIR) were used to characterize the prepared AgNPs. The DLS, SEM, and TEM analyses revealed that the AgNPs were spherical and rough, with sizes ranging from 13.7 to 40 nm. The FTIR analysis recognized various functional groups related to AgNP capping and stability. Under greenhouse conditions, spraying faba bean leaves with the AgNPs (100 µg/mL) 24 h before BYMV inoculation induced plant resistance and reduced plant disease severity and virus concentration levels. Contrarily, the AgNP treatment enhanced plant health by raising photosynthetic rates, increasing the fresh and dry weight of the faba bean plants, and increasing other measured metrics to levels comparable to healthy controls. Antioxidant enzymes (peroxidase and polyphenol oxidase) inhibited the development of BYMV in the faba bean plants treated with the AgNPs. The AgNPs decreased oxidative stress markers (H2O2 and MDA) in the faba bean plants. The plants treated with the AgNPs showed higher expression levels of PR-1 and HQT than the control plants. The study findings could be used to develop a simple, low-cost, and environmentally friendly method of protecting the faba bean plant from BYMV.

Cucumber mosaic virus (CMV) causes a significant threat to crop output sustainability and human nutrition worldwide, since it is one of the most prevalent plant viruses infecting most kinds of plants. Nowadays, different types of nanomaterials are applied as a control agent against different phytopathogens. However, their effects against viral infections are still limited. In the current study, the antiviral activities of the biosynthesized silver nanoparticles (Ag-NPs) mediated by aqueous extract of Ocimum basilicum against cucumber mosaic virus in squash (Cucurbita pepo L.) were investigated. The prepared Ag-NPs were characterized using scanning electron microscopy (SEM), dynamic light scattering (DLS), transmission electron microscopy (TEM), energy-dispersive X-ray spectroscopy (EDX), Fourier transform infrared spectroscopy (FTIR) and zeta potential distribution techniques. DLS, SEM, and TEM analyses showed that the Ag-NPs were spherical, with sizes ranging from 26.3 to 83 nm with an average particle size of about 32.6 nm. FTIR identified different functional groups responsible for the capping and stability of Ag-NPs. The zeta potential was reported as being −11.1 mV. Under greenhouse conditions, foliar sprays of Ag-NPs (100 µg/mL) promoted growth, delayed disease symptom development, and significantly reduced CMV accumulation levels of treated plants compared to non-treated plants. Treatment with Ag-NPs 24 h before or after CMV infection reduced CMV accumulation levels by 92% and 86%, respectively. There was also a significant increase in total soluble carbohydrates, free radical scavenging activity, antioxidant enzymes (PPO, SOD, and POX), as well as total phenolic and flavonoid content. Furthermore, systemic resistance was induced by significantly increasing the expression levels of pathogenesis-related genes (PR-1 and PR-5) and polyphenolic pathway genes (HCT and CHI). These findings suggest that Ag-NPs produced by O. basilicum could be used as an elicitor agent and as a control agent in the induction and management of plant viral infections.

Abstract Background Banana bunchy top virus (BBTV) is a destructive viral disease in many countries including Egypt; it causes severe economic losses in banana crop. Recently, nanotechnology was used to generate resistance against plant viruses. The main purpose of this study was to use silver nanoparticles (AgNPs) as antiviral agents against BBTV. In this research, three different concentrations of AgNPs (40, 50 and 60 ppm) were applied by foliar spray post-BBTV inoculation. In addition, photopigments, oxidative enzymes, proline and phenolic compounds were determined. Besides, Random amplified polymorphic DNA (RAPD) and Sequence-related amplified polymorphism (SRAP) markers were used to evaluate the genotoxicity of AgNPs as antiviral factors against BBTV, compared with the control plants. Results In the current study, it was observed that banana plants infected with BBTV and treated with 50 ppm AgNPs have not shown any external symptoms where the rate of infection was 36%. On the other hand, banana plants treated with 50 ppm AgNPs after viral infection gave a significant increase in dry weight and leaf area, compared with BBTV infected banana plants (viral control). Our study showed that 50 ppm AgNPs treatment post-virus inoculation induced non-significantly and significant changes in chlorophyll (a and b) and carotenoids, respectively, compared with healthy and nano-controls. In contrast, phenol, proline and oxidative enzymes were significantly increased in all plants treated with 50 ppm AgNPs post-virus inoculation, compared with the healthy control. Our findings observed that the banana plants sprayed with 50 ppm AgNPs after BBTV infection induced a few changes at the genomic DNA level in the banana plants, whereas both RAPD and SRAP markers scored nearly the same polymorphism 36.99 and 37.5%, respectively. So, genotoxicity induced by banana plants treated with 50 ppm AgNPs post-BBTV inoculation was low. Conclusions It is evident from the study results the role of AgNPs as a novel, safe and effective antiviral agent against BBTV. These results should be taken into consideration in future for the use of AgNPs for plant viruses management.

The molecular interactions between Polymyxa betae, the protist vector of sugar beet viruses, Beet necrotic yellow vein virus (BNYVV), the causal agent of rhizomania, and Beta vulgaris have not been extensively studied. Here, the transmission of BNYVV to sugar beet by P. betae zoospores was optimized using genetically characterized organisms. Molecular interactions of aviruliferous and viruliferous protist infection on sugar beet were highlighted by transcriptomic analysis. P. betae alone induced limited gene expression changes in sugar beet, as a biotrophic asymptomatic parasite. Most differentially expressed plant genes were down-regulated and included resistance gene analogs and cell wall peroxidases. Several enzymes involved in stress regulation such as the glutathione-S-transferases were significantly induced. With BNYVV, the first stages of P. betae life cycle on sugar beet were accelerated with a faster increase of relative protist DNA level and an earlier appearance of sporangia and sporosori in plants roots. A clear activation of plant defenses and the modulation of genes involved in plant cell wall metabolism were observed. The P. betae transcriptome in the presence of BNYVV revealed induction of genes possibly involved in the switch to the survival stage. The interactions were different depending on the presence – absence of the virus. P. betae alone alleviates plant defense response, playing hide-and-seek with sugar beet and allowing for their mutual development. Conversely, BNYVV manipulates plant defense and promotes the rapid invasion of plant roots by P. betae. This accelerated colonization is accompanied by the development of thick-walled resting spores, supporting the virus survival.

Abstract Background The growing field of plant molecular farming relies on expression vectors that allow high yields of recombinant proteins to be produced through transient gene expression. While numerous expression vectors currently exist for this purpose, there are very few examples of systematic efforts to improve upon these. Moreover, the current generation of expression systems makes use of naturally-occurring regulatory elements, typically selected from plant viruses, to maximise yields. This study aims to use rational design to generate synthetic sequences that can rival existing ones. Results In this work, we present the rational design of novel synthetic 5′ and 3′ untranslated regions (UTRs) which can be used in various combinations to modulate accumulation levels of transiently-expressed recombinant proteins. Using the pEAQ-HT expression vector as a point of comparison, we show that pre-existing expression systems can be improved by the deployment of rationally designed synthetic UTRs. Notably, we show that a suite of short, synthetic 5′UTRs behave as expression enhancers that outperform the HT 5′UTR present in the CPMV-HT expression system. Furthermore, we confirm the critical role played by the 3′UTR of cowpea mosaic virus RNA-2 in the performance of the CPMV-HT system. Finally, we use the knowledge obtained from these results to develop novel expression vectors (named pHRE and pHREAC) that equal or outperform pEAQ-HT in terms of recombinant protein yield. These new vectors are also domesticated for the use of certain Type IIS restriction enzymes, which allows for quicker cloning and straightforward assessment of different combinations of UTRs. Conclusions We have shown that it is possible to rationally design a suite of expression modulators in the form of synthetic UTRs. We have created novel expression vectors that allow very high levels of recombinant protein expression in a transient expression context. This will have important consequences for future efforts to develop ever-better plant transient overexpression vectors for research or industrial applications.

Yam bean (Pachyrhizus erosus), a high-yielding leguminous root crop with good nutritional value, is widely cultivated in southern China. In 2020, P. erosus (cv. Mumashan) plants exhibiting irregular yellow leaves and malformed seed pods (Supplementary Fig S1) were observed at Ningbo city, Zhejiang Province, China. To determine the causal agent(s) of the disease, symptomatic leaves (n=4) were collected for electron microscopy negative staining. Virus particles with a length of about 700nm, similar to viruses in the genus Potyvirus, were observed via transmission electron microscope (TEM), suggesting the presence a potyvirus(es). To further confirm which potyvirus(es) infected yam bean, total RNA was extracted from leaf samples of a total of six plants, including four symptomatic plants and two asymptomatic plants using TRIzol reagent (Invitrogen Carlsbad, CA, USA) according to the manufacturer’s instructions. RNA was reverse-transcribed into cDNA with M4-T as the 3'-anchoring primer by ReverTra Ace® kit (Toyobo, Japan). Sprimer/M4 Potyviridae specific primers (Chen et al., 2001) were used for PCR analysis. A ~1,700-bp-long product was amplified from four symptomatic plants using KOD FX enzyme (Toyobo, Japan). No such band was amplified from the two asymptomatic plants. The PCR product (~1.7kb) amplified from a single symptomatic plant was ligated into the pEASY®-Blunt Zero vector (TransGen Bio, Beijing, China) and sequenced (Sangon Bio, Shanghai, China). The amplicon showed 99% nucleotide sequence identities with bean common mosaic virus (BCMV) isolate NKY021 (KJ807819). Subsequently, the complete nucleotide sequences of this BCMV isolate (referred as BCMV-NB) was amplified by overlapping RT-PCR and rapid amplification of cDNA ends with primers (Supplementary Table S1) designed from the sequence of BCMV isolate NKY021. The BCMV-NB full genome (Accession No. OL871237) consists of 10,053 nucleotides excluding the poly(A) tail and contains a large open reading frame encoding a polyprotein of 3222 amino acids. BLASTn analysis showed that BCMV-NB shared a sequence identity of 96.4% with BCMV isolate HZZB011 (KJ807815). Phylogenetic tree generated by Neighbour-Joining method revealing the BCMV-NB isolate was grouped together with Chinese isolates from Glycine max (Supplementary Fig S1). To test the infectivity of BCMV-NB, virus-free yam bean (cv. Mumashan) and Nicotiana benthamiana seedlings were mechanically inoculated with sap extracted from the symptomatic leaves of a BCMV-NB-infected yam bean plant. The inoculated yam bean plants developed typical BCMV mosaic and chlorotic symptoms at 16 days post inoculation (dpi), while Nicotiana benthamiana had no obvious symptoms at 10 or 20 dpi (Supplementary Fig S1). BCMV infections were confirmed in yam bean plants (infection rate 6/6) and N. benthamiana plants (infection rate 8/8) by RT-PCR at 16 dpi and 10 dpi, respectively. Twelve further P. erosus plants (cv. Mumashan) were collected from a field in Ningbo city and tested by RT-PCR with BCMV-specific primer pair BCMV CP (+)/(-) (Supplementary Table 1). Eight out of the 12 samples tested positive for BCMV by PCR-gel electrophoresis (Supplementary Fig S1) and Sanger sequencing, suggesting a high incidence of BCMV infection in this field. BCMV infection in yam bean has been reported from Indonesia (Damayanti et al., 2008) and Peru (Fuentes et al., 2012). To the best of our knowledge, this is the first report of BCMV naturally infecting yam bean in China. Thus, special attention and appropriate management strategies are needed to minimize the damage caused by BCMV to yam bean crops in China.

Corrigendum inserted at the back. Includes bibliographical references (leaves 133-158). Ch. 1. General introduction -- ch. 2. General materials and methods -- ch. 3. Biological characterisation of Australian PSbMV isolates -- ch. 4. Developing nucleic acid based diagnostics for PSbMV -- ch. 5. Detection of PSbMV isolates by RT-PCR and RFLP analysis -- ch. 6. Developing an internal control for PSbMV RT-PCR -- ch. 7. Molecular analysis of the PSbMV VPG -- ch. 8. PSbMV sequence and phylogenetic analysis -- ch. 9. General discussion Sixteen pea seed borne mosaic virus (PSbMV) isolates were collected between 1995 and 1998. These isolates were biologically distinct yet serologically indistinguishable. The conclusion is that PSbMV is widespread and occurs at a low incidence in Australia. Reports sequence information on new isolates of PSbMV which has allowed genomic regions to be identified which distinguish PSbMV pathotypes and isolates; and, to the development of PSbMV nucleic acid hybridisation and RT-PCR assays.

Corrigendum inserted at the back.
Includes bibliographical references (leaves 133-158).
xvi, 158 leaves : ill., col. map ; 30 cm.
Sixteen pea seed borne mosaic virus (PSbMV) isolates were collected between 1995 and 1998. These isolates were biologically distinct yet serologically indistinguishable. The conclusion is that PSbMV is widespread and occurs at a low incidence in Australia. Reports sequence information on new isolates of PSbMV which has allowed genomic regions to be identified which distinguish PSbMV pathotypes and isolates; and, to the development of PSbMV nucleic acid hybridisation and RT-PCR assays.
Thesis (Ph.D.)--University of Adelaide, Dept. of Applied and Molecular Ecology, 2001