Characterization of Brown Streak Virus–Resistant Cassava

Anjanappa, Ravi B.; Mehta, Devang; Maruthi, M. N.; Kanju, Edward; Gruissem, Wilhelm; Vanderschuren, Hervé

doi:10.1094/mpmi-01-16-0027-r

Cited by 26 publications

(50 citation statements)

References 47 publications

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“…No virus was detected in leaves of KBH 2006/18 scions (Fig. S2), consistent with previous results (Anjanappa et al ., ). Notably, we did not observe CBSD symptoms in any inoculated plant at 28 dag.…”

Section: Resultsmentioning

confidence: 97%

“…In a previous study investigating the cassava–CBSV pathosystem, we found that KBH 2006/18 allows the transmission of CBSVs through the stem vasculature, whereas no virus can be detected in KBH 2006/18 leaves (Anjanappa et al ., ). This suggests that the resistance of KBH 2006/18 to CBSVs involves at least restriction of intercellular virus movement from vascular tissues to mesophyll cells.…”

Section: Resultsmentioning

confidence: 97%

“…Although DEGs associated with virus movement through plasmodesmata were found only in CBSV‐infected 60444, callose deposition at plasmodesmata was reduced in 60444 and increased in KBH 2006/18, which could only be partially explained by the detected DEGs. Nevertheless, the results are consistent with the limitation of CBSV movement in KBH 2006/18 from stems into leaves (Anjanappa et al ., ). An efficacious CBSV infection of the susceptible 60444 variety thus involves a virus‐induced reduction in callose deposition at the plasmodesmata that is absent in the resistant KBH 2006/18 variety.…”

Section: Discussionmentioning

confidence: 97%

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Molecular insights into Cassava brown streak virus susceptibility and resistance by profiling of the early host response

Anjanappa

Mehta

Okoniewski

et al. 2017

Molecular Plant Pathology

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Cassava brown streak virus (CBSV) and Ugandan cassava brown streak virus (UCBSV) are responsible for significant cassava yield losses in eastern sub-Saharan Africa. To study the possible mechanisms of plant resistance to CBSVs, we inoculated CBSV-susceptible and CBSV-resistant cassava varieties with a mixed infection of CBSVs using top-cleft grafting. Transcriptome profiling of the two cassava varieties was performed at the earliest time point of full infection (28 days after grafting) in the susceptible scions. The expression of genes encoding proteins in RNA silencing, salicylic acid pathways and callose deposition was altered in the susceptible cassava variety, but transcriptional changes were limited in the resistant variety. In total, the expression of 585 genes was altered in the resistant variety and 1292 in the susceptible variety. Transcriptional changes led to the activation of β-1,3-glucanase enzymatic activity and a reduction in callose deposition in the susceptible cassava variety. Time course analysis also showed that CBSV replication in susceptible cassava induced a strong up-regulation of RDR1, a gene previously reported to be a susceptibility factor in other potyvirus-host pathosystems. The differences in the transcriptional responses to CBSV infection indicated that susceptibility involves the restriction of callose deposition at plasmodesmata. Aniline blue staining of callose deposits also indicated that the resistant variety displays a moderate, but significant, increase in callose deposition at the plasmodesmata. Transcriptome data suggested that resistance does not involve typical antiviral defence responses (i.e. RNA silencing and salicylic acid). A meta-analysis of the current RNA-sequencing (RNA-seq) dataset and selected potyvirus-host and virus-cassava RNA-seq datasets revealed that the conservation of the host response across pathosystems is restricted to genes involved in developmental processes.

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Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 97%

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Molecular insights into Cassava brown streak virus susceptibility and resistance by profiling of the early host response

Anjanappa

Mehta

Okoniewski

et al. 2017

Molecular Plant Pathology

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“…Fraile and García-Arenal (2010) defines resistance as the plant's ability to limit virus multiplication by interfering with the disease cycle. Lecoq et al (2004) supported by Anjanappa et al (2016) explains complete immunity as the plants being unable to sustain virus replication. Resistance in a broader perspective is diverse and may range from 22 interference with virus development at cell, organ, individual plant or population level.…”

Section: Resistancementioning

confidence: 99%

“…Sometimes systemic hypersensitivity occurs (Murphy and Kyle, 1995;Tatineni and French, 2014) Resistance to virus movement between cells Virus gains entry into plant virus is sequestrated to islands of cells without induction of necrosis Plant defence mechanism confines the virus to inoculated cells (Lecoq et al, 2004) Complete resistance (immunity) There's contact between plant and virus but virus does not either gain entry or is not allowed to replicate after entry Virus may lack some necessary factors for pathogenesis or the plant's defence is strong to combat virus replication (Anjanappa et al, 2016;Kohm et al, 1993;Legnani et al, 1995) Resistance due to escape of infection mature plant escaping infection at adult stage but not earlier (same level of inoculum is used) Virus does not overcome the initial passive defence barriers of the plant (rigid cell walls) (Caranta et al, 1997) Resistance to inoculation by vectors There is no contact between plant and virus Vectors are not able to transmit the virus for some reason (Jones, 1998;Lecoq et al, 1979) While there are different types of small RNAs in plants, interestingly, they are generated by a related set of multiple genes following different pathways. There are four major sets of protein families which include Dicer-like, dsRNA binding, RNA-dependent RNA polymerase (RDRPs) and…”

Section: Rna Silencing As An Antiviral Defence Mechanism By Plantsmentioning

confidence: 99%

Assessment of Banana Streak MY virus-based infectious clone vectors in Musa ssp.

Onsarigo¹

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Banana streak disease, caused by a complex of different banana streak viruses (BSVs), occurs in all banana-producing countries. BSVs are genetically very diverse and can exist both as episomal forms or integrated into the host genome and both can be infectious to banana.Several field studies have assessed the infectivity of one or more BSV species on different banana genotypes with significant differences reported in virus incidence and symptom expression between and within genotypes. These studies used a severity index, based on symptom expression, to determine the resistance/susceptibility levels of the genotypes.Because of the great genetic variability amongst BSV species, symptoms of banana streak disease may vary widely and may be influenced by the cultivar and/or environmental conditions. Also this system of screening does not reflect the level of viral DNA accumulation In the current study, symptom variability was considerable with different Musa genotypes expressing distinct symptoms. Quantification of the levels of virus DNA showed that virus accumulation differs between genotypes, but also within plants of the same accession, and that severity scores do not correlate well with the viral load as measured using qPCR.Modified vectors with either ORF1 or ORF2 deleted were not infectious and the addition of a GFP ORF into two sites in the genome did not result in expression of this heterologous sequence from the constructs used in this study. Interestingly, two constructs with small inserts, initially designed for the purpose of gene silencing, were found to retain infectivity and maintain a heterologous sequence up to 110 nt. These studies confirm that BSMYV is infective in a broad range of Musa genotypes and cultivars but that further work is required to develop suitable vectors for either gene expression or gene silencing studies in banana

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The Biotechnological Story of Microbial Genes from Soil to Transgenic Plants

Kumari

Patra

Guha

et al. 2023

Sustainable Agriculture Reviews 60

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Characterization of Brown Streak Virus–Resistant Cassava

Abstract: replication. Our molecular characterization of CBSD resistance in cassava offers a robust virus-host system to further investigate the molecular determinants of CBSD resistance.Ravi B. Anjanappa MPMI 4

Cited by 26 publications

References 47 publications

Molecular insights into Cassava brown streak virus susceptibility and resistance by profiling of the early host response

Molecular insights into Cassava brown streak virus susceptibility and resistance by profiling of the early host response

Assessment of Banana Streak MY virus-based infectious clone vectors in Musa ssp.

The Biotechnological Story of Microbial Genes from Soil to Transgenic Plants

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