Herbivory in the Previous Generation Primes Plants for Enhanced Insect Resistance

Rasmann, Sergio; Vos, Marina De; Casteel, Clare L.; Tian, Donglan; Halitschke, Rayko; Sun, Ji; Agrawal, Anurag A.; Felton, Gary W.; Jander, Georg

doi:10.1104/pp.111.187831

Cited by 435 publications

(440 citation statements)

References 45 publications

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“…Independently from our findings, two independent studies by Slaughter et al (2012) and Rasmann et al (2012) demonstrate similar transgenerational resistance phenomena in response to priming-inducing stimuli. Slaughter et al (2012) discovered that progeny of Arabidopsis that had been treated with b-aminobutyric acid or an avirulent isolate of PstDC3000 (PstavrRpt2) are primed for SA-dependent resistance against H. arabidopsidis and PstDC3000.…”

Section: Discussionsupporting

confidence: 89%

Next-Generation Systemic Acquired Resistance

et al. 2011

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Systemic acquired resistance (SAR) is a plant immune response to pathogen attack. Recent evidence suggests that plant immunity involves regulation by chromatin remodeling and DNA methylation. We investigated whether SAR can be inherited epigenetically following disease pressure by Pseudomonas syringae pv tomato DC3000 (PstDC3000). Compared to progeny from control-treated Arabidopsis (Arabidopsis thaliana; C 1 ), progeny from PstDC3000-inoculated Arabidopsis (P 1 ) were primed to activate salicylic acid (SA)-inducible defense genes and were more resistant to the (hemi)biotrophic pathogens Hyaloperonospora arabidopsidis and PstDC3000. This transgenerational SAR was sustained over one stress-free generation, indicating an epigenetic basis of the phenomenon. Furthermore, P 1 progeny displayed reduced responsiveness of jasmonic acid (JA)-inducible genes and enhanced susceptibility to the necrotrophic fungus Alternaria brassicicola. This shift in SA-and JAdependent gene responsiveness was not associated with changes in corresponding hormone levels. Instead, chromatin immunoprecipitation analyses revealed that SA-inducible promoters of PATHOGENESIS-RELATED GENE1, WRKY6, and WRKY53 in P 1 plants are enriched with acetylated histone H3 at lysine 9, a chromatin mark associated with a permissive state of transcription. Conversely, the JA-inducible promoter of PLANT DEFENSIN1.2 showed increased H3 triple methylation at lysine 27, a mark related to repressed gene transcription. P 1 progeny from the defense regulatory mutant non expressor of PR1 (npr1)-1 failed to develop transgenerational defense phenotypes, demonstrating a critical role for NPR1 in expression of transgenerational SAR. Furthermore, the drm1drm2cmt3 mutant that is affected in non-CpG DNA methylation mimicked the transgenerational SAR phenotype. Since PstDC3000 induces DNA hypomethylation in Arabidopsis, our results suggest that transgenerational SAR is transmitted by hypomethylated genes that direct priming of SA-dependent defenses in the following generations.

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Section: Discussionsupporting

confidence: 89%

Next-Generation Systemic Acquired Resistance

et al. 2011

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“…In several cases, plant responses to biotic stress, such as enhanced defense reactions to herbivore and plant pathogen attacks, persist in the next generation, indicating inherited resistance (Kathiria et al 2010;Luna et al 2012;Rasmann et al 2012;Slaughter et al 2012). The transmission of stress-induced stress tolerance to the progeny was impaired when the RdDM pathway was not functional (Boyko et al 2010;Rasmann et al 2012). The reported results suggest that the exposure of the mother plant to biotic and abiotic stresses has an influence on its progeny.…”

Section: Epigenetic Stress Responses and Their Potential Inheritancementioning

confidence: 89%

“…Furthermore, environmentally induced changes in DNA methylation patterns and gene expression are transmitted to unstressed offspring (Hauben et al 2009;Verhoeven et al 2010;Bilichak et al 2012). In several cases, plant responses to biotic stress, such as enhanced defense reactions to herbivore and plant pathogen attacks, persist in the next generation, indicating inherited resistance (Kathiria et al 2010;Luna et al 2012;Rasmann et al 2012;Slaughter et al 2012). The transmission of stress-induced stress tolerance to the progeny was impaired when the RdDM pathway was not functional (Boyko et al 2010;Rasmann et al 2012).…”

Section: Epigenetic Stress Responses and Their Potential Inheritancementioning

confidence: 99%

Epigenetic Variation, Inheritance, and Selection in Plant Populations

Hirsch

Baumberger

Grossniklaus

2012

Cold Spring Harbor Symposia on Quantitative Biology

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Plant populations show phenotypic diversity, which may be caused by genetic and epigenetic variation. It has recently been shown that new epigenetic variants are generated at a higher rate than genetic variants and several studies have shown that epigenetic variation can be influenced by the environment. Although the heritability of environmentally induced epigenetic traits has gained increasing interest in past years, it is still not clear whether and to what extent induced epigenetic changes have a role in ecology and evolution. Some reports on model and nonmodel species support the possibility of adaptive epigenetic alleles, indicating that epigenetic variants are subject to natural selection. However, most of these studies rely solely on phenotypic data and no information is available about the underlying mechanisms. Thus, the role of inherited epigenetic variation for plant adaptation is unclear and further investigations are required to gain insights into the significance of epigenetic variation for ecological and evolutionary processes. Here, we review mechanisms of epigenetic regulation, epigenetic responses to environmental challenges, their inheritance, and their implication for adaptation and plant evolution.

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“…Increasing evidence is accumulating that environmental maternal effects may be adaptive, enhancing the fitness of the offspring when established under environmental conditions that resemble the maternal environment (Galloway and Etterson, 2007;Herman and Sultan, 2011). This form of adaptive transgenerational plasticity has been reported in response to several biotic and abiotic environmental cues, including temperature (Yakovlev et al, 2010), drought (Herman et al, 2012), shade (Galloway and Etterson, 2007), nutrient availability (Kou et al, 2011), salinity (Boyko et al, 2010), herbivory (Rasmann et al, 2012) or viral infection (Kathiria et al, 2010). As a result of all these studies, environmental maternal effects are now recognized as a relevant source of phenotypic variation that may have an essential role in local adaptations (Herman and Sultan, 2011;Holeski et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Mediation of seed provisioning in the transmission of environmental maternal effects in Maritime pine (Pinus pinaster Aiton)

2013

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Although maternal environmental effects are increasingly recognized as an important source of phenotypic variation with relevant impacts in evolutionary processes, their relevance in long-lived plants such as pine trees is largely unknown. Here, we used a powerful sample size and a strong quantitative genetic approach to analyse the sources of variation of early seedling performance and to identify seed mass (SM)-dependent and -independent maternal environmental effects in Maritime pine. We measured SM of 8924 individual seeds collected from 10 genotypes clonally replicated in two environments of contrasting quality (favourable and stressful), and we measured seedling growth rate and biomass allocation to roots and shoots. SM was extremely variable (up to 14-fold) and strongly determined by the maternal environment and the genotype of the mother tree. The favourable maternal environment led to larger cones, larger seeds and reduced SM variability. The maternal environment also determined the offspring phenotype, with seedlings coming from the favourable environment being 35% larger and with greater root/shoot ratio. Transgenerational plasticity appears, thus, to be a relevant source of phenotypic variation in the early performance of this pine species. Seed provisioning explained most of the effect of the maternal environment on seedling total biomass. Environmental maternal effects on seedling biomass allocation were, however, determined through SM-independent mechanisms, suggesting that other epigenetic regulation channels may be involved.

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Herbivory in the Previous Generation Primes Plants for Enhanced Insect Resistance

Cited by 435 publications

References 45 publications

Next-Generation Systemic Acquired Resistance

Next-Generation Systemic Acquired Resistance

Epigenetic Variation, Inheritance, and Selection in Plant Populations

Mediation of seed provisioning in the transmission of environmental maternal effects in Maritime pine (Pinus pinaster Aiton)

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