Browsing by Person "Mager, Svenja"

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    Nutritional regulation of DNA methylation and gene expression in maize
    (2018) Mager, Svenja; Ludewig, Uwe
    DNA methylation in plants plays a role in transposon silencing, genome stability and gene expression regulation. Environmental factors alter the methylation pattern of DNA and recently nutrient stresses, such as phosphate starvation, were shown to alter DNA methylation. DNA methylation had been frequently addressed in plants with notably small genomes that are poor in transposons. Here, part of the DNA methylome of nitrogen-, phosphorus- and zinc-deficient (-N, -P and -Zn, respectively) maize roots were compared by reduced representation sequencing and their relationship with gene expression under prolonged stresses analyzed. Tremendous DNA methylation loss was encountered in maize under nitrogen and zinc deficiency, but much less under phosphorus deficiency. This occurred only in the symmetrical cytosine contexts, predominantly in CG context, but also in the CHG context. In contrast to other plants, differential methylation in the more flexible CHH context was essentially absent. For each sample, specific nutrient deficiency-regulated genes were differentially expressed. In -Zn samples the lowest number of differentially expressed genes was found while -N and -P samples contained a similar number of differentially expressed genes. For all samples, differentially methylated regions (DMRs) were predominantly identified in transposable elements (TEs). A minor fraction of such DMRs was associated with altered gene expression of nearby genes in -N and -P. Interestingly, although these TEs were mostly hypomethylated, they were associated with both upand down-regulated gene expression. For -Zn, these associations were not found but a correlation between hypomethylation of gene bodies and expression of some genes. Here again, hypomethylation occurred with up- and downregulation of gene expression. The results suggested a different methylome regulation in maize compared to rice and Arabidopsis upon nutrient deficiencies indicating a nutrient- and species-specific association of genomic DNA methylation and gene expression. The limited correlation between differential DNA methylation and gene expression suggested that heritable regulation of the expression of nutrient deficiency-regulated genes was not the primary function of the methylation loss. Rather, the major function of the DNA methylation loss in this experiment may have been to increase the genetic diversity in the next generation by increased frequency of recombination events, mutations and transposable element movements.