Abstract
Inter-individual variability of conspecific plants is governed by differences in their genetically determined growth and development traits, environmental conditions, and adaptive responses under epigenetic control involving histone post-translational modifications. The apparent variability in histone modifications among plants might be increased by technical variation introduced in sample processing during epigenetic analyses. Thus, to detect true variations in epigenetic histone patterns associated with given factors, the basal variability among samples that is not associated with them must be estimated. To improve knowledge of relative contribution of biological and technical variation, mass spectrometry was used to examine histone modification patterns (acetylation and methylation) among Arabidopsis thaliana plants of ecotypes Columbia 0 (Col-0) and Wassilewskija (Ws) homogenized by two techniques (grinding in a cryomill or with a mortar and pestle). We found little difference in histone modification profiles between the ecotypes. However, in comparison of the biological and technical components of variability, we found consistently higher inter-individual variability in histone mark levels among Ws plants than among Col-0 plants (grown from seeds collected either from single plants or sets of plants). Thus, more replicates of Ws would be needed for rigorous analysis of epigenetic marks. Regarding technical variability, the cryomill introduced detectably more heterogeneity in the data than the mortar and pestle treatment, but mass spectrometric analyses had minor apparent effects. Our study shows that it is essential to consider inter-sample variance and estimate suitable numbers of biological replicates for statistical analysis for each studied organism when investigating changes in epigenetic histone profiles.
Highlights
Epigenetic traits are heritable traits that are not linked to changes in DNA sequence
In the model plant Arabidopsis thaliana, Roudier et al (2011) distinguished four chromatin states based on the distribution of 11 histone modifications and level of DNA methylation: transcriptionally active genes characterized by the presence of trimethylated H3K4 and H3K36; two types of repressive chromatin – regions associated with H3K27me3 under polycomb group-mediated control and classical heterochromatin marked by H3K9me2 and H4K20me1; and weakly expressed genes and intergenic regions with no typical set of chromatin modifications
Changes in epigenetic modifications of histones are related to numerous biological processes and warrant attention in various scientific investigations
Summary
Epigenetic traits are heritable traits that are not linked to changes in DNA sequence. They involve spatiotemporal changes in gene activity realized mainly via modifications of major chromatin components – methylation of cytosines in DNA and modifications of histone proteins These mechanisms, together with the activity of small and non-coding RNA molecules and distribution of histone variants, determine the structure of the chromatin in affected regions. In a subsequent more detailed study considering 16 chromatin features—including DNA sequence motifs, nucleosome occupancy, cytosine methylation, histone variants and histone modifications— Sequeira-Mendes et al (2014) characterized nine functional chromatin states in A. thaliana. They found distinct preferential associations of these chromatin states, further increasing the complexity of the plant’s chromatin arrangements
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