Abstract
The arrangement of chromatin within interphase nuclei seems to be caused by topological constraints and related to gene expression depending on tissue and developmental stage. In yeast and animals it was found that homologous and heterologous chromatin association are required to realize faithful expression and DNA repair. To test whether such associations are present in plants we analyzed Arabidopsis thaliana interphase nuclei by FISH using probes from different chromosomes. We found that chromatin fiber movement and variable associations, although in general relatively seldom, may occur between euchromatin segments along chromosomes, sometimes even over large distances. The combination of euchromatin segments bearing high or low co-expressing genes did not reveal different association frequencies probably due to adjacent genes of deviating expression patterns. Based on previous data and on FISH analyses presented here, we conclude that the global interphase chromatin organization in A. thaliana is relatively stable, due to the location of its 10 centromeres at the nuclear periphery and of the telomeres mainly at the centrally localized nucleolus. Nevertheless, chromatin movement enables a flexible spatial genome arrangement in plant nuclei.
Highlights
Interphase chromatin organization in relation to gene regulation and other nuclear functions is currently under intensive research (Bickmore and van Steensel, 2013)
Chromatin fiber motility and changing associations are the prerequisite for chromatin interactions important for regulating gene expression, DNA replication and repair (Fraser and Bickmore, 2007; Dekker, 2008; Zhang et al, 2012)
We applied BACs and BAC contigs containing A. thaliana euchromatin segments labeled in different colors for FISH experiments on flow sorted differentiated leaf nuclei to elucidate the degree of homologous and heterologous chromatin associations
Summary
Interphase chromatin organization in relation to gene regulation and other nuclear functions is currently under intensive research (Bickmore and van Steensel, 2013). Chromatin fiber motility and changing associations are the prerequisite for chromatin interactions important for regulating gene expression, DNA replication and repair (Fraser and Bickmore, 2007; Dekker, 2008; Zhang et al, 2012). The occurrence of spatial associations between chromatin segments were proven for centromeres, telomeres, replication origins, enhancers, promoters and chromosome break ends (Cavalli, 2007; Duan et al, 2010; Obe and Durante, 2010; Li et al, 2012; Sanyal et al, 2012; Crevillen et al, 2013; Dekker et al, 2013; Jin et al, 2013)
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