Plant Chromatin Structure and Post-Translational Modifications

Although a majority of the key works on chromatin structure and function have been carried out using animal tissues, studies of plant chromatin and the characterization of the histones and nonhistone chromosomal proteins are now developing well. There are clear functional differences between plant and animal genomes, including the percentage of total DNA transcribed, levels of ploidy, and the pathways of morphogenesis and cell differentiation. It is therefore not surprising that differences are appearing between animal and plant chromatin, for example, the consensus amino acid sequence for the plant H3 globular domain; the extensions to the basic domain regions of some plant histones such as H2A, which have specific interactions with linker DNA; the larger molecular weight of the plant H1 molecule with its extended basic domains correlated with short lengths of linker DNA, and the absence of the five residue binding segment in the globular part of plant H1, which suggests differences in the organization of higher order structure in plant chromatin. There are also unifying features between plant and animal chromatin, and the nature of plant material makes its study particularly advantageous in several areas. The regular nucleosome repeat and short lengths of linker DNA in some plants should provide more regular order structures for study, in which in the near absence of linker DNA, nucleosome position is the main, if not sole, determining factor in model building. However, the improved characterization and isolation of plant chromatin and associated molecules, for example, the isolation of the SPKK kinase gene in pea, are essential if major progress is to be made in our understanding of functional activities.