Higher Order Chromatin Structures in Maize and Arabidopsis

doi:10.1105/tpc.10.8.1349

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Higher Order Chromatin Structures in Maize and Arabidopsis

Anna-Lisa Paul^a and Robert J. Ferl^a
^a Program in Plant Molecular and Cellular Biology, Department of Horticultural Sciences, University of Florida, Gainesville, Florida 32611

Correspondence to: Robert J. Ferl, robferl{at}nervm.nerdc.ufl.edu (E-mail), 352-392-4072 (fax).

We are investigating the nature of plant genome domain organizationby using DNase I– and topoisomerase II–mediatedcleavage to produce domains reflecting higher order chromatinstructures. Limited digestion of nuclei with DNase I resultsin the conversion of the >800 kb genomic DNA to an accumulationof fragments that represents a collection of individual domainsof the genome created by preferential cleavage at super-hypersensitiveregions. The median size of these fragments is ~45 kb in maizeand ~25 kb in Arabidopsis. Hybridization analyses with specificgene probes revealed that individual genes occupy discrete domainswithin the distribution created by DNase I. The maize alcoholdehydrogenase Adh1 gene occupies a domain of 90 kb, and themaize general regulatory factor GRF1 gene occupies a domainof 100 kb in length. Arabidopsis Adh was found within two distinctdomains of 8.3 and 6.1 kb, whereas an Arabidopsis GRF gene occupiesa single domain of 27 kb. The domains created by topoisomeraseII–mediated cleavage are identical in size to those createdby DNase I. These results imply that the genome is not packagedby means of a random gathering of the genome into domains ofindiscriminate length but rather that the genome is gatheredinto specific domains and that a gene consistently occupiesa discrete physical section of the genome. Our proposed modelis that these large organizational domains represent the fundamentalstructural loop domains created by attachment of chromatin tothe nuclear matrix at loop basements. These loop domains maybe distinct from the domains created by the matrix attachmentregions that typically flank smaller, often functionally distinctsections of the genome.

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