Multiple enzyme forms of histone deacetylase and histone acetyltransferase exist in germinating maize embryos. We analyzed the association of the different enzymes to chromatin by ion exchange chromatography of subcellular fractions from different time points of embryo germination. The vast majority of histone deacetylase HD-1A was not bound to chromatin, since it was solubilized during chromatin isolation, regardless of its phosphorylation state and the phase of embryo germination. In contrast, HD-2 was chromatin bound during the entire germination pathway. Histone deacetylase HD-1B was present in a chromatin-bound and a soluble form; the ratio between these two forms changed during germination. Both nuclear histone acetyltransferases, HAT-A1 and HAT-A2, were tightly chromatin-bound and could only be released from chromatin by salt extraction. To test whether histone acetyltransferases or deacetylases are associated with the nuclear matrix, we analyzed nuclear matrix preparations from yeast, Physarum, and maize step by step for both enzyme activities. This analysis confirmed that part of the activity is chromatin bound, but no significant enzyme activity could be found in the final nuclear matrix, regardless of the preparation protocol. This result was further substantiated by detailed analysis of histone deacetylases and acetyltransferases during cellular fractionation and nuclear matrix preparation of chicken erythrocytes. Altogether our results suggest that the participation of these enzymes in different nuclear processes may partly be regulated by a distinct location to intranuclear components.
Agarose-encapsulated nuclear matrix preparations of the lower eukaryote Physarum polycephalum and the mammalian renal epithelial LLC-PKJ cell line were analyzed after various experimental protocols with respect to the protein composition. The effect of the mode of deproteinization (2 M NaC1,0.25 M ammonium sulfate or 25 mh4 lithium diiodosalicylate), presence of 2-mercaptoethanol, Ca", Cu2+, chelating agents, the sequence of protein extraction and nuclease digestion, the use of RNase, the temperature at which the experimental manipulations were performed and the use of hypotonic or isotonic conditions was investigated. No significant differences in the final nuclear matrix composition could be observed, regardless of the experimental procedure applied. In Physarum, the major nuclear matrix proteins range over 12-70 kDa with prominent bands at 24, 31, 37 and 45 kDa; the proteins of the matrix in U C -P K J cells extend predominantly over 40-80 kDa.Furthermore, no essential differences in the protein composition could be observed when type I and type I1 nuclear matrices from the highly differentiated LLC-PK, cell line were compared. The same was found for analogous matrix preparations of Physarum. Therefore, in both systems a distinction between type I/II matrix is questionable. Immunoblotting of the matrix preparations with a variety of antibodies against intermediate filament proteins and with antinuclear autoantibodies revealed the presence of intermediate filament proteins as components of the nuclear matrix. We conclude that the nuclear matrix represents a much more stable and reproducible structure than has been proposed so far, largely independent of changes in the preparation protocol.
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