Histone H1 subtype synthesis in neurons and neuroblasts.

Rat cerebral cortex neurons contain the five histone H1 subtypes H1a-e and the subtype H1 zero present in other mammalian somatic tissues. The four subtypes H1a-d decay exponentially during postnatal development and are partially or totally replaced by H1e that becomes the major H1 subtype in adults. H1 zero accumulates in a period restricted to neuronal terminal differentiation. Here we study the synthesis of the H1 subtypes in cortical neurons and their neuroblasts by in vivo labeling with [14C]lysine. The subtype synthesis pattern of neuroblasts has been determined by labeling gravid rats during the period of proliferation of cortical neurons and synthesis in neurons has been studied by postnatal labeling. The subtype H1a is synthesized in neuroblasts but not in neurons and is therefore rapidly removed from neuronal chromatin. The synthesis of H1b and H1d is much lower in neurons than in neuroblasts so that these subtypes are replaced to a large extent during postnatal development. H1c is synthesized at levels much higher than the other subtypes both in neurons and neuroblasts, but its very high turnover, about one order of magnitude faster than that of H1e in neurons, favors its partial replacement during postnatal development. Comparison of the synthesis rates of H1 zero in newborn and 30-day-old rats shows that the accumulation of H1 zero in differentiating neurons is due to an increased level of synthesis.     

Structural heterogeneity of reconstituted complexes of DNA with typical and intermediate protamines

The binding of the intermediate proteins φ1 and φ3 from the mussel Mytilus edulis to DNA was studied in comparison with the typical protamine from the squid Loligo vuigaris using precipitation curves, thermal denaturation and X-ray diffraction techniques. The properties of protein φ1 appear to be very close to those of typical protamines while the properties of protein φ3 are notably different. The method of reconstitution influences the structural properties of the complexes. This effect is most pronounced in the case of protein φ3. The structural heterogeneity of the protein component in the complexes is discussed in the light of these observations.     

Differential acetylation of core histones in rat cerebral cortex neurons during development and aging

Core histones can be modified by aceylation and this modification has been correlated with the modulation of chromatin condensation and histone deposition. We have now studied the levels of acetylation of the core histones in rat brain cortical neurons from the middle of the period of neuronal proliferation through postnatal development and aging. The results show that the level of acetylation of H4 decreases with age. The kinetics of H4 deacetylation show a perinatal fast phase followed by a much slower phase that spans the rest of the period examined. H4 deacetylation is accounted for by the decrease of the monoacetylated species, the proportions of the more highly acetylated species remaining essentially constant. By contrast to histone H4, the overall levels of acetylation and the proportions of the different acetylated species of H2A, H2B and H3 remain unchanged throughout the period examined. Furthermore, the variants belonging to a given histone class always show the same level of acetylation. The fact that in neurons the level of monoacetylated H4 decreases during development and aging, in sharp contrast with the constancy of the levels of all other acetylated histone species, raises the possibility that in interphase chromatin monoacetylated H4 may have a central role in the modulation of chromatin structure. The results also suggest that the slow decrease of the proportion of monoacetylated H4 may imply a gradual loss of chromatin structural plasticity and thus lead to aging.