Factors affecting nucleosome disassembly by protamines in vitro. Histone hyperacetylation and chromatin structure, time dependence, and the size of the sperm nuclear proteins

Histone displaced in vitro from nuclei by protamine competition display a higher degree of hyperacetylation than the residual histones. In addition, hyperacetylated core particle pools are disassembled in vitro with a higher efficiency than control or nonacetylated core particles and when analyzed by electron microscopy display an elongated shape (length/width ratio = 1.52 +/- 0.19) instead of the round compact shape of control nucleosomes (length/width ratio = 1.06 +/- 0.06). In the absence of histone hyperacetylation, the fish protamines, salmine and iridine (32-33 residues), are relatively inefficient in disassembling nucleosomal core particles in vitro as compared to the large (65-70 residues), tyrosine-containing protamines from rooster (galline), squid, and cuttlefish which disassemble nucleosomes in a range of protamine concentrations close to physiological. The fact that an artificially cross-linked salmine dimer acquires the ability of the large protamines from rooster, squid, and cuttlefish to disassemble core particles in vitro and also binds more tightly to the DNA, suggests that the size of the sperm nuclear protamines is a critical factor in this process. Even when the core histones of spermatid chromatin are hyperacetylated in the trout testis, the replacement process by iridine or salmine is slow and time-dependent in vitro. However, since spermiogenesis in trout occurs over several weeks, the slow in vitro nucleosome disassembly process by salmine is sufficient to allow complete displacement, thus supporting the hypothesis that a protamine-mediated displacement of the histones from DNA in vivo may take place in the salmonid fishes by a mechanism similar to that in the rooster, squid, and cuttlefish.     

A model chromatin assembly system. Factors affecting nucleosome spacing

Poly[d(A-T)].poly[d(A-T)], when reconstituted with chicken erythrocyte core histones and subsequently incubated with sufficient histone H5 in a solution containing polyglutamic acid, forms structures resembling chromatin. H5 induces nucleosome alignment in about two hours at physiological ionic strength and 37 degrees C. The nucleosome spacing and apparent linker heterogeneity in the assembled nucleoprotein are very similar to those in chicken erythrocyte chromatin. Also, condensed chromatin-like fibers on the polynucleotide can be visualized. The binding of one mole of H5 per mole of core octamer is necessary to generate the physiological nucleosome spacing, which remains constant with the addition of more H5. The nucleosome repeat length is not a function of the core histone to poly[d(A-T)] ratio for values lower than the physiological ratio. With increasing ratios, in excess of the physiological value, nucleosome spacing first becomes non-uniform, and then takes on the close packing limit of approximately 165 base-pairs. In addition to eliminating possible base sequence effects on nucleosome positioning, poly[d(A-T)] allows nucleosomes to slide more readily than does DNA, thereby facilitating alignment. Evidence is presented that polyglutamic acid facilitates the nucleosome spacing activity of histone H5, primarily by keeping the nucleoprotein soluble. This model system should be useful for understanding how different repeat lengths arise in chromatin.     

Histone acetylation and chromatin pattern in cancer. A review

Chromatin phenotype is known to be significantly disrupted in cancer. This has been demonstrated in many morphologic studies on cancer and in recent years by the application of digital texture analysis for quantitative evaluation of chromatin phenotype in neoplasia. Studies have consistently demonstrated the role of chromatin phenotype as a biomarker of diagnosis and prognosis. The underlying molecular mechanisms for chromatin reorganization and its role as a biomarker are largely unknown, but epigenetic processes are likely to be a main factor that not only modify chromatin arrangement but in doing so alter gene expression profiles in a reversible fashion. Of the range of epigenetic modifications that might control chromatin phenotype, histone acetylation is a strong candidate because of its role in the direct modification of chromatin, both through local relaxation of nucleosomal structure and recruitment of chromatin remodeling complexes. The reversible nature of histone acetylation is therapeutically attractive for treatment of aberrant histone acetylation; however, it still remains to be seen whether histone deacetylase inhibitors are clinically applicable or for use primarily as valuable research tools. This review explores the role of histone acetylation in cancer development, as a potential therapeutic candidate and a potential biomarker in tissue pathology.     

Increase in initiation sites for chromatin directed RNA synthesis by acetylation of chromosomal proteins.

Treatment of rat liver chromatin with 0.7 mM acetic anhydride (1) leads to an approximately twofold increase in initiation sites for DNA-dependent RNA polymerase from $\text{E.}\text{coli}$. With reconstituted chromatin, in which only the histone moiety was acetylated, again a twofold increase in initiation sites could be observed, compared to control chromatin which had undergone the dissociation and reassociation procedure, but which had not been exposed to acetic anhydride.