Immunofluorescent study of histone fractions F1 and F2a-1 in cultured cells

Cytophotometric determinations of DNA, histone, arginine, lysine, and their concentrations in eu- and heterochromatin of the cell nucleus of dysplasias, carcinoma in situ, and carcinoma of the human cervix uteri

In the cell nuclei of dysplasias, carcinoma in situ, and carcinoma the amount of DNA, histone, arginine, lysine, and their condensed areas were determined by cytophotometry. Moreover their concentrations in the euchromatic and heterochromatic areas of the nuclei were measured. Statistical analysis showed that the quantitative relations between parameters did not change during carcinogenesis. The significantly increased amount of lysine underlines the role of the lysine-rich histones in producing denser coiling of the chromatin fibril in heterochromatin.

The in situ labeling of histone H3 in chromatin by a fluorescent probe

A sulfhydryl-specific fluorescent probe, N-3-pyrene maleimide, has been shown to label with high efficiency the sulfhydryl groups of histone H3 in nonsheared chromatin. The probe labels chromatin preparations obtained by mild homogenization or nuclease treatment of rat liver and mouse thymocyte, but not chick erythrocyte nuclei. Mononucleosomes from all nuclear preparations are labeled by the probe. The reaction is inhibited by prior reaction of the chromatin with N-ethyl maleimide. The reaction kinetics show fast and slow components representing reactions with cysteinyl sulfhydryl groups and lysyl epsilon-amino groups, respectively. Dissociation of the chromatin by urea (6 M) or sodium dodecyl sulfate (SDS) increases the fluorescence intensity (2-3 fold) and is maximal at approx. 0.01-0.02% (w/v) SDS. Histones extracted from the labelled chromatin show that approx. 80-90% of the label is associated with the histone fraction and column chromatography of this fraction shows that the label is primarily associated with histone H3. Labelling of the isolated histone fractions shows significant labelling only of histone H3. The intrinsic fluorescence of tryptophan is quenched by the labelled histone H3, but not by iodide, suggesting that non-histone (tryptophan-containing) proteins lie in close proximity to the labelled histone H3 but are not immediately accessible to external solvent. The labelled chromatin exhibits fluorescence anistropy, the anistropy parameter being 0.19 +/- 0.003 for chromatin, 0.05 +/- 0.01 for mononucleosomes and 0.0 for isolated histone H3. This demonstrates the restriction placed on the label's mobility by the chromatin fiber. The formation of a superhelix at 60-100 mM NaCl has been monitored with the probe. An increase in fluorescence intensity at 80 mM NaCl is observed with intact chromatin (but not H-1 depleted chromatin) followed by dissociation of the octamer in 1.50-2.0 M salt accompanied by a large increase in labelling.

Distribution of antigenicity in chicken erythrocyte histone H5

We have compared the inhibitory strengths of eight peptides from chicken histone H5 to that of the parent protein (189 residues) in complement fixation by guinea pig anti-H5 serum complexed with the homologous histone. Two precisely delineated regions (residues 59 to 65 and 94 to 99) and two less-defined regions (between 66 and 93; 100 and 189) are depicted. The sequences of particular consequences are quite conserved in avian histone H5 while the most variable N-terminal portion of 31 residues has no inhibitory effect.

Immunofluorescent study of histone H5 in chick erythroid cells from developing embryos and adults

Indirect immunofluorescence has been used to detect the presence of histone H5 in single cells during avian erythropoiesis. Evidence is presented which demonstrates that this method specifically detects histone H5. The results show that the increase in the amount of H5 which can be extracted from nuclei during erythropoiesis is accounted for both by an increase in the amount of H5 per cell and by an increase in the total number of cells containing histone H5. Of particular interest are the observations that histone H5 is arranged within the nucleus in several distinct, reproducible patterns and that different patterns predominate at different stages of erythroid cell development. In addition to suggesting new possibilities for the role of histone H5, these findings indicate that immunofluorescence may be used profitably to explore the supramolecular organization of chromatin.

Studies on antibodies to histones by immunofluorescence

When mouse kidney tissue sections were extracted with 0.1 N hydrochloric acid, sera with antibodies to certain nuclear antigens no longer stained tissue nuclei by immunofluorescence. This effect was due to removal of histones and nuclear acidic proteins Sm and nuclear ribonucleoprotein by the acid. DNA remained in the nuclei of the acid-extracted tissue sections. When solutions of calf thymus histones were reacted with acid-extracted tissues, histones combined with nuclear DNA to form complexes of DNA-histone. These complexes contained antigenic determinants which reacted with sera containing antibodies to deoxyribonucleoprotein to give nuclear staining demonstrated by immunofluorescence. The reaction was immunologically specific in that sera with antibodies to Sm and nuclear ribonucleoprotein were not reactive with reconstituted DNA-histone in nuclei. Other basic proteins such as protamine, poly-L-lysine, and poly-L-arginine could not substitute for histones. The method is introduced as a specific and reproducible assay for study of antibodies to histones.