histone fraction
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N-Bromosuccinimide cleavage of a lysine-rich histone fraction (histone III-S) yields a peptide substrate, purified by reverse-phase h.p.l.c., for the Ca2+ + phospholipid-dependent protein kinase (protein kinase C). This substrate displays no reactivity with the cyclic AMP-dependent protein kinase, and may prove useful for the detection of protein kinase C activity in crude tissue extracts.

Because of contentions concerning the generality of cell-specific histone 5 (H5) in nucleated erythrocytes of species other than birds, the erythrocyte histones of carp, trout, perch, black crappie, and white sucker were studied under conditions which minimize proteolysis. All were examined by polyacrylamide gel electrophoresis, and histone 1 (H1) and H5 were purified by cation-exchange chromatography on Amberlite CG-50 and by exclusion chromatography through BioGel P60.A protein homologous to H5 could be isolated and identified from the mature erythrocytes of carp, trout, perch, and black crappie but not from white sucker. The relative amounts of H5 differed extensively and inversely in proportion to H1, implying some functional homology between these proteins. The extremely variable levels of H5, including its apparent absence from one species, suggests that typical H5 is not essential to the function or development of nucleated erythrocytes.Although H1 is the most divergent histone fraction, H5 is also highly variable. Fish erythrocyte H5 differs from avian H5 in relative electrophoretic mobility, ease of elution from Amberlite CG-50 cation-exchange columns, and amino acid composition. H5's from fish tend to have more threonine but less serine, arginine, glutamic acid, and histidine than avian H5's. Fish H5's are more diverse than avian H5's and resemble the H5 homologues from other extremely diverse species; thus avian H5 may be an extreme in specialization of an H1 subfraction.

1. Phosphoprotein phosphatases with activity towards the inhibitory subunit of troponin (troponin I), phosphorylase a and lysine-rich histone (fraction F1) have been fractionated from rat skeletal muscle by chromatography on Sephadex G-200 and polylysine-Sepharose. Six separate fractions were identified on the basis of substrate specificity and behaviour during chromatography. 2. All fractions showed similar Km values for any given protein substrate. The Km for troponin I (5 muM) was significantly lower than that previously reported. 3. Phosphatase activities towards troponin I and hosphorylase a did not show a requirement for bivalent-metal ions. Two of the fractions with only minor activity towards histone were activated by Mn2+. 4. Discontinuous polyacrylamide-gel-electrophoresis studies indicated that several of the fractions contained more than one phosphatase activity, and additionally showed that several of the activities could exist in different aggregation states. On the basis of these studies at least two phosphatases with activity only towards troponin I were identified. In addition, phosphorylase phosphatase (which has considerable activity towards troponin I) and a general phosphatase with activity towards all three substrates were found. 5. A fraction with mol.wt. of 150000 could be activated by freezing with 2-mercaptoethanol or by heating to 55 degrees C. This activation was accompanied by a decrease in mol.wt. to 25000. 6. The total amount of phosphatase with activity towards troponin I which was extracted would be sufficient to dephosphorylate all the troponin I present in skeletal muscle in approximately 10s.

Histones were extracted from frog livers and testes and analyzed by electrophoresis on long polyacrylamide gels and on sodium dodecyl sulfate (SDS)-containing polyacrylamide gels. Frog histones were found to be similar to those of calf thymus except that frog histone fraction F2A2 showed a marked dependence on the temperature at which the long gels were run, and frog histone fraction F3 could be separated from frog F2B on SDS-containing gels. Comparisons between frog liver and frog testis histones indicated that the testis contains as its major F1 component a fast migrating species not found in liver. Testis histones also showed less microheterogeneity of fractions F3 and F2A1 than liver histones. These were the only differences observed between liver and testis histones, even when testis histones were prepared from sperm suspensions that were rich in cells in the late stages of spermiogenesis. Thus it seems that, in Rana, the electrophoretic properties of the basic proteins of sperm differ from those of somatic cells only in the nature of histone F1 and in the degree of microheterogeneity of fractions F2A1 and F3.

Histone fraction F1 has been isolated and purified from macronuclei of the ciliated protozoan, Tetrahymena pyriformis. In many respects, Tetrahymena F1 is similar to that of other organisms. It is the only Tetrahymena histone soluble in 5% perchloric acid or 5% trichloroacetic acid, has a higher molecular weight than any other Tetrahymena histone, is the histone most easily dissociated from Tetrahymena chromatin, and is susceptible to specific proteolytic cleavage. However, unlike F1 in all other organisms, Tetrahymena F1 is not the slowest-migrating histone fraction when analyzed by polyacrylamide gel electrophoresis at low pH. Tetrahymena F1 also exhibits unusual behavior in sodium dodecyl sulfate-containing polyacrylamide gels, migrating faster than calf thymus F1 at pH 10, and slower than calf thymus F1 at pH 7.6. Tetrahymena F1 was found to be highly phosphorylated in rapidly growing cells, suggesting that the relationship between cell replication and F1 phosphorylation previously observed in mammalian cells may extend to all eukaryotes. The observation that extensive F1 phosphorylation occurs in macronuclei, which divide amitotically, argues against a unique role for F1 phosphorylation in the process of chromosome condensation at mitosis.

Histone fraction F2A1 has been isolated and purified from macronuclei of the ciliate Tetrahymena pyriformis. It migrates as a single species on sodium dodecyl sulphate-acrylamide gel electrophoresis, with a molecular weight indistinguishable from that of calf thymus F2A1. The solubility properties of Tetrahymena F2A1 are also similar to those of calf thymus F2A1. Electrophoretic analyses on urea-acrylamide gels indicate that Tetrahymena F2A1 consists of four or five subspecies, the two fastest having electrophoretic mobilities identical with those of the two major electrophoretically separable forms of calf thymus F2A1. High resolution (long gel) electrophoresis coupled with incorporation of radioactive acetate both in vivo and in vitro suggest that, as in the case of calf thymus F2A1, differentical acetylation of a parent molecule can explain the observed electrophoretic heterogeneity of Tetrahymena F2A1. Electrophoretic analysis of histones isolated from the micronucleus, which is genetically less active than the macronucleus, indicates that it contains largely the relatively unacetylated (parent) form of histone F2A1.