Interactions between the lysine-rich histone F1 and deoxyribonucleic acid

1. The interactions of the lysine-rich histone F1 with DNA have been studied at various histone to DNA ratios, in water and in the presence of uni- and bi-valent cations. In water only, histone F1, even in fourfold excess, is unable to precipitate all the DNA. In 0.14m-sodium chloride, 0.8mg. of histone F1 is required to precipitate 1mg. of DNA, whereas in 0.07m-magnesium chloride only 0.4mg. is required. 2. Bivalent cations are also shown to be more effective in dissociating the DNA-histone complex. Histone F1 can be selectively removed from deoxyribonucleoprotein with 0.1m-magnesium chloride. 3. The precipitation of DNA by histone F1 is a reversible process and the complex can be taken in and out of solution by changing the ionic environment. 4. The bearing of these results on the observed ability of various DNA-histone complexes to act as templates for RNA synthesis is discussed.     

Fractionation of chick oviduct chromatin. Nuclease-resistant deoxyribonucleic acid.

Chromatin isolated from several chick tissues was treated with micrococcal nuclease. A limited degree of tissue specificity of chromatin DNA resistance to nuclease digestion was observed. No difference in the extent of nuclease resistance of chromatin DNA was detected during oestrogen-induced oviduct differentiation. This suggested that the amount of non-histone chromosomal protein does not play an important role in the sensitivity of chromatin DNA to nuclease digestion. Studies of nuclease resistance of chromatin DNA after dissociation and reconstitution of chromatin proteins and ethanol extraction of chromatin indicate that the histones protect the DNA from nuclease attack. Slow thermal denaturation of nuclease-resistant DNA suggests that the protected DNA sequences may be (A+T)-rich, and the (G+C)-rich satellites present in total chick DNA are sensitive to nuclease.     

Fractionation of deoxyribonucleic acid from phage-infected bacteria

1. DNA has been isolated in 90% yield from T5-infected cultures of Escherichia coli ;pulse'-labelled with [(3)H]thymidine. It had a buoyant density in caesium chloride solution identical with the DNA of mature T5 phage, and no components of unusual buoyant density were detected. 2. The DNA preparation was resolved into two major components of differing specific activity on a column of kieselguhr coated with methylated serum albumin. The DNA of high specific activity could be eluted from the column only with 2n-ammonia, and the firm binding did not appear to be due to an artifact of preparation. 3. A similar fractionation into two DNA components of differing specific activity was observed when the ;pulse'-labelled culture was lysed with sodium dodecyl sulphate and the lysate rocked with phenol. The DNA of high specific activity was found in the interface precipitate between the phenol and aqueous layers. 4. The amounts of DNA in the two fractions were measured at different times after infection and the radioactivity content of each was determined at various times after a short ;pulse' of [(3)H]thymidine. The interface fraction contained the replicating phage DNA, and the DNA from mature phage particles appeared in the aqueous fraction. 5. Analogous results were obtained with T2-infected E. coli. In the presence of chloramphenicol the DNA in the interface fraction was not converted into DNA extractable into the aqueous layer. Since chloramphenicol prevents the condensation of DNA into phage heads, it is suggested that any DNA in extended configuration is trapped inside the rigid-layer framework of the cell wall. 6. Treatment with lysozyme released much of the DNA from the interface precipitate. This DNA was firmly bound by the chromatographic column and had the same buoyant density in caesium chloride solution as normal T5-phage DNA. Sucrose-gradient sedimentation studies showed that it was heterogeneous and that as much as 60% sedimented faster than T5-phage DNA.     

Phosphorylation of the lysine-rich histones throughout the cell cycle.

The phosphorylating of the lysine-rich histone at various stages in the cell cycle has been studied. In rapidly dividing cell populations the lysine-rich histone is phosphorylated rapidly after synthesis and more slowly once bound to the chromosome. The half-life of hydrolysis of such interphase phosphorylation in 5 hr except during mitosis when the phosphata hydrolysis increases almost three-fold. During mitosis there is extensive phosphorylation at sites different from those phosphorylated during interphase and a smaller measure of sites common to both mitotic and interphase cells. The sites of mitotic phosphorylation are most critically distinguished from those phosphorylated in interphase by the rapidly hydrolysis of M-phase phosphohistone when the cells divide and enter the G1 phase of the cell cycle.     

The interaction of histones with simian virus 40 supercoiled circular deoxyribonucleic acid in vitro.

The interaction of supercoiled, circular SV40 DNA with calf thymus histone fractions has been studied. Five- to ten-fold less f1 histone is required to complex a given amount of DNA compared to the other histones. When the supercoiled DNA is converted to either the relaxed circular form, or full length linear molecules, or gragmented linear or denatured stands, the efficiency of complex formation with f1 histone markedly decreases. We conclude that f1 histone has a special ability to interact with supercoiled DNA. This conclusion is supported by the fact that supercoiled circular Col E1 DNA interacts with f1 as efficiently as does SV40 DNA.     

Depurination-induced infidelity of deoxyribonucleic acid synthesis with purified deoxyribonucleic acid replication proteins in vitro

Removal of purine bases from phi X174 single-stranded DNA leads to increased reversion frequency of amber mutations when this DNA is copied in vitro with purified DNA polymerases. This depurination-induced mutagenesis is observed at three different genetic loci and with several different purified enzymes, including Escherichia coli DNA polymerases I and III, avian myeloblastosis virus DNA polymerase, and eukaryotic DNA polymerases alpha, beta, and gamma. The extent of mutagenesis correlates with the estimated frequency of bypass of the lesion and is greatest with inherently inaccurate DNA polymerases which lack proofreading capacity. With E. coli DNA polymerase I, conditions which diminish proofreading result in a 3-5-fold increase in depurination-induced mutagenesis, suggesting a role for proofreading in determining the frequency of bypass of apurinic sites. The addition of E. coli single-stranded DNA-binding protein to polymerase I catalyzed reactions with depurinated DNA had no effect on the extent of mutagenesis. Analysis of wild-type revertants produced during in vitro DNA synthesis by polymerase I or avian myeloblastosis virus DNA polymerase on depurinated phi X174 amber 3 DNA indicates a preference for insertion of dAMP opposite the putative apurinic site at position 587. These results are discussed in relation both to the mutagenic potential of apurinic sites in higher organisms and to studies on error-prone DNA synthesis.