Chromatin organization in nuclei of sea urchin embryos. Comparison with the chromatin organization of the sperm.

The chromatin in sea urchin embryo nuclei and that in sperm heads are both organized in nucleosomes but show marked differences when analyzed by endonuclease digestion. Sperm chromatin DNA appears to be totally organized in nucleosomes that are highly resistant to nuclease hydrolysis. The kinetics of formation of acid-soluble oligonucleotides is slow and concerns only about 50% of the total DNA. In contrast, the DNA of embryo chromatin does not appear to be totally organized in nucleosomes since 5 to 10% is rapidly and preferentially hydrolysed into acid-soluble oligonucleotides without any appreciable fragmentation of the remaining parts. Futher digestion causes the formation of the usual pattern of DNA bands, as detected by gel electrophoresis. The length of the DNA segment associated with the embryo nucleosomes appears to be shorter than that of the DNA segment associated with the sperm nucleosomes. The kinetics of formation of acid-soluble oligonucleotides upon digestion of embryo chromatin is much faster than that of sperm chromatin and concerns almost all the chromatin DNA.     

DNA-binding proteins of mammalian mitochondria

Acid-soluble proteins were isolated from liver and spleen mitochondria and their ability to form complexes with DNA was investigated. According to electrophoresis data, acid-soluble proteins include about 20 polypeptides ranging in the molecular mass from 10 to 120 kDa. It was found that acid-soluble proteins form stable DNA-protein complexes at a physiological NaCl concentration. Different polypeptides possess different degrees of DNA affinity. There is no significant difference between DNA-binding proteins of mitochondria from liver and those from spleen as to their ability to form complexes with mtDNA and nDNA. In the presence of 5 microg of DNA most polypeptides were bound to DNA, and further increase in DNA amount affected little the binding of proteins to DNA. There was no distinct difference in DNA-protein complex formation of liver mitochondrial acid-soluble proteins with nDNA or mtDNA. Also, it was detected that with these mitochondrial acid-soluble proteins, proteases that specifically cleave these proteins are associated. It was shown for the first time that these proteases are activated by DNA. DNA-binding proteins including DNA-activated mitochondrial proteases are likely to participate in the regulation of the structural organization and functional activity of mitochondrial DNA.     

The accumulation of soluble deoxyribosidic compounds in relation to nuclear division in anthers of Lilium longiflorum

Intervals of sporogenous DNA synthesis in lily anthers are associated with marked accumulations of methanol- and acid-soluble deoxyribosidic compounds. There are differences in solubility between compounds accumulating at meiosis and those accumulating at mitosis. The formation of these compounds appears to be related to a breakdown of somatic DNA.     

The Accumulation of Soluble Deoxyribosidic Compounds in Relation to Nuclear Division in Anthers of Lilium longiflorum

Intervals of sporogenous DNA synthesis in lily anthers are associated with marked accumulations of methanol- and acid-soluble deoxyribosidic compounds. There are differences in solubility between compounds accumulating at meiosis and those accumulating at mitosis. The formation of these compounds appears to be related to a breakdown of somatic DNA.     

Incorporation of thymidine and iododeoxyuridine into the DNA of mouse tissues.

Mice were injected intravenously with a solution containing tritiated thymidine (TdR) and iodine-labelled iododeoxyuridine (IUdR). The ratio of 3H/125I activities was measured in the acid-soluble fraction and in the DNA of several tissues at various times from 0.08 to 24 h after injection. There did not appear to be any discrimination in favor of TdR in the acid-soluble fraction of the tissues. The amount of TdR incorporated into the DNA was four to five times greater than the amount of IUdR incorporated; moreover, this value remained relatively constant throughout the period of DNA synthesis under the conditions used. Although IUdR was destroyed more rapidly than TdR in the body, particularly at high concentrations of both precursors, this factor did not account for the major portion of the discrimination observed with tracer amounts of the two DNA precursors. Discrimination in favor of TdR as a precursor for DNA must, therefore, occur at some stage in the utilization of intracellular precursor.     

Synthesis of the acid-soluble proteins in early cleaving embryos of the sea urchin. Cyclic synthesis of histones.

Synthesis of the acid-soluble proteins in the early cleavage stage of the sea urichin, Hemicentrotus pulcherrimus, was investigated. As detected by the incorporation of lysine, the acid-soluble proteins were synthesized periodically even before the first cleavage, differing from the pattern of incorporation of tryptophan into the fraction. Cyclic synthesis occurred almost in parallel with DNA synthesis. However, the phase and periodicity of cyclic synthesis of the acid-soluble protein fraction were quite different from those found in the hot TCA-insoluble (acid-insoluble) protein fraction. The acid-soluble proteins were adsorbed on cation exchange resin, Amberlite CG-50, and gave an elution profile similar to that found for calf thymus histones. The migration pattern of these proteins on acrylamide gel also resembled that of histones.     

LPP-1 Infection of the Blue-Green Alga Plectonema boryanum: II. Viral Deoxyribonucleic Acid Synthesis and Host Deoxyribonucleic Acid Breakdown

Host and viral deoxyribonucleic acid (DNA) metabolism in LPP-1-infected Plectonema boryanum was studied by equilibrium centrifugation in CsCl gradients. Approximately 50% of the host DNA is degraded to acid-soluble material between 3 and 7 hr after infection. Most of the acid-soluble product is reincorporated into viral DNA. Incorporation of exogenous (3)H-adenine into viral DNA can be detected very early after infection (within the first 2 hr), but the bulk of viral DNA synthesis occurs between 6 and 8 hr. Both the breakdown of host DNA and the synthesis of viral DNA require protein synthesis during the first few hours of infection.     

Study of DNA-binding proteins in mitochondria of rat liver gamma-irradiation

Acid-soluble proteins were isolated from the liver mitochondria of control and irradiated (8 Gy) rats. By means of electrophoresis in 15% polyacrylamide gel, these proteins were separated into more than 20 polypeptides of molecular masses between 10 and 120 kDa. The irradiation of rats with a dose of 8 Gy led to changes in the polypeptide content of mitochondrial acid-soluble proteins in the postradiation period. It was found that the liver acid-soluble proteins of control and irradiated rats were able to form nucleoproteid complexes with DNA at the physiological NaCl concentration. It was shown that along with mitochondrial acid-soluble proteins, proteases were also released, their activity increased in the presence of DNA. Twenty four hours after irradiation of rats with 8 Gy, the activity of proteases cleaving mitochondrial acid-soluble proteins decreased. Probably, the acid-soluble proteins and DNA-activated proteases of mitochondria are involved in the regulation of the structural organization and functional activity of mitochondrial DNA.     

A nucleoside triphosphate-dependent deoxyribonuclease from Bacillus laterosporus. The mode of action of the enzyme.

The acid-soluble products of exhaustive digestion of native DNA with Bacillus laterosporus DNase consist of 6.5% of mononucleotides and 93.5% of oligonucleotides with an average chain length of 3.2. The results of viscometric studies and inactivation of transforming DNA indicate the existence of acid-insoluble intermediates and the selective degradation of the population of substrate molecules rather than a random nucleolytic action. Furthermore, sucrose density gradient analysis of partially digested DNA showed that the initial DNA added as a substrate disappeared progressively during the reaction, being replaced by much more slowly sedimenting acid-insoluble materials, which were eventually degraded into acid-soluble end products during the reaction; products intermediate in size between these two components were not detectable. Studies with DNA labeled at the 3'-terminus indicate that Bacillus laterosporus DNase does not attack DNA from 3'-hydroxyl ends to yeild acid-soluble or acid-insoluble materials in a random manner. The results presented in this paper indicate that the nature of the attack of B. laterosporus nuclease is similar to that previously proposed for Micrococcus luteus DNase. The possibility of the sequential release of acid-insoluble intermediate fragments as well as acid-soluble products from the terminal portion of DNA by the enzyme is discussed.     

Digestion of chromatin with deoxyribonuclease II

The action of DNAse II on DNA in chromatin was studied. The formation of acid-soluble products followed a two-phase kinetic curve. At the end of the first more rapid phase about 25% of DNA was degraded. Early in the degradation process DNA was converted into double stranded fragments, whose sizes were multiples of about 180 base pairs. As the degradation proceeded these fragments were reduced in size. After denaturation DNA from digested chromatin was resolved into discrete single stranded fractions, exact multiples of a ten-nucleotide length, forming a pattern very similar to that observed with DNAse I.     

Transglutaminase activity during senescence and programmed cell death in the corolla of tobacco (Nicotiana tabacum) flowers

Corolla life span of undetached flowers of Nicotiana tabacum was divided into stages from the closed corolla (stage 1) through anthesis (stage 5) to death (stage 9). Senescence began around stage 6 in the proximal part, concomitantly with DNA laddering. Nuclear blebbing, DNA laddering, cell wall modification, decline in protein, water, pigment content and membrane integrity were observed during senescence and PCD. Transglutaminase activity was measured as mono- and bis-derivatives of putrescine (mono-PU; bis-PU) and bis-derivatives of spermidine (bis-SD). Bis-derivatives decreased with the progression of senescence, while mono-PU increased during early senescence; derivatives were present in different amounts in the proximal and distal parts of the corolla. In excised flowers, exogenous spermine delayed senescence and PCD, and caused an increase in free and acid-soluble conjugated PA levels. Bis-PU was the most abundant PA-derivative before DNA laddering stage; thereafter, bis-PU generally decreased and mono-PU became the most abundant derivative.     

Degradation of Escherichia coli B Deoxyribonucleic Acid After Infection with Deoxyribonucleic Acid-Defective Amber Mutants of Bacteriophage T7

The degradation of bacterial deoxyribonucleic acid (DNA) was studied after infection of Escherichia coli B with DNA-negative amber mutants of bacteriophage T7. Degradation occurred in three stages. (i) Release of the DNA from a rapidly sedimenting cellular structure occurred between 5 and 6 min after infection. (ii) The DNA was cleaved endonucleolytically to fragments having a molecular weight of about 2 x 10(6) between 6 and 10 min after infection. (iii) These fragments of DNA were reduced to acid-soluble products between 7.5 and 15 min after infection. Stage 1 did not occur in the absence of the gene 1 product (ribonucleic acid polymerase sigma factor), stage 2 did not occur in the absence of the gene 3 product (phage T7-induced endonuclease), and stage 3 did not occur in the absence of the gene 6 product.     

Binding to DNA protects alpha/beta-type, small, acid-soluble spore proteins of Bacillus and Clostridium species against digestion by their specific protease as well as by other proteases.

Binding of alpha/beta-type, small, acid-soluble proteins from Bacillus subtilis and Clostridium bifermentans to DNA protected these proteins against cleavage by their specific protease (GPR) as well as by trypsin and chymotrypsin. These data suggest that alpha/beta-type, small, acid-soluble protein binding to DNA (i) may result in a structural change in these proteins, giving a more compact protein structure, and (ii) may be important in slowing the degradation of these proteins by GPR, in particular during sporulation.     

Conditions for initial chromatin endonucleolysis and the characteristics of its products

The restricted initial autohydrolysis of chromatin is used for obtaining its matrix-active fractions. Application of the method for isolating cell nuclei in the presence of 10 mM CaCl2 makes it possible to appreciably inhibit the cleavage of chromatin DNA in the course of isolation, namely to 0.9% according to the acid-soluble fraction. It is shown that at the initial stages of autohydrolysis the method of solubilization is by one order of magnitude more sensitive as compared to the measurement according to the acid-soluble fraction. Initial autohydrolysis is characterized by rapid increment of the amount of the solubilized fraction, delayed formation of mononucleosomes and by the capacity to a 20% activation in the presence of 10(-5) M histamine.     

STUDIES ON LIVER REGENERATION: I. 131IODODEOXYURIDINE AS A PRECURSOR of DNA IN NORMAL and REGENERATING RAT LIVER

Abstract. ¹³¹Iododeoxyuridine (¹³¹IDU) was injected into normal and partially hepatectomized rats, and the specificity of incorporation of this thymidine analogue into liver DNA was determined 2, 24 and 48 hr following intramuscular injection. At 2 and 24 hr after ¹³¹DU injection, a major proportion of radioactivity in the liver was in the acid-soluble fraction, whereas 48 hr after injection the label in the acid-soluble fraction had decreased considerably. In liver obtained 2 hr after injection of ¹³¹IDU, only 1.8–16.6% of the total radioactivity were in DNA. If, however, the tissue was subjected to formalin fixation, the acid-soluble label was extracted selectively, and of the remaining radioactivity 64–88% was in DNA. Therefore, the radioactivity that is not extracted by formalin may be used as a measure of DNA synthesis at the time of injection of ¹³¹IDU, thus obviating time-consuming biochemical fractionation procedures.     

Small acid-soluble proteins with intrinsic disorder are required for UV resistance in Myxococcus xanthus spores

Bacterial sporulation in Gram-positive bacteria results in small acid-soluble proteins called SASPs that bind to DNA and prevent the damaging effects of UV radiation. Orthologs of Bacillus subtilis genes encoding SASPs can be found in many sporulating and nonsporulating bacteria, but they are noticeably absent from spore-forming, Gram-negative Myxococcus xanthus. This is despite the fact that M. xanthus can form UV-resistant spores. Here we report evidence that M. xanthus produces its own unique group of low-molecular-weight, acid-soluble proteins that facilitate UV resistance in spores. These M. xanthus-specific SASPs vary depending upon whether spore formation is induced by starvation inside cell aggregations of fruiting bodies or is induced artificially by glycerol induction. Molecular predictions indicate that M. xanthus SASPs may have some association with the cell walls of M. xanthus spores, which may signify a different mechanism of UV protection than that seen in Gram-positive spores.     

Isolation and characterization of a bacteriophage T5 mutant deficient in deoxynucleoside 5''-monophosphatase activity.

A bacteriophage T5 mutant has been isolated that is completely deficient in the induction of deoxynucleoside 5'-monophosphatase activity during infection of Escherichia coli F. The mutant bacteriophage has been shown to be deficient in the excretion of the final products of DNA degradation during infection of E. coli F, and about 30% of the host DNA's thymine residues were reinocorporated into phage DNA. During infection with this mutant, host DNA degradation to trichloroacetic acid-soluble products was normal, host DNA synthesis was shut off normally, and second-step transfer was not delayed. However, induction of early phage enzymes and production of DNA and phage were delayed by 5 to 15 min but eventually reached normal levels. The mutant's phenotype strongly suggests that the enzyme's role is to act at the final stage in the T5-induced system of host DNA degradation by hydrolyzing deoxynucleoside 5'-monophosphates to deoxynucleosides and free phosphate; failure to do this may delay expression of the second-step-transfer DNA.     

Induction of single-strand regions in nuclear DNA by adriamycin.

Incubation of adriamycin with isolated nuclei converts nuclear DNA to a form which is susceptible to hydrolysis by $\text{Neurospora}$$\text{crassa}$ nuclease an enzyme highly specific for the cleavage of single-stranded DNA. The effect of adriamycin on nuclear DNA incubated in the presence of the nuclease can be determined by measuring the release of acid-soluble nucleotides or by analyzing the DNA after centrifugation in neutral sucrose gradients. Similar changes in chromatin structure are not observed during incubation of nuclei with adriamycin alone. In addition to adriamycin, daunomycin and ethidium bromide are also active in inducing the formation of DNA structures which are susceptible to the $\text{Neurospora}$$\text{crassa}$ nuclease. The results suggest that certain antitumor agents can induce the formation of single-strand regions in nuclear DNA and that these sites probably occur as a result of a DNA strand separating event.     

Demonstration of pyrimidine dimer-DNA glycosylase activity in vivo: bacteriophage T4-infected Escherichia coli as a model system.

An approach to the detection of pyrimidine dimer-DNA glycosylase activity in living cells is presented. Mutants of Escherichia coli defective in uvr functions required for incision of UV-irradiated DNA were infected with phage T4 denV+ or denV- (defective in the T4 pyrimidine dimer-DNA glycosylase activity). In the former case the denV gene product catalyzed the incision of UV-irradiated host DNA, facilitating the subsequent excision of thymine-containing pyrimidine dimers. Isolation of these dimers from the acid-soluble fraction of infected cells was achieved by a multistep thin-layer chromatographic system. Exposure of the dimers to irradiation that monomerizes pyrimidine dimers (direct photoreversal) resulted in the stoichiometric formation of free thymine. Thus, in vivo incision of UV-irradiated DNA dependent on a pyrimidine dimer-DNA glycosylase can be demonstrated.     

Formation of Cellular Deoxyribonucleic Acid During Productive Polyoma Virus Infection

It was previously shown that the majority of deoxyribonucleic acid (DNA) made in growing mouse embryo cells productively infected at low multiplicity with polyoma virus is cellular in nature and that some of this cell DNA contains discontinuities in the newly synthesized strand. Evidence obtained indicates the following. (i) Induction of cell DNA synthesis precedes the onset of detectable viral DNA replication by approximately 3 hr. (ii) Double-stranded cell DNA molecules, discontinuous in the newly synthesized strands, arise by direct synthesis (rather than by degradation of a high-molecular-weight precursor) only in the cell DNA replicated after initiation of viral DNA synthesis. (iii) This DNA component is continuously formed throughout the "late" stage of infection and is continuously converted into apparently normal cell DNA of high molecular weight without prior degradation to acid-soluble components.