Analysis of the most tightly bound proteins in eukaryotic DNA

Proteins tightly bound to DNA: new data and old problems

Proteins tightly bound to DNA (TBP) comprise a group of proteins that remain bound to DNA after usual deproteinization procedures such as salting out and treatment with phenol or chloroform. TBP bind to DNA by covalent phosphotriester and noncovalent ionic and hydrogen bonds. Some TBP are conservative, and they are usually covalently bound to DNA. However, the TBP composition is very diverse and significantly different in different tissues and in different organisms. TBP include transcription factors, enzymes of the ubiquitin-proteasome system, phosphatases, protein kinases, serpins, and proteins of retrotransposons. Their distribution within the genome is nonrandom. However, the DNA primary structure or DNA curvatures do not define the affinity of TBP to DNA. But there are repetitive DNA sequences with which TBP interact more often. The TBP distribution within genes and chromosomes depends on a cell's physiological state, differentiation type, and stage of organism development. TBP do not interact with DNA in the sites of its association with nuclear matrix and most likely they are not components of the latter.

DNA end-independent activation of DNA-PK mediated via association with the DNA-binding protein C1D

DNA-dependent protein kinase (DNA-PK), which is involved in DNA double-strand break repair and V(D)J recombination, is comprised of a DNA-targeting component termed Ku and an approximately 465-kD catalytic subunit, DNA-PKcs. Although DNA-PK phosphorylates proteins in the presence of DSBs or other discontinuities in the DNA double helix in vitro, the possibility exists that it is also activated in other circumstances via its association with additional proteins. Here, through use of the yeast two-hybrid screen, we discover that the recently identified high affinity DNA binding protein C1D interacts with the putative leucine zipper region of DNA-PKcs. Furthermore, we show that C1D can interact with DNA-PK in mammalian cells and that C1D is a very effective DNA-PK substrate in vitro. Finally, we establish that C1D directs the activation of DNA-PK in a manner that does not require DNA termini. Therefore, these studies provide a function for C1D and suggest novel mechanisms for DNA-PK activation in vivo.

cDNA cloning, recombinant expression and characterization of polypetides with exceptional DNA affinity

Polypeptides remaining tightly associated with isolated genomic DNA are of interest with respect to their potential involvement in the topological organization and/or function of genomic DNA. Such residual DNA-polypeptide complexes were used for raising monoclonal antibodies by in vitro immunization. Screening of a murine lambdagt11 cDNA library with these antibodies released a positive cDNA (MC1D) encoding a 16 kDa polypeptide. The cloned homologous human cDNA (HC1D) was identified in the dbest data base by partial sequence comparison, and it was sequenced full length. The cDNA-derived amino acid sequences comprise nuclear location signals but none of the known DNA-binding motifs. However, the recombinantly expressed proteins show in vitro DNA binding affinities. A polyclonal antiserum to the recombinant MC1D protein immunostains sub-nuclear structures, and it detects a residual 16 kDa polypeptide on western blots of DNA digests. These results support the conclusion that the cloned cDNAs reflect mRNAs encoding one of the chemically-resistant polypeptides which can be detected in isolated genomic DNA by sensitive techniques, e.g. by125Iodine labeling and SDS-PAGE.

Microgel electrophoresis: sensitivity, mechanisms, and DNA electrostretching

Based on the treatment of microgels to remove proteins, we speculate that proteins may be bound to DNA in the microgels even after electrophoresis. We speculate that some DNA single-strand breaks may be a reflection of these protein-DNA complexes. We suggest methods to limit such artifacts, and present data demonstrating a lymphocyte DNA double-strand break sensitivity of 12.5 rads and day-to-day reproducibility of microgel electrophoresis using these principles. Extending these principles, we describe DNA behavior during alkaline and neutral microgel electrophoresis based on observations of the stained DNA and its migration patterns. During microgel electrophoresis, individual DNA molecules behave as if anchored at one end while the other end is free to migrate in response to the electric field. We capitalize on this behavior by developing a neutral microgel method to stretch chromosomes.

Stably DNA-bound chromosomal proteins

DNA accomplishes its biological function in a complex with nuclear proteins. A minor protein fraction has been found in chromatin which could not be dissociated from DNA by reagents abolishing non-covalent type of interactions. The controversy surrounding the nature of the protein moiety and the nature of the bond linking the two components on the one hand, and the fact pointing to its evolutionary conservatism and metabolic stability on the other, make it necessary to critically evaluate the data in view of the possible biological function for such proteins.

DNA sequences tightly bound to proteins in mouse chromatin: identification of murine MER sequences

The finding of stably (tightly) associated DNA-protein complexes in eukaryotic chromatin has provoked many hypotheses and speculations concerning their possible role. While the answer of this question is not envisaged yet, it is clear that elucidation of the nature of the individual components involved in such complexes is a necessary step in this direction. Here, the nature of several mouse DNA sequences in the vicinity of a putative stably attached protein is studied. Eight independently isolated clones containing such sequences were compared to known sequences in GenBank. Two clones were found to belong to different subfamilies of repetitive sequences, organized into a larger family--the L1md family. One clone harbors a sequence that is a member of the Alu-type family. Four of the cloned sequences are preset in low copy numbers, but the computer search found similar sequences in various genomic regions of different rodents. These facts, together with the finding that regions homologous to the above clones often flank other repetitive elements in the genome, suggest that the cloned sequences belong to new, not yet described families of repeats in the murine genome. It is possible that they correspond to the medium reiteration frequency sequences, MER-sequences, discovered recently in the human genome (Jurka, 1990; Kaplan and Duncan, 1990). Particularly intriguing is the homology found at the integration sites of polyoma virus in two transformed cell lines with two of these clones.

Chemical and enzymatic analysis of covalent bonds between peptides and chromosomal DNA

DNA from Ehrlich ascites tumor (EAT) cells and from human placenta was examined for covalent bonds between hydroxy amino acid residues in peptides and nucleotide phosphate groups. The residual proteinaceous material in highly purified DNA was radiolabelled with 125Iodine and the linking-groups between peptides and nucleotides released by combined protease and nuclease treatment were investigated with respect to their chemical and enzymatic stabilities. The residual nucleotide(s)-peptide(s) fraction from DNA isolated after prolonged alkaline cell lysis and phenol extraction contains mainly alkali and acid-stable but phosphodiesterase-sensitive peptide-nucleotide complexes which indicates phosphodiesters between tyrosyl residues in peptides and nucleotide phosphates. In contrast, the linking-group fraction from DNA isolated under native conditions contains additional peptide components. (a) Phospho-peptides that co-purify with DNA but that are not covalently bound to nucleotides. (b) A fraction of peptides that is released from nucleotides by alkali in a time and concentration-dependent reaction. Evidence is presented indicating that the latter fraction involves phospho-triesters between hydroxy amino acid residues in peptides and internucleotide phosphates. The phosphodiesters between hydroxy amino acids and nucleotide phosphates representing the predominant class of peptide-nucleotide complexes in alkali-denatured DNA are most likely side products of peptide-nucleotide phospho-triester hydrolysis.

Bovine pancreatic DNase I binds very tightly to DNA fragments and may be mistaken for putative endogenous nuclear proteins covalently bound to DNA

Using published methods for the isolation of nuclear proteins tightly bound to DNA, and resistant to removal by SDS or 16-BAC detergent and urea, several new protein bands in the region of 55 kd and 62 kd on SDS gel and 43 kd and 70 kd on 16--BAC gel electrophoresis were identified in extracts of avian erythroid nuclei. These bands were radiolabelled by subjecting the DNA--protein complexes to nick--translation in the presence of [32P]--dCTP, followed by prolonged digestion with excess bovine DNase I. Amino acid sequence analysis shows that these bands contain DNase I. These results indicate that DNase I can form stable complexes with DNA, and suggest that DNase I--DNA complexes may be mistakenly identified as nuclear proteins covalently bound to DNA.

Site-specific location of covalent DNA-polypeptide complexes in the chicken genome

A nitrocellulose filter binding assay was applied to isolate and to analyze the fraction of chicken DNA fragments associated with residual nuclear polypeptides resistant to SDS/proteinase K treatment and phenol extraction. It is shown that the DNA-polypeptide complexes retained on nitrocellulose filters are located on a non-random sub-set of DNA sequences. (a) Southern analysis reveals that the fractions of DNA fragments from chicken erythrocytes and from hen oviduct cells associated with the resistant polypeptides have a lower sequence complexity than unfractionated DNA. Moreover, the retained DNA fractions from different cell types of the same species are highly homologous. (b) All DNA fragments of the transcriptionally active and inactive ovalbumin gene map in the DNA fraction passing the filters indicating that the tight DNA-polypeptide complexes are not remnants of transcription complexes. (c) By use of a genomic sub-set library prepared from DNA retained on filters, clones were isolated with sequences mapping specifically in the DNA fraction associated with the tight DNA-polypeptide complexes. The results are consistent with fixed covalent DNA-polypeptide complexes in the chicken genome whose location is essentially identical in different cell types of the same species and apparently determined by DNA signal-sequences.

An evolutionarily conserved protein fraction stably linked to DNA

Chromatins from four evolutionarily remote species (insect, fish, amphibian and bird) were isolated, high-salt-extracted and extensively deproteinized to remove noncovalently associated proteins. A protein fraction resisting the extraction procedures was found firmly linked to DNA in all four chromatins. Two-dimensional tryptic peptide mapping revealed a remarkable evolutionary conservativeness of this protein component, suggesting an indispensable function for it in the nucleus.

Sequence organization and cytological localization of the minor satellite of mouse

A complete 120 bp genomic consensus sequence for the mouse minor satellite has been determined from enriched L929 centromeric sequences. The extensive sequence homology existing between the major and minor satellite suggests an evolutionary relationship. Some sequences flanking the minor satellite has also been identified and they provide insight into centromeric DNA organization. Isotopic in situ hybridization analysis of the minor satellite to mouse L929 and Mus musculus metaphase spreads showed that this repetitive DNA class is localized specifically to centromeres of all chromosomes of the karyotype. With the use of high resolution non-isotopic fluorescence in situ hybridization the minor satellite is further localized to the outer surface of the centromere in a discrete region at or immediately adjacent to the kinetochore. Our cytological data suggests that the minor satellite might play a role in the organization of the kinetochore region rather than, as previously suggested, sites for general anchoring of the genome to the nuclear matrix.

Functional role of a highly repetitive DNA sequence in anchorage of the mouse genome

The major portion of the eukaryotic genome consists of various categories of repetitive DNA sequences which have been studied with respect to their base compositions, organizations, copy numbers, transcription and species specificities; their biological roles, however, are still unclear. A novel quality of a highly repetitive mouse DNA sequence is described which points to a functional role: All copies (approximately 50,000 per haploid genome) of this DNA sequence reside on genomic Alu I DNA fragments each associated with nuclear polypeptides that are not released from DNA by proteinase K, SDS and phenol extraction. By this quality the repetitive DNA sequence is classified as a member of the sub-set of DNA sequences involved in tight DNA-polypeptide complexes which have been previously shown to be components of the subnuclear structure termed 'nuclear matrix'. From these results it has to be concluded that the repetitive DNA sequence characterized in this report represents or comprises a signal for a large number of site specific attachment points of the mouse genome in the nuclear matrix.

A protein fraction stably linked to DNA in plant chromatin

DNA from the chromatin of roots and shoots of maize seedlings was isolated and extensively deproteinized by repeated high-salt extractions, by subsequent deproteinizations eliminating noncovalently associated proteins and by CsC1 density gradient centrifugation. Nevertheless, a protein component resisting all extraction procedures was found firmly associated to plant nuclear DNA. This component was responsible for the (125)I uptake when a DNA preparation had been labeled by the chloramine-T method.A residual oligodeoxynucleotide-oligopeptide complex was obtained after extensive digestions of the initial DNA-protein complex with proteases and nucleases. The stability of this complex to different chemical treatments suggested a phosphoester type of a linkage. The hydrolysis of this complex by phosphodiesterases indicated that the protein component was linked to plant chromosomal DNA through a phosphodiester bond formed by a hydroxyaminoacid and a 5'-end DNA phosphate. Two-dimensional tryptic peptide mapping of the proteins isolated from the two maize chromatins revealed a high degree of similarity to the corresponding proteins of animal origin. Its conservative structure suggests an important role for this protein component in the functioning of the eukaryotic genome.

The distribution of tightly bound proteins along the DNA chain reflects the type of cell differentiation

Distribution of proteins tightly bound to DNA (TBP) along the DNA chain was found to depend on the cell lineage. DNA sequences coding for alpha globin genes are preferentially represented in the TBP-associated DNA fractions isolated from erythroid cells (erythroblasts, mature erythrocytes, differentiated and non-differentiated Friend erythroleukemia cells), but not from cultured fibroblast cells. In transcriptionally active nuclei, complexes of TBP interact with the nuclear matrix, while in mature erythrocytes this interaction disappears.

Sub-set characteristics of DNA sequences involved in tight DNA/polypeptide complexes and their homology to nuclear matrix DNA

Polypeptides co-isolating with DNA induce the binding of a fraction of native DNA fragments to nitrocellulose filters. Southern analysis reveals a high intensity of self-hybridization of the DNA sequences retained on nitrocellulose filters. Consistently, the DNA fraction passing the filters shows only weak hybridization when probed with DNA retained on filters. This indicates that the DNA/polypeptide complexes reside on a non-random sub-set of DNA sequences. Moreover, a high degree of homology was found between residual nuclear matrix DNA sequences and the DNA sequences retained on nitrocellulose filters. This indicates that the DNA sequences associated with tightly bound polypeptides originate from sites where the genome is salt-stably anchored in the nuclear matrix.

Radiolabelling of DNA/polypeptide complexes in isolated bulk DNA and in residual nuclear matrix DNA by nick-translation

Conditions are described that allow 32P-radiolabelling and detection of tight complexes between DNA and polypeptides by nick-translation. Prolonged nick-translation of purified bulk DNA results in radiolabelled complexes migrating on SDS-polyacrylamide gels with apparent molecular weights of 68 kd and 54 kd respectively. Residual nuclear matrix DNA which is not accessible to DNase I on the nuclear level becomes accessible to radiolabelling by nick-translation on the nuclear matrix level. In this case the in situ radiolabelled complexes migrate on SDS-polyacrylamide gels with apparent molecular weights of 68 kd and 100 kd. The DNA/polypeptide complexes are stable during treatments with SDS, beta-mercapto ethanol and alkali which points to covalent bonds between the polypeptides and DNA strands.

Distribution of tissue-specific tightly bound non-histone proteins in the first level of repeating chromatin structures

Non-histone proteins, tightly bound to DNA, have been extracted from whole chromatin and core particles prepared from pig liver or kidney. We have investigated by bidimensional slab gel electrophoresis the distribution of this protein class in the first level of repeating structure of chromatin. Our results reveal that non-histone proteins tightly bound to DNA are a heterogeneous protein class. Some of them, particularly in the core particles, appear to be essentially the same in both tissues, though having differences in their isoelectric point, which may be attributed to postsynthetic modifications. We have calculated that this protein class is associated to only 10% of nucleosomes, these nucleosomes having, on the average, one protein molecule for each core DNA. The tissue-specific proteins have high molecular mass (ranging from 135 kDa to 70 kDa in liver, over 135 kDa in kidney) and, in kidney, a more basic isoelectric point. These proteins are mainly located outside the core particles; they could be situated in the spacer regions and/or be involved in determining higher levels of chromatin organization.

Age-dependent changes in the level of a 34 kDa DNA-binding protein in developing chick embryo liver

The relative amounts of a DNA-binding protein of 34 kDa increased during the early stages of development of chick embryo liver. The content of this protein reached a maximum in 18-19-day-old embryonic livers and decreased afterwards in older embryonic and post-natal chick livers. The 34 kDa polypeptide is the major DNA-binding protein (DBP) of embryonic liver and it preferentially binds to single-stranded DNA. The quantity of the 34 kDa DBP was relatively very low in embryonic muscle, heart and brain.

Antibodies to 5 M urea soluble chromosomal proteins from HeLa cells

The tissue specificity of a chromosomal protein fraction, extractable from chromatin with 5 M urea at low ionic strength, has been examined in HeLa, A549 and HT 29 cells. Electrophoresis in polyacrylamide gels indicates that each cell type has a different content of 5 M urea soluble proteins which are distinguishable from the histones, from the tight DNA-binding proteins and from the high-mobility-group chromosomal proteins. Antibodies against 5 M urea soluble proteins extracted from HeLa cells were produced in mice. Although each of the mice tested prior to immunization contained a detectable amount of antibodies against both the 5 M urea soluble proteins and tight DNA-binding proteins, immunization elevated the level of the antibodies in the serum over 100-fold. The antibodies do not distinguish between the 5 M urea extracts obtained from different sources because most of the antibodies are directed against antigens shared by the cells studied. Immunofluorescence studies reveal that components which cross-react with 5 M urea soluble chromosomal proteins are also present in the cytoplasm. We conclude the following. (1) 5 M urea extracts from chromatin a group of proteins which differs among cells. (2) Mice contain detectable amounts of autoantibodies against these chromosomal proteins. (3) Immunization with the 5 M urea extractable fraction elicits antibodies against a restricted number of antigenic components which are shared among the cells studied. (4) 5 M urea extractable proteins are found both in the nucleus and cytoplasm; part of these may be cytoskeletal elements. Because the antisera do not react with histones, high-mobility-group proteins and tight DNA-binding proteins, they may be used for various functional studies on the 5 M urea extractable chromosomal protein fraction.

Screening of isolated DNA for sequences released from anchorage sites in nuclear matrix

Isolated chromosomal DNA is associated with polypeptides that are not released from DNA by several methods designed to purify DNA, e.g. treatment with sodium dodecyl sulphate. DNA fragments associated with these very tight DNA/protein complexes show high affinity to nitrocellulose filters in the presence of salt concentrations of 500 mM or greater. Consequently, a fraction of AluI-fragmented native DNA comprising the complexes and 0.2 to 0.3 micron of vicinal DNA can be isolated by one filtration step. This fraction of DNA shows characteristics of residual DNA sequences retained in nuclei after extraction with nucleases and high salt (nuclear matrix). The DNA fragments retained on filters are highly enriched in replicative DNA; and their degree of hybridization with poly(A)+ RNA points to enrichment in actively transcribed sequences. The results support previous work indicating that the very tight DNA/polypeptide complexes co-isolating with DNA under conditions that release other peptide materials from DNA may be anchorage sites of DNA in the nuclear matrix. Moreover, the method described here allows isolation of replicating and actively transcribed DNA sequences directly from isolated total genomic DNA by skipping artefact-prone isolations of the nuclear matrix.

Antibodies to the most tightly bound proteins in eukaryotic DNA. Formation of immuno-complexes with 'nuclear matrix' components

Chromosomal DNA is associated with polypeptides covalently bound to internal DNA ends. Since these polypeptides can only be released from chromosomal DNA by enzymes or other agents hydrolysing phosphodiester bonds they were termed 'the most tightly bound' (MTB) polypeptides in DNA. Antibodies developed against the MTB polypeptides are shown to form immunocomplexes with major 'nuclear matrix' polypeptides as well as with polypeptides which are still associated with 'nuclear matrix' DNA isolated by means of SDS/proteinase K and phenol. Immuno-complex formation is revealed by immunoblotting and by indirect immunofluorescence. Thus, since MTB polypeptides, major 'nuclear matrix' polypeptides and 'nuclear matrix' DNA-associated polypeptides share common antigenic sites they can be considered to be identical or at least closely related. This suggests that a fraction of distinct 'nuclear matrix' polypeptides is either transiently or permanently linked to DNA by covalent bonds. Consistently, isolated eukaryotic 'bulk' DNA is inevitably associated with residual 'nuclear matrix' polypeptides.

Proteins tightly bound to HeLa cell DNA at nuclear matrix attachment sites

DNA-protein complexes have been isolated from HeLa cell nuclei and nuclear matrix preparations. Two proteins, 55 and 66 kilodaltons in size, remain bound to HeLa DNA after treatment at 80 degrees C in 2% sodium dodecyl sulfate and purification by exclusion chromatography on Sepharose 2B-CL in the presence of 0.3% sodium dodecyl sulfate. These proteins appear to be tightly bound but not covalently linked to the DNA, and they are distributed over the DNA with an average spacing of 40 kilobase pairs. This spacing distribution remains essentially constant throughout the cell cycle. The proteins are bound to the residual 2% of HeLa cell DNA which remains attached to the nuclear matrix after extensive nuclease digestion, a condition which reduces the average size of the DNA to approximately 150 base pairs. Our results suggest that these tightly bound proteins are involved in anchoring cellular DNA to the nuclear matrix. These tightly bound proteins are identical by partial peptide mapping to proteins found tightly bound to the DNA of mammalian, plant, and bacterial cells (D. Werner and C. Petzelt, J. Mol. Biol. 150:297-302, 1981), implying that these proteins are involved in the organization of chromosomal domains and are highly conserved in both procaryotic and eucaryotic cells.

Protein contaminants of sodium dodecyl sulfate-polyacrylamide gels

Many artifacts and confusing results have arisen following the use of sodium dodecyl sulfate-polyacrylamide gel electrophoresis and highly sensitive detection methods such as silver staining, in vitro iodination, and immunological reactions ("Western blotting"). Investigations into many areas of biology, from proteins tightly bound to DNA to common antigenic determinants of intermediate filaments, may have been affected by this confusion. Some who have suspected contamination believed 2-mercaptoethanol to be the source, but data in this report show that the contaminating proteins are skin proteins, especially keratins ranging from 54 to 57 kDa and 65 to 68 kDa.

A protease-resistant protein is a structural component of the scrapie prion

Fractions purified from scrapie-infected hamster brain contain a unique protein, designated PrP. It was labeled with N-succinimidyl 3-(4-hydroxy-5-[125I]-iodophenyl) propionate, which did not alter the titer of the scrapie prion. The concentration of PrP was found to be directly proportional to the titer of the infectious prion. Both PrP and prion infectivity were resistant for 2 hr at 37 degrees C to hydrolysis by proteinase K under nondenaturing conditions. Prolonging the digestion resulted in a concomitant decrease in both PrP and the scrapie prion. When the amino-acid-specific proteases trypsin or SV-8 protease were used instead of proteinase K, no change in either PrP or the prion was detected. The parallel changes between PrP and the prion provide evidence that PrP is a structural component of the infectious prion. Our findings also suggest that the prion contains only one major protein, namely PrP.

Proteins tightly bound to HeLa cell DNA at nuclear matrix attachment sites

DNA-protein complexes have been isolated from HeLa cell nuclei and nuclear matrix preparations. Two proteins, 55 and 66 kilodaltons in size, remain bound to HeLa DNA after treatment at 80 degrees C in 2% sodium dodecyl sulfate and purification by exclusion chromatography on Sepharose 2B-CL in the presence of 0.3% sodium dodecyl sulfate. These proteins appear to be tightly bound but not covalently linked to the DNA, and they are distributed over the DNA with an average spacing of 40 kilobase pairs. This spacing distribution remains essentially constant throughout the cell cycle. The proteins are bound to the residual 2% of HeLa cell DNA which remains attached to the nuclear matrix after extensive nuclease digestion, a condition which reduces the average size of the DNA to approximately 150 base pairs. Our results suggest that these tightly bound proteins are involved in anchoring cellular DNA to the nuclear matrix. These tightly bound proteins are identical by partial peptide mapping to proteins found tightly bound to the DNA of mammalian, plant, and bacterial cells (D. Werner and C. Petzelt, J. Mol. Biol. 150:297-302, 1981), implying that these proteins are involved in the organization of chromosomal domains and are highly conserved in both procaryotic and eucaryotic cells.

Phosphodiester bonds between polypeptides and chromosomal DNA

Polypeptides co-purifying with DNA in alkali are covalently bound to DNA. DNA purified by treatment with alkali, sodium dodecyl sulphate and phenol absorbed 125I under conditions designed to radioiodinate exclusively tyrosine and histidine in peptides. A significant amount of the absorbed 125I remained associated with DNA during treatment with phenol as well as during precipitation with ethanol from neutral and alkaline solutions. However, after prolonged digestion with proteinase K, most of the radiolabelled material could be removed from 125I-treated DNA. Further treatment with a second protease (Pronase) released no larger fraction of the 125I label. The residual radiolabelled material could be precipitated together with DNA by ethanol and it remained associated with DNA also in the presence of alkali (95 degrees C), acid (37 degrees C) and hydroxylamine (37 degrees C). In contrast, radiolabelled peptides were released from DNA by treatment with hot piperidine (10% at 95 degrees C) and by agents that hydrolyse peptides and modify DNA, e.g. strong acid (95 degrees C) and formic acid/diphenylamine. The radiolabelled peptides, once released from DNA by these chemical methods, could be further cleaved by Pronase. This shows that the residual DNA/peptide complex isolated after prolonged protease digestion is protease-resistant unless it is cleaved or otherwise modified by harsh chemical treatment. The linking groups between deoxynucleotides and the radiolabelled residual peptides could be isolated by digestion of DNA in the DNA/peptide complex. Radiolabelled peptides could be released from this linking group material by phosphodiesterases, indicating the involvement of phosphodiesters in the linking groups.

Artifacts in sodium dodecyl sulfate-polyacrylamide gel electrophoresis due to 2-mercaptoethanol

Mercaptoethanol, when present in the sample buffer during sodium dodecyl sulfate-polyacrylamide gel electrophoresis, is responsible for the appearance of two nonprotein bands (electrophoretic mobilities corresponding to 68 and 54 kdalton) stainable with silver and with Coomassie blue. After iodination in vitro of DNA preparations isolated by alkaline phenol extraction using chloramine-T procedure, part of the radioactive label is found in these bands, provided the reaction is terminated by mercaptoethanol, whereas only a diffuse background is present in this area if the reaction is stopped by sodium metabisulfite. Similar results are obtained with highly purified total cytoplasmic RNA. The results indicate that the appearance of the 68- and 54-kdalton bands is in artifact. The relevance of these results to the proteins tightly bound to DNA is discussed.

DNA double strand breaks in Ehrlich ascites tumour cells at low doses of x-rays. I. Determination of induced breaks by centrifugation at reduced speed

DNA double strand breaks (dsb) were determined in Ehrlich ascites tumour cells at doses down to 5 Gy. The method is based on the separation of DNA from other components by heating in a solution of pronase and detergents held in wide-mouth syringes, which were also used to facilitate the application of the released high molecular weight DNA to sucrose gradients. Purified DNA was sedimented in neutral sucrose gradients at low speed to reduce speed artifacts. The sedimentation profiles were analysed using a computer program and the number of dsb was determined by simulation of random breaks in the mass distribution of the control sample and by comparison of this simulated profile with that of the irradiated one. The number of dsb formed was proportional to X-ray dose in the range of 5 to 2000 Gy. The induction per dose was found to be nmr-1 D-1 = (11.7 +/- 2) x 10(-12) Gy-1.

Non-random distribution of N-methyl-N-nitrosourea sensitive sites in a eukaryotic genome

DNA released from Ehrlich ascites cells by lysis in the presence of 50 microgram X ml-1 of proteinase K contains long alkali-stable strands in the order of 50-100 X 10(6) daltons. In contrast, DNA released in the presence of 6 mg X ml-1 of autodigested pronase is significantly nicked. According to sedimentation rates the number of internal ends liberated during this procedure is 24/200 X 10(6) daltons. The number of alkali-labile sites introduced into DNA by incubation of Ehrlich ascites cells with 1 nM of N-methyl-N-nitrosourea (MNU) followed by cell lysis in the presence of 50 microgram X ml-1 of proteinase K and alkali-denaturation is 16.6/200 X 10(6) daltons. From this one should expect that denatured DNA released from cells pretreated with 1 mM of MNU which are subsequently lysed with 6 mg X ml-1 of pronase would have about 40 single-strand breaks/200 X 10(6) daltons. However, denatured DNA strands released by 6 mg X ml-1 of pronase either from MNU-treated or untreated cells cannot be separated by centrifugation through alkaline sucrose gradients. This phenomenon could be explained by a non-random distribution of MNU-inducible alkali-labile sites of DNA in vivo.

Internucleotide protein linkers in Ehrlich ascites cell DNA

DNA from Ehrlich ascites tumor cells is nicked or gapped by a reaction which is induced by proteases such as autodigested pronase, proteinase K, trypsin, chymotrypsin and subtilisin. The cleavage of the protease-sensitive sites is inhibited by protease inhibitors. The nicks or gaps induced by proteases can be demonstrated by nuclease S1 sensitivity of native DNA and by a change of the sedimentation rate of alkali-denatured DNA. The limit size of denatured DNA released after optimal protease treatment is 8.5 x 10(6) daltons (27 kilo bases). The molecular weight of the native DNA pieces released after nuclease S1 degradation of DNA containing the protease-induced nicks or gaps is in the same order indicating that the protease-sensitive sites are alternatively arranged on the opposite DNA strands at an average distance of 13.5 kilo base pairs. Since the protease-induced nicks or gaps in phosphatase-treated DNA are not attacked by Escherichia coli polymerase I, one or both ends liberated by the protease treatment must be blocked by a material other than phosphate groups. The results are most compatible with peptide/protein linkers joining adjacent single-strand DNA subunits. Alternative explanations such as alkali-stable RNA linkers, protein-protected RNA linkers, site-specific nuclease contaminations in the protease preparations or cellular nucleases activated by the protease treatment are eliminated by the results presented in this paper.