A stretch of "late" SV40 viral DNA about 400 bp long which includes the origin of replication is specifically exposed in SV40 minichromosomes.

Examination of DNA fragments produced from either formaldehyde-fixed or unfixed SV40 minichromosomes by multiple-cut restriction endonucleases has led to the following major results: Exhaustive digestion of unfixed minichromosomes with Hae III generated all ten major limit-digest DNA fragments as well as partial cleavage products. In striking contrast to this result, Hae III acted on formaldehyde-fixed minichromosomes to yield only one of the limit-digest fragments, F, which is located in the immediate vicinity of the origin of replication, spanning nucleotides 5169 and 250 on the DNA sequence map of Reddy et al. (1978). This 300 base pair (bp) fragment was released as naked DNA from formaldehyde-fixed, Hae III-digested minichromosomes following treatment either by pronase-SDS or by SDS alone. In the latter case, the remainder of the minichromosome retained its compact configuration as assayed by both sedimentational and electrophoretic methods. In minichromosomes, the F fragment is therefore not only accessible to Hae III at its ends, but is also neither formaldehyde cross-linked into any SDS-resistant nucleoprotein structure nor topologically "locked" within the compact minichromosomal particle. This same fragment was preferentially produced during the early stages of digestion of unfixed minichromosomes with Hae III, and its final yield in the exhaustive Hae III digest was significantly higher than that of other limit-digest fragments. Similar results were obtained upon digestion of either unfixed or formaldehyde-fixed minichromosomes with Alu I. In particular, of approximately twenty major limit-digest DNA fragments, only two fragments (F and P, encompassing nucleotides 5146 to 190, and 190 to 325, respectively) were produced by Alu I from the formaldehyde-fixed minichromosomes. All other restriction endonucleases tested (Mbo I, Mbo II, Hind III, Hin II+III and Hinf I), for which there are no closely spaced recognition sequences in the above mentioned regions of the SV40 genome, did not produce any significant amount of limit-digest DNA fragments from formaldehyde-fixed minichromosomes. These findings, taken together with our earlier data on the preferential exposure of the origin of replication in SV40 minichromosomes (Varshavsky, Sundin and Bohn, 1978), strongly suggest that a specific region of the "late" SV40 DNA approximately 400 bp long is uniquely exposed in the compact minichromosome. It is of interest that, in addition to the origin of replication, this region contains binding sites for T antigen (Tjian, 1977), specific tandem repeated sequences and apparently also the promoters for synthesis of late SV40 mRNAs (Fiers et al., 1978; Reddy et al., 1978).

SV40 viral minichromosome: preferential exposure of the origin of replication as probed by restriction endonucleases.

Isolated SV40 minichromosomes [1-3] were treated with different single-cut restriction endonucleases to probe the arrangement of nucleosomes in relation to the SV70 DNA sequence. While Eco RI and Bam HI each cut 22-27% of the SV40 minichromosomes under limit-digest conditions, Bgl I, which cuts SV40 DNA at or very near the origin of replication [4,5], cleaves 90-95% of the minichromosomes in a preparation. Similar results were obtained with minichromosomes which had been fixed with formaldehyde before endonuclease treatment. One possible interpretation of these findings is that the arrangement of nucleosomes in the compact SV40 minichromosomes is nonrandom at least with regard to sequences near the origin of DNA replication.

Compact form of SV40 viral minichromosome is resistant to nuclease: possible implications for chromatin structure.

We report two new findings bearing on the "supranucleo-somal" level of the structure of the Simian Virus 40 minichromosome. I) Isolated SV40 minichromosome which contains all five histones including HI/I/ exists in solution under approximately physiological ionic conditions as a compact roughly spherical particle approximately 300 A in diameter which is capable of fitting within the virus capsid. In spite of such a compact conformation of the minichromosome individual nucleosomes can be readily visualized within the particle. Compact state of SV40 minichromosome depends on both the presence of histone HI and maintenance of approximately physiological ionic strength of solution (micron approximately 0.15). Removal of HI results in a conversion of the compact minichromosomes into an extended (circular beaded) structure. 2) The compact form of the SV40 minichromosome in contract to its circular beaded form is virtually completely resistant to staphylococcal nuclease, strongly suggesting that in particular nuclease-sensitive parts of the internucleosomal DNA regions are not exposed on the outside of the compact SV40 minichromosome. On the other hand, DNase I which is known to attack both inter-and intranucleosomal DNA in the chronatin /2,3/ readily digests the compact form of the SV40 minichromosome. Possible models of the compact minichromosome and implications for higher order structures of the cellular chromatin are discussed.

Histone-like proteins in the purified Escherichia coli deoxyribonucleoprotein.

Analysis of E.coli chromosomes isolated under conditions similar to those used for isolation of eukaryotic chromatin has shown that: 1) The proteins of highly purified E.coli deoxyribonucleoprotein are mainly in addition to RNA polymerase two specific histone-like proteins of apparent molecular weight of 17,000 and 9,000 (proteins 1 and 2, respectively). 2) Proteins 1 and 2 occur in approximately equal molar amounts in the isolated E.coli chromosome, and their relative content corresponds to one molecule of protein 1 plus one molecule of protein 2 per 150-200 base pairs of DNA. 3) There are no long stretches of naked DNA in the purified E.coli deoxyribonucleoprotein suggesting a fairly uniform distribution of the proteins 1 and 2 along DNA. 4) The protein 2 is apparently identical to the DNA-binding protein HU which was isolated previously /1/ from extracts of E.coli cells. 5) Digestion of the isolated E.coli chromosomes with staphylococcal nuclease proceeds through discrete deoxyribonucleoprotein intermediates (in particular, at approximately 120 base pairs) which contain both proteins 1 and 2. However, since no repeating multimer structure was observed so far in nuclease digests of the E.coli chromosome, it seems premature to draw definite conclusions about possible similarities between the nucleosomal organization of the eukaryotic chromatin and the E.coli chromatin structure.Images

Free DNA stretches in histone H1-depleted chromatin and their possible relation to chromomere structure.

Oligomers of chromatin subunits (oligonucleosomes) were prepared by a mild digestion of chromatin with staphylococcal nuclease followed by a purification of a high molecular weight material (hexanucleosomes and larger DNP particles) by gel chromatography. The main finding is that a mild removal of histone H1 from the oligonucleosome preparation by treatment with tRNA in the absence of any significant hydrodynamic shearing leads to the formation of free DNA molecules which constitute 5-6% of the total oligonucleosomal DNA. The size of nucleosome-free DNA stretches in H1-depleted hydrodynamically sheared chromatin is about 6000 base pairs and their content is apparently 10-12% of the total DNA. These and related findings are discussed in terms of the previously proposed "asymmetric hairpin" model of DNA packing in chromatin [1-4]. Different kinds of the asymmetric hairpin are considered and ambiguities in interpretations of experimental data are pointed out.

Minichromosome of simian virus 40: presence of histone HI.

In contrast to conclusions of previous studies /I-3/ claiming the absence of histone HI from the SV40 and polyoma viral minichromosomes we have found that a preparation of purified SV40 minichromosomes does contain histone HI. The content of HI in relation to other four histones in the SV40 minichromosomes is close to that in the cellular chromatin. Histone HI in the isolated SV40 minichromosomes is bound apparently to internucleosomal DNA stretches as was shown already for HI in the cellular chromatin /4/. In addition it was found that more than 90% of the purified SV40 minichromosomes migrated as a single discrete deoxyribonucleoprotein band upon agarose gel electrophoresis.

Studies on chromatin. Free DNA in sheared chromatin.

Chromatin which has been hydrodynamically sheared in a low-ionic-strength buffer lacking divalent cations (I = 0.0005 M) contains a heterogeneous set of deoxyribonucleoprotein particles but no molecules of free DNA. The main finding is that a transference of sheared chromatin to 1--2 mM MgCl2 or to 0.1--0.2 M NaCl results in appearance of completely free DNA molecules. A salt-induced rearrangement of DNA-bound histones but not a partial loss of them is responsible for the observed phenomenon. Formation of free DNA molecules is accompanied by aggregation of the majority of remaining deoxyribonucleoprotein particles. The percentage of free DNA molecules in the chromatin which was sheared to an average DNA length of about 400 base pairs is increased from zero in the initial sample to 8-9% in 1 mM MgCl2 and further to approximately 25% of the total DNA in 0.15 M NaCl, 2 mM MgCl2. Free DNA molecules in the sheared chromatin are observed not only upon isopycnic banding of formaldehyde-fixed deoxyribonucleoproteins in CsCl gradients but also in non-ionic metrizamide gradients with either fixed or unfixed deoxyribonucleoprotein samples. The process of free DNA formation is a reversible one; its direction and the equilibrium state depend in particular on the ionic conditions of the medium.

Heterogeneity of chromatin subunits in vitro and location of histone H1.

Chromatin subunits ("nucleosomes") which were purified by sucrose gradient centrifugation of a staphylococcal nuclease digest of chromatin have been studied. We found that such a preparation contains nucleosomes of two discrete types which can be separated from each other by polyacrylamide gel electrophoresis. Nucleosome of the first type contains all five histones and a DNA segment of approximately 200 base pairs long, whereas nucleosome of the second type lacks histone H1 and its DNA segment is approximately 170 base pairs long, i.e., about 30 base pairs shorter than the DNA segment of the nucleosome of the first type. Purified dimer of the nucleosome also can be fractionated by gel electrophoresis into three discrete bands which correspond to dinucleosomes containing two molecules of histone H1, one and no H1. These and related findings strongly suggest that the H1 molecule is bound to a short (approximately 30 base pairs) terminal stretch of the nucleosomal DNA segment which can be removed by nuclease (possibly in the form of H1-DNA complex) without any significant disturbance of main structural features of the nucleosome.

Studies on chromatin. III. v-Bodies and free DNA in chromatin lacking histone H1.

Chromatin lacking histone H1 was found by electron microscopy to contain 'beaded' deoxyribonucleoprotein fibers. Adjacent beads are connected with each other by threads having a DNA-like appearance. At least some of threads are shown to be free DNA stretches. Average length and the content of free DNA stretches in histone H1-depleted chromatin depends on the ionic conditions of the medium. The appearance of individual beads is similar to that of chromatin subunits or v-bodies [1] in the original chromatin. Thus, in agreement with the X-ray data [2], histone H1 apparently is not required for maintenance of a compact state of DNA in chromatin subunits.

Studies on chromatin. IV. Evidence for a toroidal shape of chromatin subunits.

Electron microscopy of purified chromatin subunits (v-bodies [17] or nucleosomes [2] revealed a hole or at least a deep indentation in the globular nucleosome. A hole in the nucleosome was visualized using rotatory shadowing with platinum-palladium or more directly, by negative staining with sodium phosphotungstate. The diameter of the hole as measured from negatively stained samples is 10-25 A. The external diameter of the negatively stained nucleosome equals 75 +/- 15 A. Although most of the data are formally compatible with either a hole or a deep indentation in the nucleosome, some views of the particles in the negatively stained samples suggest a hole rather than an indentation. The possible significance of a toroidal structure of the chromatin subunit is discussed in the accompanying paper [3].

Studies on chromatin. V. A model for the structure of chromatin subunit.

A new model for the fine structure of the chromatin subunit (or 'nucleosome') is proposed. The model is based on previous experimental findings [1-14] and on two new suggestions, namely: (1) Eight histones form a toroidal-shaped histone coe of nucleosome and are arranged in the following ciruclar sequence: (see article). (2) DNA is 'kinked' around a toroidal-shaped histone core in a 'solenoid-like' mode, each kink occurring every 10 base pairs along DNA. The electron microscopic evidence for a toroidal shape of the nucleosome is described in the preceding paper [13]. The possibility of the existence of kinks in the DNA double helix was considered recently by Crick and Klug [14]. The proposed model of the nucleosome, being more detailed than earlier models permits us to explain in direct structural terms the yet unordered set of data bearing on the pattern of histone-histone interactions in chromatin, the results of a mild deoxyribonuclease digestion of DNA within the nucleosomal particle and also the quantitative data on the unwinding of the DNA duplex upon formation of the nucleosome.

Arrangement of histones along DNA in chromosomal deoxyribonucleoprotein lacking histone F1.

In deoxyribonucleoprotein from which histone F1 and most nonhistone proteins were removed by treatment with tRNA in the presence of Mg(2+), one can find very long stretches of completely free DNA (average length of about 4×10(3) base pairs). They alternate with stretches of DNA (∼16×10(3) base pairs) which are nearly uniformly covered with the other four histones.

Redistribution of histones during unfolding of chromosomal DNA.

Just in the course of unfolding of chromosomal deoxyribonucleoproteins performed in the absence of magnesium ions all DNA-bound histones may be redistributed. This type of redistribution is completely blocked in already 'unfolded' DNP preparations. If the unfolding-induced histone redistribution is allowed it leads to a significant decrease of the average length of free DNA segments in the unfolded, histone F1-depleted DNP. The implications of these data on the mode of DNA packing in chromatin are discussed.