Replication process of the parvovirus H-1. VI. Characterization of a replication terminus of H-1 replicative-form DNA.

The linear duplex replicative form (RF) DNA of the parvovirus H-1 has been characterized with respect to cleavage by the bacterial restriction endonuclease of Escherichia coli, EcoRI. RF DNA has a single cleavage site 0.22 genome length from the left end of the molecule. The molecular weight of H-1 RF DNA determined by gel electrophoresis is 3.26 X 10(6). H-1 RF DNA has been found to dimerize by hydrogen-bounded linkage at the molecular left end, and in some molecules the viral strand is covalently linked to the complementary strand. Some 10% of monomeric RF DNA also has a covalent linkage between the viral and complementary strands at the left end. The EcoRI-B fragment, containing the left end of the RF molecule, appears to be a replication terminus by its labeling characteristics for both RF and progeny DNA synthesis. These findings suggest that the left end of H-1 RF DNA has some type of "turn-around" structure and that this end is not an origin for DNA synthesis.     

Replication process of the parvovirus H-1. VIII. Partial denaturation mapping and localization of the replication origin of H-1 replicative-form DNA with electron microscopy.

Partial denaturation mapping, restriction endonuclease digestion, and electron microscopy were used to determine which end of the linear duplex replicative-form (RF) DNA molecule contains the origin of RF replication for the parvovirus H-1. This origin was localized within approximately 300 base pairs of the arbitrarily designated right end of the RF DNA, in the EcoRI or HaeII-A fragment. Based on denaturation behavior in formamide, the right end was also found to have a relatively high guanine plus cytosine content, whereas the region adjacent to the left terminus of the RF DNA molecule was adenine plus thymine rich.     

Replication process of the parvovirus H-1. VII. Electron microscopy of replicative-form DNA synthesis.

The geometry of replicative form (RF) DNA synthesis of the H-1 parvovirus was studied with the electron microscope using formamide or aqueous variations of the Kleinschmidt spreading procedure. H-1 DNA was isolated from human or hamster cells infected with a temperature-sensitive mutant, ts1, which is deficient in progeny single-stranded DNA synthesis at the restrictive temperature (S.L. Rhode, 1976), thus minimizing possible confusion between RF and progeny DNA replicative intermediates (RIs). The purity of the isolated H-1 DNA, as determined by gel electrophoresis, ethidium bromide staining, autoadiography, and digestion with endo R-EcoRI, was high. H-1 RF DNA'S WERE LINEAR DOUBLE-STRANDED MOLECULES, 1.53 MUM IN LENGTH. H-1 RIs of RF DNA replication were double-stranded, Y-shaped molecules, with the same length as RF DNAs. The replication origin was localized no more than 0.15 genome lengths from one end of the RF DNA, with replication proceeding toward the other end at a uniform rate. Similar RF and RI molecules of dimer size were also observed. The length of H-1 single-stranded DNA extracted from purified virions was measured relative to that of phiX174 and it had a very similar contour length, so that the molecular weight of H-1 single-stranded DNA would be at least 1.48 X 10(6) to 1.59 X 10(6) (Berkowitz and Day, 1974).     

Sequence organization in nuclear deoxyribonucleic acid from Physarum polycephalum. Physical properties of foldback sequences.

An investigation was performed with the use of physical techniques, to determine the nature and organization of inverted repeat sequences in nuclear DNA fragments from Physarum polycephalum. From the average size of foldback duplexes (550 nucleotide pairs), and the foldback duplex yield as determined by treatment of DNA with S1 deoxyribonuclease followed by hydroxyapatite chromatography, it is estimated that there are at least 25000 foldback sequences in the Physarum genome. Foldback DNA molecules exhibit properties intermediate between single-stranded DNA and native duplexes on elution from hydroxyapatite with a salt gradient. In addition, thermal-elution chromatography of foldback DNA from hydroxyapatite crystals shows that foldback duplexes are less stable than native DNA. These properties can be explained on the basis that inverted repeat sequences are mismatched when in the foldback configuration. The results of experiments in which the binding of foldback DNA molecules to hydroxyapatite was determined, by using fragments of different single-chain size, agree with previous studies indicating that inverted repeat sequences are located, on average, every 7000 residues throughout the Physarum genome. The inverted repeats are derived from both the repetitive and single-copy components in Physarum nuclear DNA.     

Replication Process of the Parvovirus H-1 II. Isolation and Characterization of H-1 Replicative Form DNA

The Parvovirus H-1 replicates autonomously in hamster embryo cells. A DNA synthetic event, called HA-DNA synthesis, upon which subsequent viral RNA and viral hemagglutinin synthesis is dependent, is initiated in late S phase of the infected cell (18). It was postulated that HA-DNA represents parental viral replicative form DNA (RF DNA). This study describes the isolation and characterization of H-1 RF DNA as part of the continuing study of the mechanisms and control of DNA replication in the eukaryotic cell. The H-1 RF DNA is a linear duplex molecule containing the viral strand and its complement. The complementary strands of the RF DNA have been separated by equilibrium density gradient centrifugation. The RF DNA has a buoyant density of 1.705 in neutral CsCl and an estimated guanine plus cytosine (GC) content of 45.9%. It has a sedimentation coefficient of 17S. The calculated molecular weight of 3.7 x 10(6) is twice that of the single-stranded virion DNA. H-1 virions contain DNA that is homogeneous and free of complementary strands.     

Periodic organisation of foldback sequences in Physarum polycephalum nuclear DNA.

Nuclear DNA from the slime mould Physarum polycephalum is shown to contain interspersed inverted repeat sequences, such that denatured fragments of DNA containing pairs of these sequences form intra-chain duplexes under appropriate conditions. The organisation and distribution of the nucleotide sequences responsible for the formation of foldback structures in Physarum DNA have been investigated using the electron microscope. The majority of foldback duplexes have sizes ranging up to 800 base pairs, and about 60-80% of DNA molecules 2.2 X 10(4) bases in length contain interspersed foldback elements. The size of individual foldback duplexes, and also the length of the intervening sequences which separate them, are non-random. The results can best be explained by a model in which separate foldback foci in Physarum DNA are spaced periodically at regular intervals. The regions containing foldback foci are thought to contain smaller, tandemly-arranged sequences of discrete sizes, in some cases related to other nucleotide sequences of a similar nature in the same locality in Physarum DNA.     

Replication process of the parvovirus H-1. X. Isolation of a mutant defective in replicative-form DNA replication.

A temperature-sensitive mutant of H-1, ts14, that is partially defective in replicative-form (RF) DNA synthesis has been isolated. ts14 H-1 is characterized by a decrease in plaque-forming ability and production of infectious virus at the restrictive temperature of 39.5 degrees C. RF DNA synthesis of ts14 is reduced to 3 to 7% of that of wild-type H-1 at either the restrictive or the permissive temperature. A complementation analysis of RF synthesis of ts14 and a viable defective H-1 virus, DI-1, or wild-type H-3 indicates that the defective RF DNA synthesis of ts14 is cis-acting. ts14, unlike wild-type H-1, causes a multiplicity-dependent inhibition of DI-1 or H-3, but not LuIII, RF DNA synthesis. Mixed infections of cells with two parvoviruses also exhibited a cross-interference for viral protein synthesis that was multiplicity dependent, ts14 inhibited infectious virus production of H-1 or H-3, but not LuIII. LuIII-or H-3-pseudotype particles were produced by coinfection with H-1. H-3 and H-1 showed similar interactions with ts14, and H-3 DNA was more homologous to H-1 than was LuIII by comparative physical mapping studies. The results suggest that ts14 is a mutant with a defect in a regulatory sequence of its DNA that influence RF DNA replication.     

Inverted repeated sequences in yeast nuclear DNA.

The inverted repeated sequences (foldback DNA) of yeast nuclear DNA have been examined by electron microscopy and hydroxyapatite chromatography. Of the inverted repeat structures seen in the electron microscope, 34% were hairpins and 66% had a single stranded loop at the end of a duplex stem. The number average length of the repeat was 0.3 kb and the single stranded loop was 1.6 kb. It is estimated that there are approximately 250 inverted repeats per haploid genome. A statistical analysis of the frequency of molecules containing multiple inverted repeats showed that these sequences are non-randomly distributed. The distribution of inverted repeats was also examined by measuring the fraction of total DNA in the foldback fraction that bound to hydroxyapatite as a function of single strand fragment size. This analysis also indicated that the inverted repeats are clustered. Renaturation kinetic analysis of isolated foldback and inverted repeat stem sequence DNA showed that these sequences are enriched for repetitive DNA.     

Organisation of inverted repeat sequences in hamster cell nuclear DNA.

Hamster cell nuclear DNA is shown to contain inverted repeat (foldback) sequences, in some respects similar to the foldback fraction in DNA from other animal cell types. Using electron microscopy the majority of foldback duplexes are shown to be located in simple hairpin-like DNA structures, formed from individual pairs of complementary inverted repeated sequences 50--1000 nucleotides in length, in some cases arranged in tandem, and in other cases separated by intervening sequences, up to 16000 nucleotide residues long. In addition, a novel class of foldback structure, referred to as 'bubbled hairpins' is reported, which appear to be formed from clusters of inverted repeat sequences that are separated from adjacent clusters of complementary inverted repeats by large intervening sequences which vary in length from 5000 to over 20000 nucleotide residues. Due to the special pattern of distribution of these latter inverted repeat sequences, 'bubbled hairpins' are observed only in long foldback DNA. Evidence is presented that the distribution of foldback sequences in hamster cell DNA is highly ordered. The lengths of the intervening single chains in foldback structures appear to vary non-randomly. This gives rise to a localised periodic pattern of organisation that is believed to be a consequence of regular alternating arrangements of foldback and non-foldback sequences in the segments of DNA from which foldback structures are derived.     

DNA sequence repetition in the genome of the American oyster.

The genome of Crassostrea virignica, the American oyster, has been studied by reassociation kinetics in order to construct a profile of DNA sequence frequency components. Oyster DNA has been shown to contain at least 51% single copy DNA sequences and two classes of middle repetitive DNA. The major repetitive class contains sequences which are repeated on the average 20 times and comprise 29% of oyster DNA. The other class represents 10% of oyster DNA and contains sequences repeated approx. 3000 times. In addition the DNA of oyster contains at least 1% foldback sequences. The spectrum of DNA repetition components in the American oyster is similar to that found in the genomes of other mollusks.     

Parvovirus genome: nucleotide sequence of H-1 and mapping of its genes by hybrid-arrested translation.

The nucleotide sequence of the parvovirus H-1 has been determined by the chain-terminating method of Sanger. The sequence is 5,176 nucleotides long. Two large open reading frames (1 and 2) and two smaller open reading frames (3 and 4) of potential importance were identified in the plus-strand sequence. Promoter sequences are located at map positions 4 and 38 when map positions are expressed as percent of genome length from the 3' end of the virion minus strand. The locations for the genes for the parvovirus capsid proteins and a 76,000-dalton noncapsid protein (NCVP1) were mapped by hybrid-arrested translation. The gene for the capsid proteins VP1 and VP2' is located in the 5' half of the virus genome. The gene for NCVP1 is located in the 3' half of the viral DNA.     

Changes in the H-1 histone complement during myogenesis. II. Regulation by differential coupling of H-1 variant mRNA accumulation to DNA replication

We have shown that changes in proportions of the four chicken H-1's during in vitro myogenesis are primarily the result of differential coupling of their synthesis to DNA replication (see the previous paper). We show here that the four major chicken H-1's are encoded by distinct mRNAs which specify primary amino acid sequence variants. Accumulation of the H-1-variant mRNAs is coupled to DNA replication to different extents. The level of mRNA encoding H-1c (the H-1 variant that increases relative to the other H-1's in nondividing muscle cells) is completely uncoupled. In contrast, the level of mRNAs encoding H-1's a, b, and d (which have levels that decrease in nondividing muscle cells) are more tightly coupled. Polyadenylation is not involved in uncoupling H-1c mRNA accumulation from DNA replication.     

Changes in the H-1 histone complement during myogenesis. I. Establishment by differential coupling of H-1 species synthesis to DNA replication

Proportions of the four major chicken H-1 histones (referred to as H-1's a-d) change during in vitro skeletal myogenesis. As myoblasts fuse and differentiate into myotubes, the relative amount of H-1c increases dramatically. The change occurs primarily because synthesis of the H-1 species is coupled to DNA synthesis to different extents. H-1c synthesis is least tightly coupled to DNA replication in precursor myoblasts and in differentiated myotubes. Thus H-1c synthesis predominates after dividing myoblasts fuse into postmitotic myotubes. This results in the replacement of pre-existing H-1 and therefore increases the relative amount of H-1c. Differences in the stability of the H-1's are also involved in changing H-1 proportions. The results show that changes in H-1 proportions during myogenesis are a consequence of withdrawal from the cell cycle. The data provides a general mechanistic explanation of how tissue-specific H-1 proportions are established.     

Characterization of foldback sequences in hamster DNA using electron microsocpy.

Foldback sequences in nuclear DNA from cultured Hamster fibroblasts (BHK-21/C13 cells) have been characterized by electron microscopy. One half of the structures observed when denatured hamster DNA is allowed to anneal in the range O less than Cot1 less than 1 x 10(-4) M sec result from the annealing of inverted sequences forming foldback DNA. The remainder have a probable bimolecular origin. arising from rapidly-annealing sequences of satellite-like complexity. The average length of the inverted sequences in the foldback molecules is about 0.9 kilobases. There is estimated to be about 42,000 such sequences (21,000 pairs) in the hamster genome, approximately 45% of which form looped structures with a mean loop length of 1.74 kilobases. Contrary to previous reports, binding of the renatured duplex molecules to hydroxyapatite results in a poor recovery of structures containing identifiable foldback sequences, due to preferential enrichment of the bound fraction with duplexes formed by intermolecular annealing.     

Characterization of foldback sequences in Physarum polycephalum nuclear DNA using the electron microscope

An examination of the foldback fraction of nuclear DNA from Physarum polycephalum has been carried out using the electron microscope. Results show that the inverted repeat sequences responsible for the formation of foldback DNA range from 150-3000 bases in length, with a number-average size of 340 bases. About one-half of the inverted sequences form looped structures with loop sizes averaging 1200 bases in length. The distance between adjacent foldback sequences is estimated to be in the range 100-1500 bases.     

Purification of KBF1, a common factor binding to both H-2 and beta 2-microglobulin enhancers.

An enhancer binding factor, designated KBF1, has been purified from the nuclear extract of mouse BW5147 thymoma cells by five column chromatography steps including a sequence-specific DNA affinity column. Gel retardation and footprint analysis have shown that purified KBF1 has a binding activity specific for both H-2 and beta 2-microglobulin enhancer sequences. After SDS-polyacrylamide gel electrophoresis of the most purified preparation a 48-kd protein showed, after elution and renaturation, a binding activity to both enhancer sequences. These findings suggest that the expression of both H-2 and beta 2-microglobulin genes utilizes a common regulatory mechanism.     

Sequence organization of the rat genome by electron microscopy.

The size and arrangement of repetitive and inverted repeat (foldback) sequences in rat DNA were studied by visualization of hybrid and heteroduplex structures in the electron microscope. The self-reassociation of repetitive sequence-bearing DNA strands often results in the formation of four-ended "H" structures, whose duplex regions equal the repetitive sequence length and can be measured in the electron microscope. In this way, it was determined that the average size of the class of numerous short repetitive sequences is 0.40 +/- 0.15 kbp. Heteroduplex structures were prepared between long whole DNA single strands and short repeat-sequence-bearing strands. The analysis of these structures confirms that the size of the repetitive sequences in 0.4 kbp on average. Length measurements between adjacent duplexes show that the average spacing between two interspersed repeats is at least 1.5-1.8 kbp. By examining 29.4-kbp single strands after brief renaturation, the size and distribution of foldback sequences were determined. There are 1.9 X 10(5) foldback apirs per rat genome, spaced an average of 9.7 kbp apart according to our measurement. Repetitive, inverted repeat and unique sequences are interspersed with each other in at least half the genome.     

Distribution of inverted repeat sequences in nuclear DNA from Physarum polycephalum.

Inverted repeat sequences, capable of forming stable intra-chain foldback duplexes, are shown using electron microscopy to be located in over 90% of fragments of nuclear DNA from Physarum polycephalum. A statistical treatment of the data indicates that, on average, foldback sequence foci are spaced every 7,000 nucleotides and that they are distributed uniformly amongst the DNA chains. The majority of inverted repeat sequences give rise to the simple types of foldback structure observed in DNA from other eukaryotic species, but a significant proportion of the DNA fragments also contain novel foldback structures with a more complex appearance, referred to as 'bubbled' hairpins. The latter structures appear to be formed by the annealing of several distinct segments of homologous inverted repeat sequence, each separated by interspersed non-foldback sequences of variable sizes up to 15,000 nucleotides in length. The size, both of the foldback duplexes and of the intervening single-chain segments of DNA, are not random. Instead, they appear to form a regular, arithmetic series of lengths. These observations suggest that the different segments of Physarum DNA from which foldback structures are derived contain nucleotide sequences that share a highly ordered and unform pattern of structural organisation. These regular units of organisation in Physarum DNA in some cases extend over distances up to 50,000 nucleotides in length.     

Sequence organisation in nuclear DNA from Physarum polycephalum. Arrangement of highly-repeated sequences

Recombinant plasmids containing highly repetitive Physarum DNA segments were identified by colony hybridisation using a radioactively-labelled total Physarum DNA probe. A large number of these clones also hybridised to a foldback DNA probe purified from Physarum nuclear DNA. The foldback DNA probe was characterised by reassociation kinetic analysis. About one-half of this component was shown to consist of highly repeated sequences with a kinetic complexity of 1100 bp and an average repetition frequency of 5200. Direct screening of 67 recombinant plasmids for foldback sequences using the electron microscope revealed that about one-half were located in segments of DNA containing highly repetitive sequences; the remainder were present in clones containing low-copy number repeated elements. Analysis of two DNA clones showed that they contained repetitive elements located in over half of all DNA segments containing highly repetitive DNA and that the foci containing these highly repetitive sequences had different sequence arrangements. The results are consistent with the hypothesis that the most highly repeated DNA sequence families in the Physarum genome are few in number and are clustered together in different arrangements in about one-sixth of the genome. Over one-half of the foldback DNA complement in the Physarum genome is derived from these segments of DNA.