Mechanism of mitochondrial DNA replication in mouse L-cells: RNA priming during the initiation of heavy-strand synthesis

The major form of mouse L-cell mitochondrial DNA contains a small displacement loop at the replication origin, created by synthesis of a 550 to 670-nucleotide portion of the heavy strand. These short heavy-strand segments remain hydrogen-bonded to the parental light strand and are collectively termed 7 S mitochondrial DNA. The unique location of these 7 S mitochondrial DNAs at the heavy-strand origin suggests that they may function as primers in the synthesis of full-length heavy strands. Ribonucleotides have been detected at the 5′-end of some of these molecules, which are most likely remnants of primer RNAs. Using 5′-end labeling in vitro, we have determined that these ribonucleotides occur at several discrete positions along the nucleotide sequence of the origin region, which suggests that there may be variability in the precise initiation point of RNA priming or in the location of the switchover from RNA priming to DNA synthesis. The length of 5′-end RNA was estimated by alkali treatment of mitochondrial DNA prior to end labeling. A range of one to ten ribonucleotides was hydrolyzed from the 5′-end of some 7 S mitochondrial DNA strands. This is the first evidence of RNA priming at a eukaryotic cell DNA replication origin.     

Mechanism of mitochondrial DNA replication in mouse L-cells: introduction of superhelical turns into newly replicated molecules

The first closed circular product of mouse L-cell mitochondrial DNA synthesis is a zero superhelix density molecule. Both of the asynchronously synthesized mitochondrial DNA daughter molecules pass through the zero superhelix density state. These molecules have a mean lifetime of approximately one hour before conversion to supercoiled molecules containing approximately 100 superhelical turns. A low frequency of intermediates in the conversion of these two closed circular forms is demonstrable by agarose gel electrophoresis. The degree of sensitivity to alkali has been used to demonstrate that newly replicated mitochondrial DNA has the same content of ribonucleotides as mass-labeled mitochondrial DNA.     

Mechanism of mitochondrial DNA replication in mouse L-cells: localization and sequence of the light-strand origin of replication

In the novel replication mechanism of closed circular mouse L-cell mitochondrial DNA synthesis one strand of the duplex (the heavy-strand) is initiated at a defined origin and proceeds unidirectionally. Synthesis of the complementary light-strand is initiated at a different origin, located approximately two-thirds genome length from the heavy-strand origin, and also proceeds unidirectionally. The initiation of light-strand synthesis does not occur until synthesis of the heavy-strand has extended past the light-strand origin region. One intriguing consequence of this asynchrony is that the heavy-strand origin functions in a DNA duplex, while the light-strand origin functions as a single-stranded template. In order to obtain the precise location of the light-strand origin we have isolated replicative molecules in which light-strand synthesis has begun and subjected them to digestion by a combination of the single-strand specific nuclease S₁ and various restriction cndonucleases. By comparison of the sizes of the duplex fragments thus generated with those produced by cleavage of non-replicating molecules cleaved with the same enzymes we have located the 5′-end of daughter light-strands at a position 55 to 90 nucleotides from a HpaI cleavage site 0.67 genome length from the heavy-strand origin. The nucleotide sequence of a 318-base region surrounding this site, determined by chemical sequencing techniques, possesses the symmetry required for the formation of three hairpin loops. The most striking of these has a stem consisting of 12 consecutive basepairs and a 13-base loop. In the heavy-strand template, this loop contains 11 consecutive thymidine nucleotides. This light-strand origin region has been found to possess a remarkable degree of homology with several other prokaryotic and eukaryotic origin-related sequences, particularly those of the øX174 A region and the simian virus 40 EcoRII G fragment.It has previously been shown that mouse mitochondrial DNA contains alkali-labile sites, which are presumably due to the presence of ribonucleotides incorporated into the DNA. A cluster of sites, representing eight adjacent ribonucleotides, has been located in mature light strands at or near the origin of light-strand synthesis. The retention of ribonucleotides at this specific location may reflect inefficient removal of an RNA primer at the light-strand origin.     

Biased incorporation of ribonucleotides on the mitochondrial L-strand accounts for apparent strand-asymmetric DNA replication

Recently, we presented evidence for conventional, strand-coupled replication of mammalian mitochondrial DNA. Partially single-stranded replication intermediates detected in the same DNA preparations were assumed to derive from the previously described, strand-asymmetric mode of mitochondrial DNA replication. Here, we show that bona fide replication intermediates from highly purified mitochondria are essentially duplex throughout their length, but contain widespread regions of RNA:DNA hybrid, as a result of the incorporation of ribonucleotides on the light strand which are subsequently converted to DNA. Ribonucleotide-rich regions can be degraded to generate partially single-stranded molecules by RNase H treatment in vitro or during DNA extraction from crude mitochondria. Mammalian mitochondrial DNA replication thus proceeds mainly, or exclusively, by a strand-coupled mechanism.     

Characteristics of the nascent and non-nascent small DNA molecules found in Escherichia coli

We have purified nascent DNA molecules from Escherichia coli pulse-labeled with 5-bromo[6-3H]deoxyuridine by repeated chromatography on nitrocellulose and isopycnic centrifugation in CsCl. The nascent molecules were labeled with 32P either at their 5' ends using polynucleotide kinase or at their 3' ends using terminal transferase. Compared to the non-nascent DNA of normal density, the nascent dense DNA contained a higher proportion of molecules terminated at their 5' ends with ribonucleotides. Exposure of the dense DNA to alkali generated 5' OH termini quantitatively equivalent to the number of molecules bearing 5' ribonucleotides. Experiments designed (1) to detect structures at the 5' ends of phosphatase-treated nascent DNA molecules that caused them to be resistant to hydrolysis by spleen exonuclease or (2) to detect polypeptides that were associated covalently with small DNA molecules and could be iodinated with the Bolton-Hunter reagent did not yield positive results. We conclude that many, if not all, of the intermediates in E. coli DNA replication are initiated with one or more ribonucleotides. The nascent molecules are outnumbered by small non-nascent DNA molecules in the cell, many of which appear to become slightly longer when cells are pulsed with thymidine. Many of the non-nascent DNA molecules behave as if they were self-complementary or crosslinked.     

Localization of the ribonucleotide sites in rat liver mitochondrial deoxyribonucleic acid.

Supercoiled rat liver mitochondrial DNA is relaxed by treatment with ribonucleases A, T1 or H. All the supercoiled mitochondrial DNA is sensitive to ribonuclease H and ribonuclease A, but only 35% of the supercoiled population is sensitive to ribonuclease T1. Removal of the ribonucleotides with calf thymus ribonuclease H, followed by denaturation of the mitochondrial DNA and analysis of the single-strand fragment lengths in the electron microscope, showed that the ribonucleotides were randomly located on both strands of the DNA. Endonuclease-S1 digestion of mitochondrial DNA after removal of the ribonucleotides reveals that no unique fragments are produced and ribonucleotides are randomly distributed with respect to one another. The average number of ribonucleotide sites per molecule was estimated to be between 8 and 13. Two possible mechanisms for the origin of ribonucleotide sites are discussed.     

Both strands of polyoma DNA are replicated discontinuously with ribonucleotide primers in vivo

Nascent polyoma DNA molecules were isolated after pulse-labeling of infected murine 3T6 cells with [3H]thymidine. The extent of digestion of these DNA molecules by spleen exonuclease was increased by exposure to alkali or RNase, suggesting that ribonucleotides were present at or near the 5' terminal of the newly synthesized pieces of DNA. Intermediates shorter than 300 nucleotides were hybridized to the separated strands of restriction enzyme fragments of the polyoma genome: 2.5 to 3-fold more radioactivity was found in the strand whose synthesis is necessarily discontinuous (the lagging strand) than in the strand whose synthesis is potentially continuous (the leading strand) than in the strand whose synthesis is potentially continuous (the leading strand). Separation of the strands of [5'-32P]DNA molecules showed that the excess [3H]thymidine in lagging-strand molecules was not simply the result of an increased number of molecules. Therefore, assuming equivalent efficiencies of labeling, lagging-strand pieces must be slightly longer than those with leading-strand polarity. The presence of ribonucleotides on the 5' termini of molecules with both leading- and lagging-strand polarity was demonstrated by (i) release of 32P-ribonucleoside diphosphates upon alkaline hydrolysis of [5'-32P]DNA separated according to replication polarity and (ii) the change in the degree of self-annealing of nascent molecules upon preferential degradation of DNA molecules possessing initiator RNA moieties by spleen exonuclease. We conclude that replication of polyoma DNA in vivo occurs discontinuously on both sides of the growing fork, using RNA as the major priming mechanism.     

Evidence for the presence of ribonucleotides at the 5' termini of some DNA molecules isolated from Escherichia coli polAex2.

We have purified a set of small DNA molecules from various strains of exponentially growing Escherichia coli, including E. coli polAex2. This material included very short molecules (2 S), the nascent DNA (“Okazaki fragments”) and some longer molecules. Most of the [³H]thymidine incorporated during a brief period of labeling was found in the 5 S to 15 S Okazaki fragments. There was a large number of the 2 S molecules in the cell. The properties of the 5′ ends of these molecules were investigated using three procedures. (1) The DNA preparation, pulse-labeled with [³H]thymidine, was reacted with polynucleotide kinase and ATP to insure that all 5′ ends were phosphorylated. After subjection of the DNA to alkaline hydrolysis, the proportion of incorporated ³H pulse-label that became susceptible to digestion by spleen exonuclease was determined. In different experiments there was an increment of up to 20% in the amount of pulse-labeled E. coli polAex2 DNA that could be hydrolyzed by the exonuclease after treatment with alkali. (2) As in the preceding protocol, phosphorylation of the 5′ ends was assured by reaction with kinase and ATP; the preparation was then treated with alkali and the number of 5′-OH ends generated that could be labeled with ³²P using [γ-³²P]ATP and kinase in a second reaction was determined. The data indicated that 3 to 30% of the molecules could be labeled after alkali digestion, but not before. (3) The DNA molecules were reacted with kinase and [γ-³²P]ATP after having been exposed previously to alkaline phosphatase. The end-labeled molecules were then subjected to an alkaline hydrolysis and the resulting hydrolysate chromatographed on a polyethyleneimine-cellulose thinlayer plate. Alkali treatment was found to release 2′(3′),5′-ribonucleoside diphosphates from 1 to 30% of the molecules; pAp and pGp predominated. Control experiments showed that these ribonucleotides were covalently linked to the 5′ ends of polydeoxyribonucleotides. Curiously, the smaller the DNA molecule the less likely it was to possess a 5′-terminal ribonucleotide. Very few apparent RNA/DNA molecules were observed in the non-polAex2 strains tested. These observations are in part in agreement with previous reports, and we infer that at least some of the nascent E. coli polAex2 DNA molecules are initiated in vivo with a ribonucleotide primer. The relatively smaller proportion of molecules with apparent 5′-terminal ribonucleotides among the smaller DNA molecules and in strains other than E. coli polAex2 suggests to us that there may exist a mechanism for initiating DNA molecules that does not require an RNA primer.     

Interaction of ribonuclease T1 with DNA,mononucleotides and oligonucleotides

The interaction of ribonuclease T₁ with DNA and nucleotides was investigated by fluorescence titration to establish whether or not this enzyme is a helix-destabilizing protein. Binding of the enzyme to DNA, ribonucleotides and oligodeoxyribonucleotides of chain length ten or more leads to enhancement of fluorescence emission of the enzyme as a function of increasing nucleotide/protein ratio. For deoxyribonucleotides of chain length less than ten, only quenching is observed. Energy transfer from the bases is postulated to be the source of the enhancement of fluorescence, while the decrease can be ascribed to changes in the distribution of charged groups in or near the binding site.     

Evidence for semi-conservative replication of mitochondrial DNA from Paramecium aurelia

The mode of replication of mitochondrial DNA in Paramecium aurelia was studied using 5-bromouracil incorporation. Density gradient analysis showed that 5-BrUra-substituted mitochondrial DNA had a density of 1.702 g/cm³, corresponding to 4% substitution in the duplex. Analysis of monomer length molecules revealed that these consisted of a mixture of normal density and 5-BrUra-substituted DNA, whereas dimer length molecules consisted of only 5-BrUra-substituted DNA. Analysis of denatured, 5-BrUra-substituted DNA indicated that the 5-BrUra was contained in just one strand, while the other strand had the density expected of normal mitochondrial DNA. It was concluded that the linear molecules from mitochondrial DNA of P. aurelia replicate via a semi-conservative mode of replication.     

Mechanism of mitochondrial DNA replication in mouse L cells: Localization of alkali-sensitive sites at the two origins of replication

Under alkaline conditions which completely degrade RNA but leave DNA intact, only a few percent of the mitochondrial DNA molecules of mouse L cells remain as intact closed circles. Approximately one-third of the closed circular molecules are nicked only once or twice, and the remainder are nicked at several sites, producing a heterogeneous distribution of fragment lengths. We have compared the products of alkali treatment of replicative intermediates with those of nonreplicating molecules, and no variation in the pattern of alkali-sensitive sites was detected. The two strands of the mitochondrial DNA duplex are both sensitive to high pH. Alkaline treatment of the two largest BamHI restriction endonuclease fragments produces specific degradation products consistent with the presence of alkali-sensitive sites at both the heavy- and light-strand replication origins. These sites may represent residues of ribonucleotide priming of the asynchronously replicated strands of mouse mitochondrial DNA.     

DNA sequencing by partial ribosubstitution

A new rapid method for DNA sequence analysis has been devised. In this method, base-specific cleavage is achieved at partially substituted ribonucleotides which are introduced by DNA polymerase extension in the presence of Mn2⁺. Access to a target sequence and label incorporation are achieved by extending a restriction fragment primer with DNA polymerase I. After a short initial incorporation with [α-³²P]deoxynucleotide triphosphates to label the 5′ region of the target sequence, the triphosphates are removed and the reaction mixture is divided four ways for a second primed extension. The second extension is a cold chase in the presence of Mn²⁺, all four deoxynucleotides and one of the four ribonucleotides under conditions that result in about 2% ribonucleotides substitution at each position. After cleavage at the restriction site and alkali cleavage at the positions of partial ribosubstitution, each reaction mixture is analysed by electrophoresis on a high-resolution denaturing acrylamide gel. As in the other rapid DNA sequencing methods the extent of DNA sequence that can be determined from a single experiment is limited only by the resolution of the analysing gels. At present some 100 nucleotides of sequence can be determined from a single priming reaction.     

Evidence for discontinuous replication of circular mitochondrial DNA molecules from Novikoff rat ascites hepatoma cells

Double-forked circular molecules of mitochondrial DNA (mtDNA) from rat tissues, indicated by their form and size to be replicative intermediates, are of two structurally distinct classes. Molecules of the first class are totally double stranded. Molecules of the second class are defined by one daughter segment being totally or partially single stranded. Length histograms of daughter segments measuring between 2% and 44% of the total 5-µm molecular contour were constructed from samples of both classes of replicating molecules derived from mtDNA or Novikoff rat ascites hepatoma cells. For single strand-containing molecules, the lengths fell into eight distinct, reproducible groups with mean values separated by 4.1–7.6% of the circular contour length. For totally double stranded molecules, the lengths fell into seven groups, corresponding to seven of the groups found for single strand-containing molecules. These results suggest that along at least 44% of the contour of mtDNA molecules there exist discrete points at which DNA synthesis tends to be arrested. This may indicate that there are pauses in normal mtDNA synthesis. However, as the DNA used in these experiments was isolated from mitochondrial fractions, the findings may indicate that continuation of synthesis beyond specific points on the nucleotide strands requires a factor which is not available after cell disruption.     

Heterogeneity of mitochondrial DNA from Saccharomyces carlsbergensis. Denaturation mapping by electron microscopy.

Electronmicroscopic observation of the denaturation pattern of 130 partially denaturated linear mitochondrial DNA molecules from Saccharomyces carlsbergensis was used to investigate the distribution of AT-rich sequences within the mitochondrial genome. The molecules were observed after heating to 43 degrees C in the presence of 12% formaldehyde. These conditions resulted in an average denaturation per molecule of 21%. The average length of the molecules was 10 mum, and a few molecules had a length corresponding to the size of the complete genome. The undenaturated regions varied in length from 0.1 to 5.0 mum with denaturated regions of length 0.02 to 0.1 mum in between. A denaturation map was constructed by use of one of the long molecules (28.7 mum) as a master molecule for positioning of all other molecules. This map shows distinct regions corresponding to the position of easily denaturated sequences in the mitochondrial DNA. These sequences which presumably correspond to the very AT-rich regions, known to exist in the yeast mitochondrial DNA, were found at intervals of about 0.5 - 3 mum on the map.