DNA replication in Escherichia coli: evidence for two classes of small deoxyribonucleotide chains

Degron-Controlled Protein Degradation in Escherichia coli: New Approaches and Parameters

Protein degron tags have proven to be uniquely useful for the characterization of gene function. Degrons can mediate quick depletion, usually within minutes, of a protein of interest, allowing researchers to characterize cellular responses to the loss of function. To develop a general-purpose degron tool in Escherichia coli, we sought to build upon a previously characterized system of SspB-dependent inducible protein degradation. For this, we created a family of expression vectors containing a destabilized allele of SspB, capable of a rapid and nearly perfect "off-to-on" induction response. Using this system, we demonstrated excellent control over several DNA metabolism enzymes. However, other substrates did not respond to degron tagging in such an ideal manner, indicating the apparent limitations of SspB-dependent systems. Several degron-tagged proteins were degraded too slowly to be completely depleted during active growth, whereas others appeared to be completely refractory to degron-promoted degradation. Thus, only a minority of our, admittedly biased, selection of degron substrates proved to be amenable to efficient SspB-catalyzed degradation. We also uncovered an apparent stalling and/or disengagement of ClpXP from a degron-tagged allele of beta-galactosidase (beta-gal). While a degron-containing fusion peptide attached to the carboxy-terminus of beta-gal was degraded quantitatively, no reductions in beta-gal activity or concentration were detected, demonstrating an apparently novel mechanism of protease resistance. We conclude that substrate-dependent effects of the SspB system present a continued challenge to the widespread adoption of this degron system. For substrates that prove to be degradable, we provide a series of titratable SspB-expression vehicles.

Degron-controlled protein degradation in Escherichia coli: New Approaches and Parameters

Protein degron tags have proven uniquely useful for characterization of gene function. Degrons mediate quick depletion, usually within minutes, of a protein of interest - allowing researchers to characterize cellular responses to the loss of function. To develop a general purpose degron tool in E. coli, we sought to build upon a previously characterized system of SspB-dependent inducible protein degradation. For this, we created a family of expression vectors containing a destabilized allele of SspB, capable of a rapid and nearly perfect "off-to-on" induction response. Using this system, we demonstrated control over several enzymes of DNA metabolism, but also found with other substates apparent limitations of a SspB-dependent system. Several degron target proteins were degraded too slowly to affect their complete depletion during active growth, whereas others appeared completely refractory to degron-promoted degradation. We demonstrated that a model substrate, beta-galactosidase, was positively recognized as a degron substrate, but failed to be degraded by the ClpXP protease - demonstrating an apparently unknown mechanism of protease resistance. Thus, only a minority of our, admittedly biased, selection of degron substates proved amenable to rapid SspB-catalyzed degradation. We conclude that substrate-dependence of the SspB system remains a critical factor for the success of this degron system. For substrates that prove degradable, we provide a series of titratable SspB-expression vehicles.

Ultraviolet-induced RNA:DNA hybrids interfere with chromosomal DNA synthesis

Ultraviolet (UV) induces pyrimidine dimers (PDs) in DNA and replication-dependent fragmentation in chromosomes. The rnhAB mutants in Escherichia coli, accumulating R-loops and single DNA-rNs, are generally resistant to DNA damage, but are surprisingly UV-sensitive, even though they remove PDs normally, suggesting irreparable chromosome lesions. We show here that the RNase H defect does not cause additional chromosome fragmentation after UV, but inhibits DNA synthesis after replication restart. Genetic analysis implies formation of R-loop-anchored transcription elongation complexes (R-loop-aTECs) in UV-irradiated rnhAB mutants, predicting that their chromosomal DNA will accumulate: (i) RNA:DNA hybrids; (ii) a few slow-to-remove PDs. We confirm both features and also find that both, surprisingly, depend on replication restart. Finally, enriching for the UV-induced RNA:DNA hybrids in the rnhAB uvrA mutants also co-enriches for PDs, showing their co-residence in the same structures. We propose that PD-triggered R-loop-aTECs block head-on replication in RNase H-deficient mutants.

Near-continuously synthesized leading strands in Escherichia coli are broken by ribonucleotide excision

In vitro, purified replisomes drive model replication forks to synthesize continuous leading strands, even without ligase, supporting the semidiscontinuous model of DNA replication. However, nascent replication intermediates isolated from ligase-deficient Escherichia coli comprise only short (on average 1.2-kb) Okazaki fragments. It was long suspected that cells replicate their chromosomal DNA by the semidiscontinuous mode observed in vitro but that, in vivo, the nascent leading strand was artifactually fragmented postsynthesis by excision repair. Here, using high-resolution separation of pulse-labeled replication intermediates coupled with strand-specific hybridization, we show that excision-proficient E. coli generates leading-strand intermediates >10-fold longer than lagging-strand Okazaki fragments. Inactivation of DNA-repair activities, including ribonucleotide excision, further increased nascent leading-strand size to ∼80 kb, while lagging-strand Okazaki fragments remained unaffected. We conclude that in vivo, repriming occurs ∼70× less frequently on the leading versus lagging strands, and that DNA replication in E. coli is effectively semidiscontinuous.

Polyphosphate accumulation in Escherichia coli in response to defects in DNA metabolism

Phenol-chloroform extraction of [(32)P]orthophosphate-labeled Escherichia coli cells followed by alkaline gel electrophoresis revealed, besides the expected chromosomal DNA, two non-DNA species that we have identified as lipopolysaccharides and polyphosphates by using a combination of biochemical and genetic techniques. We used this serendipitously found straightforward protocol for direct polyphosphate detection to quantify polyphosphate levels in E. coli mutants with diverse defects in the DNA metabolism. We detected increased polyphosphate accumulation in the ligA, ligA recBCD, dut ung, and thyA mutants. Polyphosphate accumulation may thus be an indicator of general DNA stress.

The replication intermediates in Escherichia coli are not the product of DNA processing or uracil excision

The current model of DNA replication in Escherichia coli postulates continuous synthesis of the leading strand, based on in vitro experiments with purified enzymes. In contrast, in vivo experiments in E. coli and its bacteriophages, in which maturation of replication intermediates was blocked, report discontinuous DNA synthesis of both the lagging and the leading strands. To address this discrepancy, we analyzed nascent DNA species from ThyA+ E. coli cells replicating their DNA in ligase-deficient conditions to block maturation of replication intermediates. We report here that the bulk of the newly synthesized DNA isolated from ligase-deficient cells have a length between 0.3 and 3 kb, with a minor fraction being longer that 11 kb but shorter than the chromosome. The low molecular weight of the replication intermediates is unchanged by blocking linear DNA processing with a recBCD mutation or by blocking uracil excision with an ung mutation. These results are consistent with the previously proposed discontinuous replication of the leading strand in E. coli.

Kinetics of thymidine incorporation into detergent-soluble DNA of mouse lymphocytes

We reported recently that splenocytes from concanavalin A-stimulated mice rapidly incorporated [3H]thymidine into non-mitochondrial DNA that was detergent soluble and distributed in size classes between 200 and 5000 base pairs. In this report we show that small [3H]thymidine-labeled oligonucleotides (less than 100 base pairs long) appear by 15 min. Subsequently, [3H]thymidine in small oligonucleotides diminishes as incorporation into larger size classes of detergent-soluble DNA occurs in a pattern that is stable for at least 3 hr. Although incorporation of [3H]thymidine into the oligonucleotides is not sensitive to aphidicolin or hydroxyurea, the appearance of [3H]thymidine in larger species is blocked by both drugs. These results indicate that the enzymatic process involved in synthesis of oligonucleotides is somehow distinct from the process involved in synthesis of larger detergent-soluble size classes. Synthesis of the latter may be replication related.

Metabolism and non-random occurrence of nonnascent short chains in the DNA of Ehrlich ascites cells

The DNA of Ehrlich ascites cells was labeled with radioactive thymidine using different labeling schedules: Incubation periods between 15 s and 4 h; pulse/pulse-chase experiments with pulses in the range of a few minutes; longtime incubation followed by a longtime chase (both in the range of 1 cell generation). From the purified DNA of the labeled cells a fraction (0.3-0.4%) of short chains was separated and partially fractionated by means of a hydroxyapatite thermochromatography procedure. The evaluation of the labelling patterns of the short chains indicated that less than 5% of them can be regarded as replication intermediates ('Okazaki pieces'). The rest, termed nonnascent pieces, exhibited a slow turnover. The life span of the nonnascent pieces was estimated to be about 1 cell generation. On helical DNA, nonnascent pieces were distributed in a non-random manner. Their preferential localisation was nearby sites which caused binding of the DNA, after purification, to nitrocellulose and which occurred about every 60-80 microns on the nuclear DNA of the cells.

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.

Origin and characterization of short DNA chains in Escherichia coli

One of the major problems in the study of DNA replications involves the presence of numerous short, non-nascent DNA chains in the cell. Such chains often contaminate nascent DNA preparations, making accurate analysis of the replicative DNA difficult. This complication can be avoided by the use of hydroxyapatite chromatography. Previous results from this laboratory had shown that short nascent DNA chains could be eluted from hydroxyapatite at low phosphate concentrations because of their non-covalent association with protein. Additional data now indicate that this isolation procedure yields a DNA preparation which contains only nascent DNA and is essentially free of non-nascent chains. 5'-Terminal labelling patterns and molecular weight distributions show that only nascent DNA chains from the DNA-protein complex and can therefore be separated from non-nascent chains if the isolation is performed under non-denaturing conditions. The protein involved in the complex appears to be rather specific for DNA chains in the replication fork since short chains resulting from the excision of dUMP immediately after replication also form the DNA-protein complex. Using this isolation technique, the 5'-terminal nucleotides of nascent DNA chains were determined in an effort to learn something about the chain initiation process. DNA was pulse-labeled in several ways, purified by hydroxyapatite chromatography, and labeled at the 5' end with [32P]phosphate. Two-dimensional thin-layer chromatography of the 32P-labeled nucleotides, obtained after enzymatic hydrolysis, revealed that all four deoxyribonucleotides are present at the 5' end in approximately equal amounts. In most cases, this 5'-terminal nucleotide distribution does not vary significantly, even when the conditions of pulse-labeling are changed. Only if the cells are allowed to run out of thymine is a variation in the relative amounts of 5'-end nucleotides detected. In this case, the amount of dTMP at the 5' end decreases significantly, reflecting the low thymine levels and indicating that the cell can compensate for this deficiency by utilizing other available nucleotides. From these results, it appears that DNA chain initiation is essentially random with respect to the nucleotide used in the initiation process.

Characterization of arithmetic deoxyribonucleic acid synthesis at restrictive temperature in a dnaE mutant of Escherichia coli K-12

The dna-293 mutation is shown to be a dnaE allele. The linear deoxyribonucleic acid synthesis previously observed in this mutant has been further characterized. The production of small deoxyribonucleic acid intermediates and their subsequent joining were identical in the mutant and its dnaE+ parent at 42.5 degrees C. Though the mutant cells continued to divide at the nonpermissive temperature, the rate of division was reduced. The data are consistent with a lack of production of replicationally active deoxyribonucleic acid polymerase III at the restrictive temperature.

Most short DNA molecules isolated from 3T3 cells are not nascent

The population of short DNA molecules (less than 10(3) nucleotides) in 3T3 cells has been studied using in vivo and in vitro pulse labeling techniques and in vitro end-labeling. There is a large number of molecules of less than 100 nucleotides present in equal numbers in both Go and S phase cells. In S phase cells, most of these molecules are not replicating intermediates because they do not become density-labeled after a moderate period of substitution of BrdUMP, although they are detected by end-labeling in vitro. This population includes the nascent Okazaki pieces that can be labeled in a short pulse with [3H]dThd or [3H]dTTP, however, these represent less than 10% of the total population. Alkaline hydrolysis of the molecules that had been end-labeled with 32P using [gamma32P]ATP and polynucleotide kinase did not reveal significant release of [32P] 2'(3'), 5' ribonucleoside diphosphates.

Electron microscopic studies of bacteriophage M13 DNA replication

Intracellular forms of M13 phage DNA isolated after infection of Escherichia coli with wild-type phage have been studied by electron microscopy and ultracentrifugation. The data indicate the involvement of rolling-circle intermediates in single-stranded DNA synthesis. In addition to single-stranded circular DNA, we observed covalently closed and nicked replicative-form (RF) DNAs, dimer RF DNAs, concatenated RF DNAs, RF DNAs with single-stranded tails (theta, rolling circles), and, occasionally, RF DNAs with theta structures. The tails in theta molecules are always single stranded and are never longer than the DNA from mature phage; the proportion of theta to other RF molecules does not change significantly with time after infection. The origin of single-stranded DNA synthesis has been mapped by electron microscopy at a unique location on RF DNA by use of partial denaturation mapping and restriction endonuclease digestion. This location is between gene IV and gene II, and synthesis proceeds in a counterclockwise direction on the conventional genetic map.

Physiological effects of growth of an Escherichia coli temperature-sensitive dnaZ mutant at nonpermissive temperatures

The physiological effects of incubation at nonpermissive temperatures of Escherichia coli mutants that carry a temperature-sensitive dnaZ allele [dnaZ(Ts)2016] were examined. The temperature at which the dnaZ(Ts) protein becomes inactivated in vivo was investigated by measurements of deoxyribonucleic acid (DNA) synthesis at temperatures intermediate between permissive and nonpermissive. DNA synthesis inhibition was reversible by reducing the temperature of cultures from 42 to 30 degrees C; DNA synthesis resumed immediately after temperature reduction and occurred even in the presence of chloramphenicol. Inasmuch as DNA synthesis could be resumed in the absence of protein synthesis, we concluded that the protein product of the dnaZ allele (Ts)2016 is renaturable. Cell division, also inhibited by 42 degrees C incubation, resumed after temperature reduction, but the length of time required for resumption depended on the duration of the period at 42 degrees C. Replicative synthesis of cellular DNA, examined in vitro in toluene-permeabilized cells, was temperature sensitive. Excision repair of ultraviolet light-induced DNA lesions was partially inhibited in dnaZ(Ts) cells at 42 degrees C. The dnaZ(+) product participated in the synthesis of both Okazaki piece (8-12S) and high-molecular-weight DNA. During incubation of dnaZ(Ts)(lambda) lysogens at 42 degrees C, prophage induction occurred, and progeny phage were produced during subsequent incubation at 30 degrees C. The temperature sensitivity of both DNA synthesis and cell division in the dnaZ(Ts)2016 mutant was suppressed by high concentrations of sucrose, lactose, or NaCl. Incubation at 42 degrees C was neither mutagenic nor antimutagenic for the dnaZ(Ts) mutant.

Growth response of Escherichia coli to nutritional shift-up: immediate division stimulation in slow-growing cells

When Escherichia coli 15T- cells growing exponentially at 70- to 80-min doubling times are subjected to a nutritional shift-up via glucose addition, cell division continues at the preshift rate for about 70 min (rate maintenance). The same cells growing at doubling times of 120 min or longer, however, begin to divide at a new faster rate immediately upon glucose addition. In both the rate maintenance and immediate division situations, cell mass, as measured by optical density (OD), begins to increase immediately upon shift-up. Consequently, the OD/cell pattern differs in the two growth-rate transitions. During rate maintenance, the OD/cell ratio increases dramatically for 60 to 70 min, and then slows appreciably and approaches the OD/cell characteristic of the new medium. During immediate division situations, the OD/cell increases only slightly for the first 180 +/- min; then the rate of increase accelerates but does not stop at the OD/cell characteristic of the new medium. Immediate division upon nutritional shift-up apparently depends upon initial doubling times in excess of 115 to 120 min and provision of a readily metabolized carbon source supporting doubling times of about 40 min. Similar immediate division occurs in E. coli B/r and K-12.

Preliminary characterization of the temperature-sensitive defect in DNA replication in a mutant mouse L cell

Temperature-sensitive ts A1S9 mouse L cells synthesize DNA apparently normally for 6-8 hr upon incubation at 38.5 degrees C. Thereafter, these cells are able to perform limited polydeoxyribonucleotide chain synthesis at the high temperature, but are unable to convert newly replicated small single-strand segments of DNA (of the order of molecular weight 10(6) daltons) to large molecular weight chromosomal DNA. Data obtained are compatible with a model which suggests that ts A1S9 cells are able to carry out most individual reactions of DNA synthesis at the high temperature, but are temperature-sensitive in a protein which participates in the joining of small DNA segments to make chromosomal DNA strands. When cells are reincubated at a permissive temperature, after the temperature-sensitive lesion has been established, they recover the latter capability several hours before they are able once again to synthesize DNA at normal rates.

Discontinuous DNA replication in mouse P-815 cells

The length of newly synthesized DNA strands from mouse P-815 cells was analyzed after denaturation both by electrophoresis and by sedimentation in alkaline sucrose gradients. [3-H]-Thymidine pulses of 2-8 min at 37 degrees C predominantly label molecules of 20-60 S. With 30-s pulses at 25 degrees C, all the [3-H]thymidine appears in short DNA strands of 50-200 nucleotides. Thus, DNA strand elongation occurs discontinuously via Okazaki fragments at both the 5' end and the 3' end. In dodecylsulfate lysates, only 10% of the Okazaki fragments are found as single-stranded molecules. About 90% are resistant to hydrolysis by the single-strand-specific nuclease S-1 and band in isopycnic gradients at the buoyant density of double-stranded DNA. No evidence for ribonucleotides at the 5' end of Okazaki fragments was obtained either in isopycnic CsCl or Cs2SO4 gradients or after incubation with polynucleotide kinase and [gamma-32P]ATP.

More precise mapping of the replication origin in Escherichia coli K-12

The origin of replication in Escherichia coli K-12 was mapped by determining the rate of marker replication during a synchronous round of replication. Four isogenic strains were made lysogenic for lambdaind(-) and for phage Mu-1, with Mu-1 integrated into a different chromosomal location in each strain. Cultures were starved for amino acids to allow completion of chromosome replication cycles and then starved for thymine in the presence of amino acids, and a synchronous cycle of replication was initiated by the addition of thymine. Samples were exposed to radioactive thymidine at intervals, deoxyribonucleic acid was extracted, and the rate of marker replication was determined by deoxyribonucleic acid-deoxyribonucleic acid hybridization to filters containing Mu-1, lambda, and E. coli deoxyribonucleic acid. The results confirm that the origin of replication is near ilv. The travel times of the replication forks, calculated from the data obtained for cultures with doubling times of approximately 40 and 61 min, are 40 and 52 min, respectively.

Size distribution and molecular polarity of newly replicated DNA in Escherichia coli

Newly synthesized DNA, in E. coli lysogenic for the phage lambda, was labeled by short pulses of [(3)H]-thymidine, isolated, and separated on the basis of size by alkaline sucrose density gradient centrifugation. The molecular polarity of this DNA was determined by hybridization with each of the separated strands of lambda DNA. The results show that, in the 3' to 5' direction, replication proceeds by synthesis of short chains that are subsequently joined to long DNA. This is true for both a polA(+) and a polA(-) strain. (The polA locus codes for DNA polymerase I.) In the 5' to 3' direction, replication proceeds continuously, by addition of nucleotides to long DNA, for the polA(+) strain. In the polA(-) strain, however, replication in the 5' to 3' direction is also discontinuous, but the discontinuities are 1-40 times less frequent than in the other direction.