Replication origin (oric) on the complementary DNA strand of Escherichia coli phage G4: biological properties of mutants

Phage G4 origin of complementary DNA strand synthesis (oric) consists of three stable secondary loop structures. In a cloned 274-bp DNA fragment that is active as an ori in the filamentous phage cloning vector R199, insertion mutants have been constructed by introducing EcoRI and HindIII linkers at the base of loop III. The in vivo activity of these oric mutants (conversion of single-strand form to replicative form in the presence of rifampicin) was significantly reduced (50-70%) but not completely abolished. Nucleotide sequences and/or potential secondary structure of loop III centered at the AvaII site are therefore an important functional part of oric.     

Rescue of functional replication origins from embedded configurations in a plasmid carrying the adenovirus genome.

A variant of the adenovirus type 5 genome which lacks EcoRI sites has been cloned in a bacterial plasmid after the addition of EcoRI oligonucleotide linkers to its ends. Closed circular forms of the recombinant viral genome were not infectious upon their introduction into permissive eucaryotic cells. The linear genome released by digestion of the 39-kilobase recombinant plasmid (pXAd) with EcoRI produced infectious virus at about 5% of the level of wild-type controls. The viruses which arose were indistinguishable from the parental strain, and the normal termini of the viral genome had been restored. Marker rescue experiments demonstrate that provision of a DNA fragment with a normal viral end improves infectivity. When a small fragment carrying a wild-type left end (the 0 to 2.6% ClaI-B fragment) was ligated to ClaI-linearized pXAd, virus was produced with efficiencies comparable to a similar reconstitution of the two ClaI fragments of the wild-type genome. These viruses stably carry the left-end fragment at both ends, leaving the normal right end embedded in 950 base pairs of DNA. The embedded right origin is inactive. The consensus of the analyses reported here is that a free end is a necessary configuration for the sequences which make up the adenovirus origin of replication.     

萘降解质粒ND1.860和NAH7的DNA同源性研究

通过DNA:DNA杂交技术,用NAH7质粒的全部EcoR Ⅰ片段或ECOR Ⅰ A片段作为~(32)P标记的DNA探针,研究了萘降解质粒ND1.860和NAH7之间的DNA同源性。在ND1.860的9个HindⅢ片段中,5个与NAH7有同源性,其中3个与NAH7的编码萘降解途径的EcoR Ⅰ A片段有同源性。     

Plasmid vector for cloning, determination of nucleotide sequence and directed assembly of DNA fragments

A plasmid vector pNIMB has been constructed (starting) from the pUR222 plasmid as a result of substitution of the polylinker containing restriction sites: PstI, SalGI, AccI, HindII, BamHI EcoRI and by other synthetic linkers with additional sites for HindIII and HgaI. Plasmid pNIMB does not differ from the parent one phenotypically. Compared to pUR222 the vector contains an additional site for cloning HindIII fragments of DNA and allows to clone SalGI/BamHI- and PstI/SalGI-fragments. Cloning of DNA fragments in all seven unique sites of pNiMB gives the possibility for sequencing the fragments avoiding their isolation from the gel. Moreover, this vector may be useful for cloning and directed assembly of chemically synthesised DNA fragments when the endonuclease HgaI sites are used.     

DNA of Epstein-Barr virus. IV. Linkage map of restriction enzyme fragments of the B95-8 and W91 strains of Epstein-Barr Virus.

The arrangement of EcoRI, Hsu I, and Sal I restriction enzyme sites in the DNA of the B95-8 and W91 isolates of Epstein-Barr virus (EBV) has been determined from the size of the single-enzyme-cleaved fragments and from blot hybridizations that identify which fragments cut from the DNA with one enzyme contain nucleotide sequences in common with fragments cut from the DNA with a second enzyme. The DNA of the B95-8 isolate was the prototype for this study. The data indicate that (i) approximately 95 X 10(6) to 100 X 10(6) daltons of EBV (B95-8) DNA is in a consistent and unique sequence arrangement. (ii) Both termini are variable in length. One end of the molecule after Hsu I endonuclease cleavage consists of approximately 3,000 base pairs, with as many as 10 additional 500-base pair segments. The opposite end of the molecule after Sal I endonuclease cleavage consists of approximately 1,500 base pairs, with as many as 10 additional 500-base pair segments. (iii) The opposite ends of the molecule contain homologous sequences. The high degree of homology between the opposite ends of the molecule and the similarity in size of the "additional" 500-base pair segments suggests that there are identical repeating units at both ends of the DNA. The arrangement of restriction endonuclease fragments of the DNA of the W91 isolate of EBV is similar to that of the B95-8 isolate and differs from the latter in the presence of approximately 7 X 10(6) daltons of "extra" DNA at a single site. Thus, the size of almost all EcoRI, Hsu I, and Sal I fragments of EBV (W91) DNA is identical to that of fragments of EBV (B95-8) DNA. A single EcoRI fragment, C, of EBV (W91) DNA is approximately 7 X 10(6) daltons larger than the corresponding EcoRI fragment of EBV (B95-8) DNA. Digestion of EBV (W91) DNA with Hsu I or Sal I restriction endonucleases produces two fragments (Hsu I D1 and D2 or Sal I G2 and G3) which differ in total size by approximately 7 X 10(6) daltons from the fragments of EBV (B95-8) DNA. Furthermore, the EcoRI, Hsu I, and Sal I fragments of EBV (W91) and (B95-8) DNAs, which are of similar molecular weight, have homologous nucleotide sequences. Moreover, the W91 fragments contain only sequences from a single region of the B95-8 genome. Two lines of evidence indicate that the "extra" sequences present in W91 EcoRI fragment C are viral DNA and not cellular. (i) The molecular weight of the "enlarged" EcoRI C fragment of EBV (W91) DNA is identical to that of the EcoRI C fragment of another isolate of EBV (Jijoye), (ii) The HR-1 clone of Jijoye has previously been shown to contain DNA which is not present in the B95-8 strain but is present in the EcoRI C and Hsu I D2 and D1 fragments of EBV (W91) DNA (N. Raab-Traub, R. Pritchett, and E. Kieff, J. Virol. 27:388-398, 1978).     

Analysis of the genome of type 7 simian adenovirus using restrictases.

The effect of the restricting endonucleases R.EcoRI, R.BamI and R.SalI on the genome of type 7 simian adenovirus (SA-7) has been studied. Since the DNA has only one site of R.EcoRI recognition the enzyme cleaves SA-7 DNA into two fragments with the molecular weights 12.0 and 10.0 . 10(6). The restrictase R.BamI cleaves the SA-7 DNA at six sites producing 7 fragments with the molecular weights 6.6, 5.9, 3.8, 2.7, 1.3, 0.7 and 0.6 . 10(6). R.SalI cleavage yields 6 fragments with the molecular weights 8.1, 5.5, 4.3, 2.45, 1.2 and 0.6 . 10(6). The R.BamI and R.SalI fragments are arranged in the orders E-A-D-F-C-G-B and A-B-D-F-E-C, respectively. The only R.EcoRI recognition site is localized in the C fragment produced by R.BamI and in the B fragment produced by R.SalI.     

Purification and structures of recombining and replicating bacteriophage T7 DNA.

During the infection of Escherichia coli by bacteriophage T7, there is a gradual conversion of host DNA to T7 DNA. Recombination and replication occur during this time. We have devised a new way of examining the physical structures of the intermediates of these processes. It is based on the observation that there are no sites in T7 DNA susceptible to cleavage by the restriction endonuclease EcoRI. E. coli DNA, on the other hand, is susceptible to degradation by EcoRI. Thus, phage and host DNA can be separated by sucrose gradient centrifugation after treatment with EcoRI. Concatemeric T7 DNA contains a high proportion of branched, gapped, and whiskered structures. These appear to be intermediates of replication and recombination. This approach also monitors the conversion process from host to T7 DNA.     

Synthesis of a human insulin gene. VII. Synthesis of preproinsulin-like human DNA, its cloning and expression in M13 bacteriophage

A 74-bp DNA sequence coding for the pre sequence of human preproinsulin and containing EcoRI termini was synthesized by the chemical enzymatic method, joined with previously synthesized proinsulin DNA, and cloned in the M 13mp8 vector. A clone pNB82 -121 was identified by DNA sequence which confirmed the correct orientation of the pre sequence to the proinsulin DNA. The EcoRI site at the junction of pre- and proinsulin DNA was eliminated by removing a triplet ATT using a synthetic 19-mer primer. To simplify preproinsulin isolation and to study its expression in the M 13 system, a 25-bp affinity leader sequence coding for (glu)7 was inserted at the remaining EcoRI site; this put the preproinsulin DNA in a correct reading frame with the AUG initiation codon of beta-galactosidase. Preproinsulin was expressed under lac promoter control as analyzed by a radioimmunoassay (RIA) against C-peptide.     

The specific binding, bending, and unwinding of DNA by RsrI endonuclease, an isoschizomer of EcoRI endonuclease

To determine whether RsrI endonuclease recognizes and cleaves the sequence GAATTC in duplex DNA similarly to its isoschizomer EcoRI we initiated a functional comparison of the two enzymes. Equilibrium binding experiments showed that at 20 degrees C RsrI endonuclease binds to specific and nonspecific sequences in DNA with affinities similar to those of EcoRI. At 0 degrees C the affinity of RsrI for its specific recognition sequence is reduced 7-fold whereas the affinity for noncanonical sequences remains relatively unchanged. Unlike EcoRI, incubation of RsrI endonuclease with N-ethylmaleimide inactivates the enzyme; however, preincubation with DNA prevents the inactivation. The N-ethylmaleimide-treated enzyme fails to bind DNA as assayed by gel mobility shift assays. Comparison of the deduced amino acid sequences of RsrI and EcoRI endonucleases suggests that modification of Cys245 is responsible for the inactivation. Fe(II). EDTA and methidiumpropyl-EDTA.Fe(II) footprinting results indicate that RsrI, like EcoRI, protects 12 base pairs from cleavage when bound to its specific recognition sequence in the absence of Mg2+. RsrI bends DNA by approximately 50 degrees, as determined by measuring the relative electrophoretic mobilities of specific RsrI-DNA complexes with the binding site in the center or near the end of the DNA fragment. This value is similar to that reported for EcoRI. RsrI also unwinds the DNA helix by 25 degrees +/- 5 degrees, a value close to that reported for EcoRI endonuclease. Collectively, these results indicate that the overall structural changes induced in the DNA by the binding of RsrI and EcoRI endonucleases to DNA in the absence of Mg2+ are similar. In the accompanying paper (Aiken, C. R., McLaughlin, L. W., and Gumport, R. I. (1991) J. Biol. Chem. 266, 19070-19078) we present results of studies of RsrI endonuclease using oligonucleotide substrates containing base analogues which suggest differences in the ways the two enzymes cleave DNA.     

Rescue of infectious virus from permissive monkey cells containing simian virus 40 DNA fragments.

Permissive TC7 cells were separately transfected with simian virus 40 (SV40) EcoRI/Hap II A (74% genome) DNA fragments and EcoRI/Hap II B (26% genome) DNA fragments in the presence of DEAE-dextran. Fusion of the progeny of recipient cells receiving the A fragment, TC7 (SV40/74) cells, with TC7 (SV40/26) cells, which had received the B fragment, resulted in SV40 rescue. TC7 (SV40/74 + 26) cells, which had simultaneously received both complementary subgenomes, either spontaneously produced SV40 upon subculture or yielded virus upon treatment with iododeoxyuridine. In addition, fusion of rat cells containing the EcoRI/Hap II A fragment with TC7 (SV40/26) cells resulted in SV40 rescue. Cytopathology, V-antigen production, neutralization, and electron microscopy were parameters used to verify that the rescued virus was SV40. No infectious virus was produced when the combinations of cells fused did not total a complete SV40 genome equivalent.     

Biochemical studies on bovine adenovirus type 3. III. Cleavage maps of viral DNA by restriction endoncleases EcoRI, BamHI, and HindIII.

Cleavage of bovine adenovirus type 3 (BAV3) DNA by restriction endonucleases EcoRI, BamHI, and HindIII yielded 7 (A to G), 5 (A to E), and 12 (A to L) fragments, respectively. The order of these fragments has been determined to be GDACBFE for EcoRI fragments, AEBDC for BamHI fragments, and JEBKACDHFGIL for HindIII fragments, and cleavage sites of these enzymes have been mapped on the genome of BAV3. BAV3 preparation contains incomplete virus whose genome has a deletion of about 13% of complete virus genome. Restriction endonuclease digestion of the incomplete virus DNA revealed that EcoRI E and F, BamHI C and HindIII G, I, and L fragments were deleted. Therefore, the deleted region of incomplete virus DNA is located near the right-hand end of the BAV3 DNA molecule, a result consistent with our previous electron-microscopic observations on heteroduplex molecules formed between complete and incomplete BAV3 DNA.     

Overmethylation of DNAs by the EcoRI methylase.

EcoRI methylase is able to catalyze methy incorporation into DNA at sequences other than the canonical EcoRI site. At high enzyme concentrations and over a wide range of pH and ionic strengths, EcoRI methylase modifies polyoma DNA (which contains one EcoRI site) at a number of sites. This modification prevents EcoRI endonuclease activity, and thus is presumably at or near the EcoRI sequences (5') NAATTN.     

Epstein-Barr Virus-Specific RNA III. Mapping of DNA Encoding Viral RNA in Restringent Infection

Namalwa and Raji cells, originally obtained from a Burkitt tumor biopsy, grow as continuous cell lines in vitro and contain the Epstein-Barr virus (EBV)-related nuclear antigen EBNA (B. M. Reedman and G. Klein, Int. J. Cancer 11:499-520, 1973) and RNA homologous to at least 17 and 30% of the EBV genome, respectively (S. D. Hayward and E. Kieff, J. Virol. 18:518-525, 1976; T. Orellana and E. Kieff, J. Virol. 22:321-330, 1977). The polyribosomal and polyadenylated [poly(A)+] RNA fractions of Namalwa and Raji cells are enriched for a class of viral RNA homologous to 5 to 7% of EBV DNA (Hayward and Kieff, J. Virol. 18:518-525, 1976; Orellana and Kieff, J. Virol. 22:321-330, 1977). The objective of the experiments described in this communication was to determine the location within the map of the EBV genome (D. Given and E. Kieff, J. Virol. 28:524-542, 1978) of the DNA which encodes the viral RNA in the poly(A)+ and non-polyadenylated [poly(A)-] RNA fractions of Namalwa cells. Hybridization of labeled DNA homologous to Namalwa poly(A)+ or poly(A)- RNA to blots containing EcoRI, Hsu I, or Hsu I/EcoRI double-cut fragments of EBV (B95-8) or (W91) DNA indicated that these RNAs are encoded by DNA contained primarily in the Hsu I A/EcoRI A and Hsu I B/EcoRI A fragments and, to a lesser extent, in other fragments of the EBV genome. Hybridizations of Namalwa poly(A)+ and poly(A)- RNA in solution to denatured labeled EcoRI A or B fragments, Hsu I A, B, or D fragments, and Hsu I A/EcoRI A or Bam I S fragments and of Raji polyribosomal poly(A)+ RNA to the EcoRI A fragment indicated that (i) Namalwa poly(A)+ RNA is encoded primarily by 6 x 10(5) daltons of a 2 x 10(6)-dalton segment of DNA, Bam I S, which is tandemly reiterated, approximately 10 times, in the Hsu I A/EcoRI A fragment and is encoded to a lesser extent by DNA in the Hsu I B, EcoRI B, and Hsu I D fragments. Raji polyribosomal poly(A)+ RNA is encoded by a similar fraction of the EcoRI A fragment as that which encodes Namalwa poly(A)+ RNA. (ii) The fraction of the Bam I S fragment homologous to Namalwa poly(A)- RNA is similar to the fraction homologous to Namalwa poly(A)+ RNA. However, Namalwa poly(A)- RNA is homologous to a larger fraction of the DNA in the Hsu I B, Hsu I D, and EcoRI B fragments.     

DNA methylation can enhance or induce DNA curvature.

Oligomers of different palindromic sequences (EcoRI, BamHI, and ClaI linkers) were ligated to form distributions of multimers. These long ligation ladders were methylated using corresponding methylases. The migration of the unmethylated as well as the methylated multimer distributions was analysed in 10% polyacrylamide gels. The migration anomaly of these sequences is interpreted in terms of the curvature of the DNA helix axis. The double-stranded oligomer dCGGAATTCCG is considerably curved in its unmodified form. Its curvature is strongly enhanced when the central dAs are methylated. This result is predicted by a model for DNA curvature. Multimers of the closely related sequence dCGGGATCCCG are straight. When methylated at the central dAs or at the most central dCs, a small curvature of the helix axis is induced. The double-stranded oligomer dCCATCGATGG is straight in its unmodified form as well as when it is methylated. Thus, DNA curvature can be induced or enhanced by methylation. However, DNA methylation at palindromic sequences seems not always to influence the linear path of the DNA helix axis.     

Essential structure in the cloned transforming DNA that induces gene amplification of the Bacillus subtilis amyE-tmrB region.

Bacillus subtilis B7, a mutant which acquired gene amplification of the amyE-tmrB region, showed, as a result, hyperproductivity (about a 5- to 10-fold increase) of alpha-amylase and tunicamycin resistance. The mutational character was transferred to recipient cells by competence transformation. A 14-kilobase (kb) EcoRI chromosomal DNA fragment of strain B7 was found to have the transforming activity. We cloned a 6.4-kb EcoRI fragment on a phage vector lambda Charon 4A through a spontaneous deletion of 7.6 kb from the 14-kb fragment and subcloned a 1.6-kb HindIII fragment on pGR71. The cloned 6.4-kb EcoRI and 1.6-kb HindIII fragments retained the transforming activity of inducing gene amplification of the amyE-tmrB region. At the junction point (J) of the repeating units (16 kb), the tmrB gene was linked to a DNA region (M) located 4 kb upstream of amyE. The essential structure of the cloned, transforming (gene amplification-inducing) DNA was deduced to be that around J. The subcloned 1.6-kb HindIII fragment that retained the transforming activity was shown to be almost solely composed of the tmrB-J-M region. In addition, the DNA sequence around J was determined.     

Bacteriophage lambda and plasmid vectors, allowing fusion of cloned genes in each of the three translational phases.

We have constructed vectors from bacteriophage lambda and from plasmid pBR322 having a single EcoRI restriction site which is immediately downstream from the lac UV5 promotor. Each vector allows the fusion of a cloned gene to the lac Z gene in a different phase relative to the translation initiation codon of the lac Z gene. These vectors were constructed through modification of the initial EcoRI restriction site by S1 endonuclease treatment and then addition of octadeoxyribonucleotides (EcoRI linkers), which shifted the restriction site by 2 or 4 nucleotides. Used in combination these vectors should allow translation of a cloned gene in any one of the three coding phases. The bacteriophages vectors are certified as B2 (EK2) safety level vectors by the French "recombinaison génétique in vitro" committee (D.G.R.S.T.).     

Detection of ligation products of DNA linkers with 5'-OH ends by denaturing PAGE silver stain

To explore if DNA linkers with 5'-hydroxyl (OH) ends could be joined by commercial T4 and E. coli DNA ligase, these linkers were synthesized by using the solid-phase phosphoramidite method and joined by using commercial T4 and E. coli DNA ligases. The ligation products were detected by using denaturing PAGE silver stain and PCR method. About 0.5-1% of linkers A-B and E-F, and 0.13-0.5% of linkers C-D could be joined by T4 DNA ligases. About 0.25-0.77% of linkers A-B and E-F, and 0.06-0.39% of linkers C-D could be joined by E. coli DNA ligases. A 1-base deletion (-G) and a 5-base deletion (-GGAGC) could be found at the ligation junctions of the linkers. But about 80% of the ligation products purified with a PCR product purification kit did not contain these base deletions, meaning that some linkers had been correctly joined by T4 and E. coli DNA ligases. In addition, about 0.025-0.1% of oligo 11 could be phosphorylated by commercial T4 DNA ligase. The phosphorylation products could be increased when the phosphorylation reaction was extended from 1 hr to 2 hrs. We speculated that perhaps the linkers with 5'-OH ends could be joined by T4 or E. coli DNA ligase in 2 different manners: (i) about 0.025-0.1% of linkers could be phosphorylated by commercial T4 DNA ligase, and then these phosphorylated linkers could be joined to the 3'-OH ends of other linkers; and (ii) the linkers could delete one or more nucleotide(s) at their 5'-ends and thereby generated some 5'-phosphate ends, and then these 5'-phosphate ends could be joined to the 3'-OH ends of other linkers at a low efficiency. Our findings may probably indicate that some DNA nicks with 5'-OH ends can be joined by commercial T4 or E. coli DNA ligase even in the absence of PNK.     

In vitro packaging of a lambda Dam vector containing EcoRI DNA fragments of Escherichia coli and phage P1.

In this report we describe a coliphage lambda vector system for cloning endo R. EcoRI DNA fragments. This system differs significantly from those previously described in two ways. First, restricted and ligated DNA is encapsidated in vitro. Second, with increasing lambda DNA size in the range 78 to 100% that of wild-type, the efficiency of DNA encapsidation into infectious phage particles markedly increases. For lambda wild-type DNA the efficiency of in vitro packaging (10(6) to 10(7) plaques produced per microgram of added DNA) is equal to, or better than, the standard CaCl2 transfection method. The use of a Dam mutation to facilitate recognition of size classes of inserted fragments is described. Using this vector and in vitro packaging, several E. coli and phage P1 and R.EcoRI fragments were cloned.     

Cloning of the lacI gene into A ColE1 plasmid.

The binding of lac repressor to lac operator was utilized to isolate an EcoRI fragment of lambda h80dlac (i+ as well as iq) that contains the lacI gene and lac promoter-operator regions. Ligation of this fragment into EcoRI cleaved pMB9 yielded chimeric DNA molecules of mol. w.t. 9.6 . 10(-6) and 1.5 . 10(7) daltons. Transformed strains containing the plasmids were analyzed for repressor production in vivo and in vitro. Repressor production in one plasmid strain is 7-fold greater than that in heat-inducible lambda h80dlac(iq)lysogens.     

The EcoRI restriction endonuclease with bacteriophage lambda DNA. Equilibrium binding studies.

The EcoRI restriction endonuclease was found by the filter binding technique to form stable complexes, in the absence of Mg2+, with the DNA from derivatives of bacteriophage lambda that either contain or lack EcoRI recognition sites. The amount of complex formed at different enzyme concentrations followed a hyperbolic equilibrium-binding curve with DNA molecules containing EcoRI recognition sites, but a sigmoidal equilibrium-binding curve was obtained with a DNA molecule lacking EcoRI recognition sites. The EcoRI enzyme displayed the same affinity for individual recognition sites on lambda DNA, even under conditions where it cleaves these sites at different rates. The binding of the enzyme to a DNA molecule lacking EcoRI sites was decreased by Mg2+. These observations indicate that (a) the EcoRI restriction enzyme binds preferentially to its recognition site on DNA, and that different reaction rates at different recognition sites are due to the rate of breakdown of this complex; (b) the enzyme also binds to other DNA sequences, but that two molecules of enzyme, in a different protein conformation, are involved in the formation of the complex at non-specific consequences; (c) the different affinities of the enzyme for the recognition site and for other sequences on DNA, coupled with the different protein conformations, account for the specificity of this enzyme for the cleavage of DNA at this recognition site; (d) the decrease in the affinity of the enzyme for DNA, caused by Mg2+, liberates binding energy from the DNA-protein complex that can be used in the catalytic reaction.