Arthrobacter luteus restriction endonuclease recognition sequence and its cleavage map of SV40 DNA

The nucleotide sequence at the cleavage site of the restriction endonuclease isolated from Arthrobacter luteus (Alu) has been determined. The endonuclease cleaves at the center of a palindromic tetranucleotide sequence to give even-ended duplex DNA fragments phosphorylated at the 5'-end. The endonuclease cleaves SV40 form I DNA into 32 fragments. The order and sizes of these fragments have been determined to provide an Alu cleavage map of the SV40 genome.

Terminal labeling and addition of homopolymer tracts to duplex DNA fragments by terminal deoxynucleotidyl transferase

Terminal deoxynucleotidyl transferase, which requires a single-stranded DNA primer under the usual assay conditions, can be made to accept double-stranded DNA as primer for the addition of either rNMP or dNMP, if Mg+2 ion is replaced by Co+2 ion. The priming efficiency in the presence of Co+2 ion with respect to initial rate tested with 2 single-stranded primer, is 5-6 fold higher than that observed with Mg+2 ion. In the presence of Co+2 ion, the primer specificity is altered so that all forms of duplex DNA molecules can be labeled at their unique 3'-ends regardless of whether such ends are staggered or even. Thus, using ribonucleotide incorporation, we have for the first time employed this reaction for sequence analysis of duplex DNA fragments generated by restriction endonuclease cleavages. Furthermore, by using Co+2 ion, it is possible to add a long homopolymer tract of deoxyribonucleotides to the 3'-terminus of double-stranded DNA. Therefore, without prior treatment with lambda exonuclease to expose the 3' terminus as single-stranded primer, this reaction now permits insertion of homopolymer tails at the 3'-ends of all types of DNA molecules for the purpose of in vitro construction of recombinant DNA.

Synchronous digestion of SV40 DNA by exonuclease III

We have established an optimal condition for the synchronous digestion of SV40 DNA with Escherichia coli exonuclease III. Electron microscopy and polyacrylamide gel electrophoresis were used to obtain accurate measurements on the lengths of DNA before and after exonuclease III digestion. Based on this finding, a new method for determining the sequence of long duplex DNA can be realized. It involves (a) the synchronous digestion of the DNA from the 3' ends with exonuclease III, followed by (b) repair synthesis with labeled nucleotides and DNA polymerase, and (c) sequence analysis of the repaired DNA.

A general method for inserting specific DNA sequences into cloning vehicles

A general method has been developed to introduce any double-stranded DNA molecule into cloning vehicles at different restriction endonuclease sites. In this method a chemically synthesized decadeoxyribonucleotide duplex, containing a specific restriction endonuclease sequence, is joinlex DNA is cut by the same restriction endonuclease to generate the cohesive ends. It is then inserted into the restriction endonuclease cleavage site of the cloning vehicle. To demonstrate the feasibility of this new method, we have inserted separately the synthetic lac operator DNA at the Bam I and HindIII cleavage sites of the plasmid pMB9 DNA.

Terminal labeling and addition of homopolymer tracts to duplex DNA fragments by terminal deoxynucleotidyl transferase

Terminal deoxynucleotidyl transferase, which requires a single-stranded DNA primer under the usual assay conditions, can be made to accept double-stranded DNA as primer for the addition of either rNMP or dNMP, if Mg+2 ion is replaced by Co+2 ion. The priming efficiency in the presence of (C leads to) CO+2 ion with respect to initial rate tested with 2 single-stranded primer, is 5-6 fols higher than that observed with Mg+2 ion. In the presence of Co+2 ion, the primer specificity is altered so that all forms of duplex DNA molecules can be labeled at their unique 3' -ends regardless of whether such ends are staggered or even. Thus, using ribonucleotide incorporation, we have for the first time employed this reaction for sequence analysis of duplex DNA fragments generated by restriction endonuclease cleavages. Furthermore, by using Co+2 ion, it is possible to add a long homopolymer tract of deoxyribonucleotides to the 3'-terminus of double-stranded DNA. Therefore, without prior treatment with lambda exonuclease to expose the 3' terminus as single-stranded primer, this reaction now permits insertion of homopolymer tails at the 3'-ends of all types of DNA molecules for the purpose of in vitro construction of recombinant DNA.

Chemical and enzymatic synthesis of lactose operator of Escherichia coli and its binding to lactose repressor

The 21-nucleotide-long duplex DNA constituting the lactose operator sequence of E. coli has been synthesized by both chemical and enzymatic methods. The synthetic duplex has the essential feature of the lactose operator as seen by its binding to the lactose repressor. The binding of the synthetic operator fragment to the lactose repressor is specific because it is inhibited by the inducing ligand isopropyl-beta-D-thiogalactoside. Thus, it is now possible to show that a chemically synthesized oligodeoxynucleotide can be specifically recognized by its natural regulatory protein.

Role of gene 59 of bacteriophage T4 in repair of UV-irradiated and alkylated DNA in vivo

Nonsense mutants in gene 59 (amC5, amHL628) were used to study the role of this gene in the repair of UV-damaged and alkylated DNA of bacteriophage T4 in vivo. The higher sensitivity to UV irradiation and alkylation of gene 59 mutants after exposure to these agents was established by a comparison of the survival fractions with wild type. Zonal centrifugal analysis of both parental and nascent mutant intracellular DNA molecules after UV irradiation showed that immediately after exposure the size of single-stranded DNA fragments was the same as the wild-type intracellular DNA. However, the capability of rejoining fragmented intracellular DNA was greatly reduced in the mutant. In contrast, the wild-type-infected cells under the same condition resumed DNA replication and repaired its DNA to normal size. Methyl methanesulfonate induced more randomly fragmented intracellular DNA, when compared to UV irradiation. The rate of rejoining under these conditions as judged from their sedimentation profiles was also greatly reduced in mutant-infected cells. Further evidence is presented that UV repair is not a simple consequence of arrested DNA replication, which is a phenotype of the mutant when infected in a nonpermissive host, Escherichia coli B (su minus), but rather that the DNA repair function of gene 59 is independent of the replication function. These and other data presented indicate that a product(s) of gene 59 is essential for both repair of UV lesions and repair of alkylation damage of DNA in vivo. It is suggested that gene 59 may have two functions during viral development: DNA replication and replication repair of DNA molecules.

Specific hydrolysis of the cohesive ends of bacteriophage lambda DNA by three single strand-specific nucleases

Procedures have been worked out for Aspergillus nuclease S1 and mung been nuclease to quantitatively cleave off both of the 12-nucleotide long, single-stranded cohesive ends of lambdaDNA. This cleavage is indicated by the almost complete elimination of the repair incorporation of radioactive nucleotides by DNA polymerase into the digested DNA. With S1 nuclease, cleavage was complete at 10 degrees as well as at 30 degrees. Under the conditions for quantitative cleavage of the single-stranded regions there was no digestion of the double-stranded lambdaDNA. The mung bean nuclease cleaved off the cohesive ends completely at 30 degrees but at 5 degrees, the cleavage was not complete even at high enzyme concentration. The nearest neighbor analysis of the repaired DNA indicates that at 5 degrees about four nucleotides remained undigested. The mung bean nuclease also introduced, under the conditions used, some nicks into double-stranded DNA as determined by the repair incorporation. The Escherichia coli exonuclease VII cleaved off part of the cohesive ends of lambdaDNA, leaving two nucleotides on each end as single-stranded tails.

Chemical synthesis and sequence studies of deoxyribooligonucleotides which constitute the duplex sequence of the lactose operator of Escherichia coli

We have synthesized the deoxyribooligonucleotide fragments, constituting the sequence of the lac operator of Escherichia coli. Two of these fragments, d(pApApTpTpGpTpTpApT) (nonamer) and d(pApApTpTpGpTpGpApG) (nonamer), corresponding to the 5' termini of lac operator have been synthesized by the phosphodiester method. The remaining four fragments, d(ApCpApApTpT) (hexamer), d(ApTpApApCpApApTpT) (nonamer), d(ApApTpTpGpTpGpApGpCpGpG) (dodecamer), and d(ApApTpTpGpTpTpApTpCpCpGpCpTpC) (pentadecamer), have been synthesized by an improved phosphotriester method. All of the compounds were first characterized by venom and spleen phosphodiesterase digestion to obtain their base composition. The sequence of these oligonucleotides was fully confirmed by the characteristic mobility shifts of their partial venom phosphodiesterase digestion products on two-dimensional homochromatography. A comparative study of the two methods for the synthesis of oligonucleotides has revealed that the phosphotriester method is more convenient than the phosphodiester method because of higher yields and ease of handling large scale preparations.

DNA sequence analysis. Terminal sequences of bacteriophage phi80

Sequences of the cohesive ends and the 3'-terminal regions of phi80 DNA have been determined. Sequences of the cohesive ends were obtained through the use of two standard methods. The first method involved the incorporation of all four labeled deoxyribonucleotides into the phi80 cohesive ends using DNA polymerase I. The DNA was then partially digested with micrococcal nuclease or pancreatic DNase. The products were separated by two-dimensional electrophoresis and characterized by composition, 3'-terminal, and nearest neighbor analyses. The second method involved partial incorporation using one, two, or three labeled deoxyribonucleotides followed by similar analyses. Sequences of the double-stranded regions adjacent to the cohesive ends were determined by three new methods. These methods were: (a) the DNA was specifically labeled at the 3' terminus and then partially degraded. Labeled oligonucleotide products were sequenced by their mobilities on various separation systems. (b) The cohesive ends were enlarged by limited degradation with exonuclease III. After this treatment, the DNA was partially repaired with labeled nucleotides, digested, and the products were analyzed. (c) A synthetic ologonucleotide primer was bound to phi80 DNA which had been repaired with DNA polymerase I, and then partially digested with lambda-exonuclease. The primer was extended into the region of interest by partial repair with labeled nucleotides. The extended primer was isolated and analyzed.

On the statistical significance of primary structural features found in DNA-protein interaction sites

Probabilities of occurrence for a number of the symmetries and other sequence regularities found in DNA-protein interaction site sequences have been calculated for segments of random DNA sequence. Results show that many of the symmetrical and repetitive features seen in these interaction sites are likely to have occured by chance. Other features are so unlikely to have occurred by chance that they are probably involved in the DNA-protein interaction processes.

DNA sequence analysis: a formula to predict electrophoretic mobilities of oligonucleotides on cellulose acetate

A simple method has recently become available for sequence analysis of large oligonucleotide fragments. Sequences are derived from the characteristic mobility shifts of the sequential partial degradation products of the oligonucleotide on two dimensional homochromatography. We have now developed an empirical formula for predicting the relative mobilities of each of the partial products in the first dimension (electrophoresis on cellulose acetate gel). The formula allows a more precise interpretation of the sequence of the oligonucleotide. It eliminates the ambiguities present in the method previously reported for sequence analysis by simple inspection of the mobility shifts. In order to amplify the mobility shifts so that they may be more easily and accurately measured, methods have been developed for preparing and fractionating the oligonucleotides on 40 x 40 cm DEAE-cellulose plates. Both improvements have proven valuable for direct sequence analysis by mapping.