The use of phosphorothioate-modified DNA in restriction enzyme reactions to prepare nicked DNA

Hybrid cytochromes P-450 identify a substrate binding domain in P-450IIC5 and P-450IIC4

The cytochrome P-450 superfamily of enzymes catalyzes the oxidative metabolism of innumerable lipophilic compounds (e.g., drugs, carcinogens, steroids). Although the three-dimensional structure of a soluble bacterial P-450 (P-450cam) has been solved, little is known about the structures of the membrane-bound mammalian P-450s. Thus, the structural features of these enzymes that determine their multisubstrate specificity are unknown. In this report, we identify a segment of the primary structure of the structurally similar but functionally distinct cytochromes P-450IIC5 and P-450IIC4, which determines the apparent affinity of these cytochromes for the conversion of progesterone into the mineralocorticoid deoxycorticosterone. P-450IIC5 exhibits a greater than 10-fold lower apparent Km than P-450IIC4 for progesterone 21-hydroxylation. Chimeric cDNAs were constructed and expressed in COS-1 cells, which encode hybrids between these enzymes. The hybrid enzymes were assayed for catalytic activity and compared to the parental proteins. A segment of P-450IIC5 was identified that conferred the lower Km of P-450IIC5 to P-450IIC4. Sequential reduction of the length of the exchanged segments led to a hybrid enzyme with a high affinity derived largely from P-450IIC4, which contains three amino acid residues derived from P-450IIC5 clustered between positions 113 and 118. This suggests that this region is part of a substrate binding domain. This region maps by alignment of amino acid sequences to a residue of P-450cam, which has been implicated in substrate binding, suggesting that these segments of the primary structure serve a similar functional role in these two distantly related proteins.

Characterization of the catalytic residues of the tobacco etch virus 49-kDa proteinase

The 49-kDa proteinase of tobacco etch virus (TEV) cleaves the polyprotein derived from the TEV genomic RNA at five locations. Molecular genetic and biochemical analyses of the 49-kDa TEV proteinase were performed to test its homology to the cellular trypsin-like serine proteases. A cDNA fragment, containing the TEV 49-kDa proteinase gene and flanking sequences, was expressed in a cell-free transcription/translation system and resulted in the formation of a polyprotein precursor that underwent rapid self-processing. Site-directed mutagenesis was used to test the effect of altering individual 49-kDa amino acid residues on proteolysis. The data suggest that the catalytic triad of the TEV 49-kDa proteinase could be composed of the His234, Asp269, and Cys339. These findings are consistent with the hypothesis that the TEV 49-kDa proteinase is structurally similar to the trypsin-like family of serine proteinases with the substitution of Cys339 as the active site nucleophile. A structural model of the TEV 49-kDa proteinase proposes other virus-specific differences in the vicinity of the active site triad and substrate-binding pocket. The structure may explain the observed negligible effect of most cellular proteinase inhibitors on the activity of this viral proteinase.

Deletion analysis of the polyomavirus late promoter: evidence for both positive and negative elements in the absence of early proteins

We have been interested in understanding more about the sequences that constitute the polyomavirus late promoter. Our approach has been to target specific deletions to the viral intergenic region by oligonucleotide-directed mutagenesis. Wild-type and mutant promoter cassettes with defined deletions were then inserted into a promoterless expression vector containing the bacterial chloramphenicol acetyltransferase (CAT) gene (cat). Plasmids were introduced into mouse NIH 3T3 cells by transfection, and promoter activities were assessed by quantitation of both CAT enzyme and cat mRNA levels. In this report, we present the results of experiments designed to map promoter elements which affect late transcription in the absence of early viral proteins and viral DNA replication. Using this approach, we mapped two major cis-acting elements (a positive and a negative one) which affect transcription in our transient expression system. The first, positive, element coincided with the enhancer A element, which is known to be important for early transcription and viral DNA replication. Removal of this element reduced late transcription by 50- to 100-fold. The second element was a negative one; removal of 89 base pairs that included two high-affinity large-T-antigen-binding sites just to the early side of the inverted repeat structure within the replication origin resulted in a 5- to 10-fold increase in late promoter activity. The implications of these findings for late promoter function and regulation are discussed.

Molecular genetic and biochemical evidence for the involvement of the heptapeptide cleavage sequence in determining the reaction profile at two tobacco etch virus cleavage sites in cell-free assays

Potyviruses express their genetic information from a genome length RNA as a single polyprotein, which is post-translationally processed by at least two different viral-encoded proteolytic activities. Since regulation of the expression of individual genes is not likely to occur at the transcriptional level, we sought to determine if post-translational regulation of gene expression was possible via differential proteolytic processing. Modulating the rate of cleavage at different gene product junctions could be a potential mechanism to regulate the kinetics of formation of specific gene products. We have examined the proteolytic processing of two tobacco etch virus (TEV) cleavage sites using a cell-free system in which synthetic polyprotein precursors were processed by the TEV 49-kDa proteinase. The amino acid sequences at these two sites contained both conserved and variable positions. The cleavage reaction at the TEV 50/71-kDa junction was characterized as "slow" (T1/2 = approximately 27 min) while the cleavage reaction at the 58/30-kDa junction was judged "fast" (T1/2 = approximately 5 min). Similar cleavage reactions were observed whether the cleavage site was in its natural polyprotein context or placed in a foreign position. The slow and fast cleavage sites could be interconverted by changing the nonconserved amino acid positions. The data suggest that the heptapeptide sequence proximal to a TEV cleavage site determines not only cleavage at a particular junction but influences the cleavage reaction profile in cell-free studies.

Inactivation of carboxypeptidase Y by mutational removal of the putative essential histidyl residue

Carboxypeptidase Y is a serine carboxypeptidase assumed to contain a catalytic triad similar to the serine endopeptidases. On the basis of the homology between various serine carboxypeptidases His-397 is suspected to be part of the catalytic triad. To test this it was exchanged with Ala and Arg by site-directed mutagenesis of the cloned PRC1 gene. The catalytic efficiency of the mutant enzymes were reduced by a factor of 2 X 10(4) and 7 X 10(2), respectively, confirming the key role of His-397 in catalysis. Treatment of Ala-397-CPD-Y with Hg++ or CNBr, hence modifying Cys-341 located in the vicinity of the active site abolished the residual activity of the enzyme, indicating an additional involvement of this residue in catalysis.

Molecular genetic analysis of a plant virus polyprotein cleavage site: a model

The RNA genome of tobacco etch virus (TEV) is expressed as a polyprotein which is co- and post-translationally processed by viral encoded proteinases. The TEV 49,000 dalton (49-kDa) proteinase cleaves the polyprotein at five positions each defined by the seven amino acid consensus sequence, (formula; see text) One of the cleavage sites, the 58-kDa nuclear inclusion/30-kDa capsid protein junction was altered by site-directed mutagenesis and the effects of these alterations on cleavage were determined. Polyprotein precursors were synthesized by translation of T7 polymerase-derived transcripts and processed in a cell-free system using TEV nuclear inclusion bodies as a source of 49-kDa proteolytic activity. A wild-type cleavage site and 61 substrates containing site-directed amino acid replacements at the nonconserved P7, P5, P4, P2, and P'2 positions were examined. Amino acid replacements flanking the putative TEV cleavage sequence at the P7 and P'2 positions had minimal effects on cleavage. Amino acid substitutions at positions P5, P4, and P2 resulted in substrates which were processed by the 49-kDa TEV proteinase, albeit generally at reduced rates. No substitution at any of these five positions resulted in total elimination of cleavage. A model is presented which proposes different roles for conserved and variable positions in the TEV heptapeptide cleavage sequence.

Prolactin upstream factor I mediates cell-specific transcription

DNA sequence-specific chromatography was used to purify prolactin upstream factor I (PUF-I) approximately 10,000- to 20,000-fold from rat GH3 cells. The purified transcription factor reconstituted enhanced pituitary-specific prolactin RNA synthesis in nonpituitary in vitro transcription assays. In vitro mutagenesis demonstrated that the capacity to stimulate prolactin gene transcription was directly correlated with PUF-I binding to an A+T-rich region located from -63 to -36 in the prolactin 5'-flanking DNA. We propose that PUF-I is a critical modulator of transcriptional activity in pituitary cells and has a central role in the stimulation of prolactin gene transcription in the mammalian pituitary lactotroph.

Mutations at the distal and proximal sites of cytochrome P-450d changed regio-specificity of acetanilide hydroxylations

Regio-specificities of acetanilide hydroxylations were studied for 11 distal, 9 proximal and 3 aromatic mutants of cytochrome P-450d. Ratios of turnover numbers among these products were remarkably changed depending on the mutants. For example, the ratio of turnover number, para:ortho:meta = 7:0.1:0.3 for the wild type changed to 11:4:3 for a distal mutant, Thr322Ala, or to 13:13:1 for a proximal mutant, Arg455Gly. It was suggested that regio-specificities of microsomal P-450 enzymes are controlled cooperatively by the whole structure of the protein molecules which influences the tertiary structure of the distal environment.

The conserved 900 stem/loop region in Escherichia coli 16S ribosomal RNA is not required for protein synthesis

Plasmid pPM114 carries the Escherichia coli 16S ribosomal RNA gene under the control of a T7 promoter. It can generate in vitro transcribed 16S rRNA that can be assembled into functional 30S ribosomal subunits. Two deletion mutants were derived from pPM114, by partial or total deletion of the conserved 900 stem/loop region of the 16S rRNA. These mutants, pMG delta 10 and pMG delta 23, respectively lack bases 895 to 904 and 889 to 911 of the 16S rRNA. The amputated 16S rRNA transcripts synthesized from these mutated plasmids were assembled into 30S subunits which were as active under the direction of an artificial or a natural messenger as subunits reconstructed with the full-length 16S rRNA transcript. They also responded as well to the stimulation of misreading by streptomycin, although the deleted region is proximal to the streptomycin binding domain. However, when we attempted to delete the 895-904 or 889-911 region from the 16S rRNA gene in plasmid pKK3535 which carries the rrnB operon, no transformants harbouring plasmids with one of these deletions could be recovered. These observations suggest that the 900 stem/loop region of the 16S rRNA is not required for the ribosomal function but is probably essential for important cell regulatory functions.

Bindings of axial ligands to cytochrome P-450d mutants: a difference absorption spectral study

By site-directed mutagenesis, we made several cytochrome P-450d (P-450d) mutants as follows: Asn310Phe (D13), Ile312Leu (D14), Glu318Asp (D15), Val320Ile (D16), Phe325Thr (D19), Asn310Phe,Ile312Leu (M6), Glu318Asp,Val320Ile (M7), Phe325Thr, Glu318Asp (M3). This region (Asn-310-Phe-325) is supposed to be located in the distal helix above the heme plane in P-450d, being conjectured from the structure of P-450cam. We studied Soret spectral changes of those mutants by adding several axial ligands such as aniline, pyridine, metyrapone, 2-phenylimidazole and 4-phenylimidazole. Binding constants (Kb) of aniline and pyridine to the single and double mutants were higher than those to the wild type by 2-10-times. The double mutations did not additively increase the Kb values compared with those to the single mutants. In contrast, Kb value (1.0.10(5) M-1) of metyrapone to the double mutant M3 was much higher than that (2.0.10(3) M-1) of the wild type and those of the single mutants, D15 (4.5.10(4) M-1) and D19 (1.6.10(4) M-1). The increased affinity of metyrapone to the mutant M3 may be attributed to an interaction of the hydrophobic group of metyrapone with nearby hydrophobic group(s) produced cooperatively by the double mutation of P-450d. Kb values of 2-phenylimidazole and 4-phenylimidazole to the mutant M3 were also the highest among those of the mutants and the wild type. Therefore, it was suggested that this region (from Asn-310 to Phe-325) must be located at the distal region of the heme moiety and form, at least, a substrate-binding region of membrane-bound P-450d.

A difference in the importance of bulged nucleotides and their parent base pairs in the binding of transcription factor IIIA to Xenopus 5S RNA and 5S RNA genes

Individual bulge loops present in Xenopus 5S RNA (positions 49A-A50 in helix III, C63 in helix II and A83 in helix IV), were deleted by site directed mutagenesis. The interaction of these mutant 5S RNA molecules with TFIIIA was measured by a direct binding assay and a competition assay. The results of these experiments show that none of the bulged nucleotides in Xenopus 5S RNA are required for the binding of TFIIIA. The affinity of the mutant 5S RNA genes for TFIIIA was also studied by a filter binding assay. In contrast to the effect that deleting bulged nucleotides had on the TFIIIA-RNA binding affinity, deletion of the corresponding A-T base pair at position +83 in 5S DNA was found to reduce the apparent association constant of TFIIIA by a factor of four-fold.

Phosphorothioates in molecular biology

The observation that phosphorothioate analogues of the nucleoside triphosphates are substrates for DNA- and RNA-polymerases has proven a boon for the molecular biologist. As these phosphorothioate-containing polymers are stable to degradation by nucleases and the sulfur atom confers many favourable chemical properties, several applications in molecular biology have been developed, including new methods for site-directed mutagenesis and DNA sequencing.

CUG initiation codon used for the synthesis of a cell surface antigen coded by the murine leukemia virus

Murine leukemia virus (MuLV) codes for two precursors of the group-specific antigens, Pr65gag and Pr75gag, in vivo. While Pr65gag is the precursor to the virion structural proteins, Pr75gag undergoes glycosylation and is found on the surface of the infected cell as gp85gag, and it is thought to play a role in virus maturation and spread. Pr65gag synthesis starts at an AUG codon within a favourable initiation context (AAUAUGG at positions 618 to 624). The gp85gag start codon is upstream but its precise location is not known. To map the initiation codon of gp85gag, we used deletion and site-directed mutagenesis of the leader sequence of MuLV RNA and in vitro translation of the RNAs. Synthesis of the MuLV gp85gag protein appears to be initiated at a CUG codon located within a favourable context (ACCCUGG at positions 354 to 359 for Moloney-MuLV). The possible function of gp85gag was investigated by expressing Moloney-MuLV and Friend-MuLV proviral DNA and mutants deficient for gp85gag synthesis in mouse and rat cells. The results indicate that the gp85gag protein probably facilitates the spread of virus infection in tissue culture.

Inhibition of deoxyribonucleases by phosphorothioate groups in oligodeoxyribonucleotides

The Rp- and Sp-diastereomers of the phosphorothioate-containing oligonucleotide d[ApAp(S)ApA] have been synthesized. They and the tetramer d[ApApApA] were tested as substrates for staphylococcal nuclease, DNase II and spleen phosphodiesterase. For digestions with DNase I these oligonucleotides were converted to the 5'-phosphorylated derivates. The reactions with the nucleases were analysed by HPLC. The phosphorothioate groups of both diastereomers were resistant to the action of staphylococcal nuclease, DNase I and DNase II. While the phosphorothioate group of the Rp-diastereomer was resistant to the action of spleen phosphodiesterase, the Sp-diastereomer was hydrolysed at an estimated rate 1/100 the rate of cleavage of the unmodified tetramer. The presence of the phosphorothioate group in the center of the molecule affected the rate of hydrolysis of neighbouring phosphate groups for some enzymes. In particular, very slow release of 3'-dAMP from the Rp-diastereomer occurred on incubation with staphylococcal nuclease but the Sp-diastereomer was completely resistant. DNase II produced 3'-dAMP quite rapidly from both diastereomers of d[ApAp(S)ApA] and DNase I released 5'-dAMP from both diastereomers of d[pApAp(S)ApA] only slowly.

Prolactin upstream factor I mediates cell-specific transcription

DNA sequence-specific chromatography was used to purify prolactin upstream factor I (PUF-I) approximately 10,000- to 20,000-fold from rat GH3 cells. The purified transcription factor reconstituted enhanced pituitary-specific prolactin RNA synthesis in nonpituitary in vitro transcription assays. In vitro mutagenesis demonstrated that the capacity to stimulate prolactin gene transcription was directly correlated with PUF-I binding to an A+T-rich region located from -63 to -36 in the prolactin 5'-flanking DNA. We propose that PUF-I is a critical modulator of transcriptional activity in pituitary cells and has a central role in the stimulation of prolactin gene transcription in the mammalian pituitary lactotroph.

The lactose carrier of Klebsiella pneumoniae M5a1; the physiology of transport and the nucleotide sequence of the lacY gene

A comparison has been made between the physiology and amino acid sequence of the lactose carriers of Klebsiella pneumoniae M5a1 and Escherichia coli K-12. The membrane transport of lactose was much weaker in Klebsiella than in E. coli. On the other hand o-nitrophenylgalactoside uptake by Klebsiella was distinctly greater than with E. coli. In spite of the differences in sugar transport between the two organisms, the amino acid sequences of the respective lactose carriers were remarkably similar (60% of the amino acids are identical).

Direct sequencing of polymerase chain reaction amplified DNA fragments through the incorporation of deoxynucleoside alpha-thiotriphosphates

The direct sequencing of DNA generated by the polynucleotide chain reaction, via the incorporation of phosphorothioate nucleotides and followed by treatment with an alkylating reagent that cleaves specifically at the phosphorothioate positions, is described. The Taq polymerase used in the amplification reaction incorporates the Sp-diastereomer of the deoxynucleoside 5'-O-(1-thiotriphosphates) as efficiently as the natural nucleotides. Chemical degradation of the phosphorothioate-containing DNA fragment can be performed with either 2-iodoethanol or 2,3-epoxy-1-propanol. The higher reactivity of 2,3-epoxy-1-propanol allows less reagent to be used to obtain the same amount of degradation as with 2-iodoethanol.

A mutation in the 530 loop of Escherichia coli 16S ribosomal RNA causes resistance to streptomycin

Oligonucleotide-directed mutagenesis was used to introduce an A to C transversion at position 523 in the 16S ribosomal RNA gene of Escherichia coli rrnB operon cloned in plasmid pKK3535. E. coli cells transformed with the mutated plasmid were resistant to streptomycin. The mutated ribosomes isolated from these cells were not stimulated by streptomycin to misread the message in a poly(U)-directed assay. They were also restrictive to the stimulation of misreading by other error-promoting related aminoglycoside antibiotics such as neomycin, kanamycin or gentamicin, which do not compete for the streptomycin binding site. The 530 loop where the mutation in the 16S rRNA is located has been mapped at the external surface of the 30S subunit, and is therefore distal from the streptomycin binding site at the subunit interface. Our results support the conclusion that the mutation at position 523 in the 16S rRNA does not interfere with the binding of streptomycin, but prevents the drug from inducing conformational changes in the 530 loop which account for its miscoding effect. Since this effect primarily results from a perturbation of the translational proofreading control, our results also provide evidence that the 530 loop of the 16S rRNA is involved in this accuracy control.

Substitution of murine for human CD4 residues identifies amino acids critical for HIV-gp120 binding

Human CD4 is the receptor for the gp120 envelope glycoprotein of human immunodeficiency virus and is essential for virus entry into the host cell. Sequence analysis of CD4 has suggested an evolutionary origin from a structure with four immunoglobulin-related domains. Only the two NH2-terminal domains are required to mediate gp120 binding. The extracellular segment of murine CD4 has an overall 50% identity with its human counterpart at the amino-acid level, but fails to bind gp120. To define those residues of human CD4 critical for gp120 binding, we have taken advantage of this species difference and substituted all non-conserved murine for human CD4 residues between amino-acid positions 27-167. We used oligonucleotide-directed mutagenesis to create each of 16 individual mutant human CD4 molecules containing from 1-4 amino-acid substitutions. Introduction of as few as three amino acids into corresponding positions of human CD4 abrogates gp120 binding. Furthermore, these critical residues are located in domain I with a contribution from domain II. Modelling studies using the three-dimensional coordinates of the V kappa Bence-Jones REI homodimer localize the site in domain I to the C" beta strand within CDR2 but projecting away from the homologues of principle antigen-binding regions CDR 1 and 3.

Mechanism of adenylate kinase. Histidine-36 is not directly involved in catalysis, but protects cysteine-25 and stabilizes the tertiary structure

Several previous reports on muscle adenylate kinase (AK) have suggested that histidine-36 (His-36) is located in the binding site of adenosine 5'-triphosphate (ATP) and is involved in catalysis. We have tested the role of His-36 using site-specific mutagenesis on chicken muscle AK expressed in Escherichia coli. Three mutant proteins (H36Q, H36N, and H36G) were obtained by substituting His-36 with glutamine, asparagine, and glycine, respectively. Steady-state kinetic studies showed that the mutants have similar kinetic properties to those of the wild-type (WT) AK, which suggested that His-36 is not directly involved in catalysis. However, His-36 is likely to interact with or protect cysteine-25 (Cys-25) on the basis of the following evidence: The crystal structure of porcine muscle AK revealed a close proximity between His-36 and Cys-25; the mutants were unstable during purification (the order of stability was WT greater than H36Q greater than H36N greater than H36G); the H36G mutant readily dimerized; the sulfhydryl groups of mutants became more reactive (WT less than H36Q less than H36N) toward 5,5'-dithiobis(2-nitrobenzoic acid). Furthermore, His-36 was found to stabilize the tertiary structure of AK on the basis of guanidine hydrochloride induced denaturation studies, which showed that the conformational stability decreases in the order WT greater than H36Q greater than H36N.(ABSTRACT TRUNCATED AT 250 WORDS)

DNA and RNA sequence determination based on phosphorothioate chemistry

The difference in reactivity between phosphate and phosphorothioate diesters is the basis of a chemical degradation scheme for the sequencing of DNA and RNA. The phosphorothioate groups are incorporated into the nucleic acid in four separate enzymatic reactions, with three of the natural nucleoside triphosphates and one alpha-thiotriphosphate in each reaction. Selective strand cleavage is achieved through alkylation to form the hydrolytically labile phosphorothioate triester. As an example, the sequence analysis is presented of M13 phage DNA and of RNA prepared by transcription with SP6 RNA polymerase.

Pig heart calpastatin: identification of repetitive domain structures and anomalous behavior in polyacrylamide gel electrophoresis

Isolation and nucleotide sequencing of the complementary DNA for pig heart calpastatin have been completed. The amino acid sequence of 713 residues predicted from the nucleotide sequence contains five domains, each composed of approximately 140 amino acid residues. A unique N-terminal domain is followed by four mutually homologous domains. The best fit alignment of these four domains gives residue identities between any two domains of 22.5-36.0%. The analysis of the sequence similarities by several methods also suggests the existence of additional shorter repeats at intervals of 60-80 residues. The calculated molecular weight of pig calpastatin of 713 amino acid residues (Mr 77,122) is significantly lower than the value of purified pig heart calpastatin (Mr 107,000) estimated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate (SDS-PAGE). The expression of the calpastatin genes in Escherichia coli and the detection of the translation products of 713, 366, and 140 amino acid residues by the specific anti-calpastatin antibody indicate that the products always migrate considerably slow on SDS-PAGE, giving an average of 1.53 for the ratio of the molecular weight estimated by SDS-PAGE to the value calculated from the amino acid sequences. It is most likely that the discrepancy in the molecular weight is caused by an anomalous behavior of calpastatin in SDS-PAGE.

5'-3' exonucleases in phosphorothioate-based oligonucleotide-directed mutagenesis

The application of T7 and lambda exonuclease to phosphorothioate-based oligonucleotide-directed mutagenesis was investigated. Oligonucleotide primers designed to introduce single or double base mismatches, an insertion or a deletion (each of 16 bases) were annealed to M13 phage derivatives. Double stranded closed circular DNA (RF IV) containing phosphorothioate internucleotidic linkages in the (-)strand was prepared enzymatically from these templates. A nick was introduced into the (+)strand of the hetroduplex DNA. This nicked DNA (RF II) was subjected to treatment with T7 or lambda exonuclease. Both of these enzymes were able to degrade almost all of the viral (+)strand when presented with DNA containing one or two base mismatches. Repolymerisation of the DNA after the gapping reaction, followed by transfection into E. coli cells gave mutational efficiencies of up to 95%. In the case of RF II DNA prepared with insertion or deletion primers these exonucleases could only partially degrade the viral (+)strand but were nevertheless highly efficient in such mutagenesis experiments.

Strand specific cleavage of phosphorothioate-containing DNA by reaction with restriction endonucleases in the presence of ethidium bromide

A method for achieving strand specific nicking of DNA has been developed. Phosphorothioate groups were incorporated enzymatically into the (-)strand of M13 RF IV DNA. When such DNA is reacted with restriction endonucleases in the presence of ethidium bromide nicked DNA (RF II) is produced. All of the restriction enzymes tested linearised phosphorothioate-containing DNA in the absence of this dye. The strand specificity of the reaction was investigated by employing the ethidium bromide mediated nicking reaction in the phosphorothioate-based oligonucleotide-directed mutagenesis method. The mutational efficiencies obtained were in the region of 64-89%, indicating that these restriction enzymes hydrolyse the phosphodiester bond at the cleavage site of the unsubstituted (+)strand.

Characterisation and nucleotide sequence of ogt, the O6-alkylguanine-DNA-alkyltransferase gene of E. coli

The plasmid pO61 that was isolated from an E. coli genomic DNA library and codes for O6-alkylguanine (O6AG) DNA alkyltransferase (ATase) activity (1) has been further characterised. Subclones of the 9 Kb insert of pO61 showed that the ATase activity was encoded in a 2Kb Pst1 fragment but a partial restriction endonuclease map of this was different to that of the E. coli ada gene that codes for O6-AG and alkylphosphotriester dual ATase protein. Fluorographic analyses confirmed that the molecular weight of the pO61-encoded ATase was 19KDa i.e. similar to that of the O6AG ATase function that is cleaved from the 39KDa ada protein but rabbit polyclonal antibodies to the latter reacted only very weakly with the pO61-encoded protein. A different set of hybridisation signals was produced when E. coli DNA, which had been digested with a variety of restriction endonucleases was probed with 2Kb Pst 1 fragment or the ada gene. These results provided evidence for the existence of a second ATase gene in E. coli. The 2Kb Pst-1 fragment of pO61 was therefore sequenced and an open reading frame (ORF) that would give rise to a 19KDa protein was identified. The derived amino acid sequence of this showed a 93 residue region with 49% homology with the O6AG ATase region of the ada protein and had a pentamer and a heptamer of identical sequence separated by 34 amino acids in both proteins. The pentamer included the alkyl accepting cysteine residue of the ada O6AG ATase. The hydrophobic domains were similarly distributed in both proteins. Shine-Dalgarno, -10 and -35 sequences were identified and the origin of transcription was located by primer extension and S1 nuclease mapping. The amino-terminal amino acid sequence of the protein was as predicted from the ORF.

Site-directed mutagenesis of hepatitis B surface antigen sequence at codon 160 from arginine to lysine for conversion of subtypic determinant from r to w

Site-directed mutagenesis from G to A was induced at nucleotide 479 in the S gene of hepatitis B virus DNA, cloned from an individual carrying the surface antigen of subtype ayr. HepG2 cells were transfected with the plasmid DNA containing the mutant. They produced surface antigen of subtype ayw, unlike HepG2 cells harboring the parent viral DNA that produced surface antigen of subtype ayr. These results indicate that a point mutation from G to A at nucleotide 479 in the S gene, changing codon 160 for arginine to that for lysine, can convert the subtypic determinant of hepatitis B surface antigen from r to its allelic determinant w.

Inhibition of restriction endonuclease Nci I cleavage by phosphorothioate groups and its application to oligonucleotide-directed mutagenesis

M13 RF IV DNA where phosphorothioate groups are incorporated at restriction endonuclease Nci I recognition sites in the (-)strand is efficiently nicked by the action of this enzyme. Incubation of such nicked DNA with exonuclease III produces gapped DNA. The gap can be filled by reaction with deoxynucleoside triphosphates and DNA polymerase I. When this sequence of reactions is performed with DNA containing a mismatch oligonucleotide primer in the (-)-strand mutational frequencies of 70-90% can be obtained upon transformation. The general nature of this methodology has been further shown to be applicable to other restriction enzymes such as Hind II, Pst I and Fsp I. The mutational frequency obtained using these enzymes is between 40-80% mainly because of less efficient nicking and gapping. Studies on inhibition of Nci I cleavage show that in addition to a phosphorothioate group at the position of cleavage an additional group in the 5'-neighbouring position is necessary for complete inhibition.

Phosphorothioate-modified oligodeoxyribonucleotides. III. NMR and UV spectroscopic studies of the Rp-Rp, Sp-Sp, and Rp-Sp duplexes, [d(GGSAATTCC)]2, derived from diastereomeric O-ethyl phosphorothioates

2D-NOE and 1H NMR chemical shift data obtained for the title oligonucleotides were compared with similar data previously reported [Broido et al. (1985) Eur. J. Biochem. 150, 117-128] for the unmodified "parent" structure, [d(GGAATTCC)]2. The spectroscopically detectable structural perturbations caused by replacement of phosphate oxygen with sulfur were mostly localized within the GsA moiety, and were greater for the Rp configuration wherein sulfur is oriented into the major groove of the B-helix. UV-derived Tm measurements gave the following order of stability for the duplexes in 0.4 M NaCl: unmodified (33.9 +/- 0.1 degrees C) approximately Sp-Sp (34.1 degrees C) greater than Rp-Rp (31.7 degrees C). The title compounds were prepared by a new and convenient synthetic route which utilized HPLC to separate the diastereomeric O-ethyl phosphorothioate precursors, (Rp)- and (Sp)-d[GG(S,Et)AATTCC], for subsequent de-ethylation by ammonia in water.

Site-directed mutagenesis

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