Oligonucleotide-directed mutagenesis using M13-derived vectors: an efficient and general procedure for the production of point mutations in any fragment of DNA

Studies on the mechanism of membrane fusion: site-specific mutagenesis of the hemagglutinin of influenza virus

Oligonucleotide-directed mutagenesis of a cDNA encoding the hemagglutinin of influenza virus has been used to introduce single base changes into the sequence that codes for the conserved apolar "fusion peptide" at the amino-terminus of the HA2 subunit. The mutant sequences replaced the wild-type gene in SV40-HA recombinant virus vectors, and the altered HA proteins were expressed in simian cells. Three mutants have been constructed that introduce single, nonconservative amino acid changes in the fusion peptide, and three fusion phenotypes were observed: substitution of glutamic acid for the glycine residue at the amino-terminus of HA2 abolished all fusion activity; substitution of glutamic acid for the glycine residue at position 4 in HA2 raised the threshold pH and decreased the efficiency of fusion; and, finally, extension of the hydrophobic stretch by replacement of the glutamic acid at position 11 with glycine yielded a mutant protein that induced fusion of erythrocytes with cells with the same efficiency and pH profile as the wild-type protein. However, the ability of this mutant to induce polykaryon formation was greatly impaired. Nevertheless, all the mutant proteins underwent a pH-dependent conformational change and bound to liposomes. These results are discussed in terms of the mechanism of HA-induced membrane fusion.

The rapid generation of oligonucleotide-directed mutations at high frequency using phosphorothioate-modified DNA

M13 RF IV DNA may be prepared in vitro to contain phosphorothioate-modified internucleotidic linkages in the (-)strand only. Certain restriction enzymes react with this modified DNA to hydrolyze the (+)strand exclusively when a phosphorothioate linkage occurs at the normal cleavage point in the (-)strand. The reaction of Pvu I with M13mp2 RF IV DNA containing dCMPS residues in the (-)strand is of this type, and is exploited to allow subsequent digestion with exonuclease III of a portion of the (+)strand opposite different mutagenic mismatched oligonucleotide primers. Two methods are described by which this approach has been used to produce mutations in M13mp2 phage DNA with high efficiency as a result of simple and rapid in vitro manipulations. Plaques containing mutant phage in a genetically-pure form are obtained at a frequency of 40-66%, allowing their characterisation directly by sequence analysis without prior screening and plaque purification. The wide applicability of this approach is discussed.

Synthesis and expression of a human growth hormone (somatotropin) gene mutated to change cysteine-165 to alanine

We have mutated a synthetic human growth hormone (hGH) gene specifically at the codon for Cys-165 to a codon for Ala by replacement of synthetic deoxyoligonucleotides corresponding to this site. This modification prevented the formation of a disulfide bond between Cys-53 and Cys-165 in the hGH molecule. This mutated protein, [Ala165]hGH was expressed at the same level as the intact hGH, 4 X 10(5) molecules per cell under the control of the tryptophan promoter in Escherichia coli, and retained similar immunological activity to intact hGH. The limited digestion pattern of the mutated protein with human plasmin suggests that the tertiary structure of [Ala165]hGH resembles to that of the intact hGH molecule. [Ala165]hGH revealed full biological activity as examined by the body weight increase of hypophysectomized rats.

Improved hybridization assays employing tailed oligonucleotide probes: a direct comparison with 5'-end-labeled oligonucleotide probes and nick-translated plasmid probes

Terminal deoxynucleotidyl transferase was used to add labeled dAMP residues to the 3' end of oligonucleotide probes that hybridize to the 5' end of the neomycin phosphotransferase II gene. Southern hybridization conditions were described in which the sensitivity per unit of exposure time was about 30-fold greater for the tailed probe as compared to the 5'-end-labeled probe. The tailed oligonucleotide probe had the sensitivity per unit of exposure time comparable to that of a nick-translated probe of high specific activity: in 3 h of autoradiographic exposure both easily detected an amount of target equivalent to a single-copy gene in 10 micrograms of human DNA. The thermal dissociation profiles of 5'-end-labeled and tailed oligonucleotide probes were virtually identical and the tailed oligonucleotide probe was as allele specific as the 5'-end-labeled oligonucleotide probe. The useful lifetime of a 32P-tailed probe was about 1-2 weeks. Finally, by adding 50 35S-labeled nucleotides to the 3' end, we prepared a stable oligonucleotide probe with a sensitivity per unit of exposure time comparable to that of the unstable 5'-32P-labeled oligonucleotide probe.

Saccharomyces cerevisiae CYC1 mRNA 5'-end positioning: analysis by in vitro mutagenesis, using synthetic duplexes with random mismatch base pairs

Expression of the Saccharomyces cerevisiae CYC1 gene produces mRNA with more than 20 different 5' ends. A derivative of the CYC1 gene (CYC1-157) was constructed with a deletion of a portion of the CYC1 5'-noncoding region, which includes the sites at which many of the CYC1 mRNAs 5' ends map. A 54-mer double-stranded oligonucleotide homologous with the deleted sequence of CYC1-157 and which included a low level of random base pair mismatches (an average of two mismatches per duplex) was used to construct mutants of the CYC1 gene and examine the role of the DNA sequence at and immediately adjacent to the mRNA 5' ends in specifying their locations. The effect of these mutations on the site selection of mRNA 5' ends was examined by primer extension. Results indicate that there is a strong preference for 5' ends which align with an A residue (T in the template DNA strand) preceded by a short tract of pyrimidine residues.

DNA sequences regulating human beta globin gene expression

Human delta globin is expressed at approximately 1-2% of the level of human beta globin in erythroid cells despite the marked homology between these two globins. To determine the DNA sequences responsible for this effect, delta and beta globin genes and fusion products of these genes constructed in vitro were transfected and expressed in HeLa cells. The results indicate that when the small intervening sequence of the beta gene (beta IVS 1) is replaced by delta IVS 1, expression of the chimeric gene is the same as that of the normal beta globin gene. By contrast, when the large intervening sequence of the beta gene (beta IVS 2) is replaced by delta IVS 2, expression of the chimeric gene is markedly reduced. These results suggest that there are signals within IVS 2 of the delta and beta genes which affect their relative expression.

A single N-linked oligosaccharide at either of the two normal sites is sufficient for transport of vesicular stomatitis virus G protein to the cell surface

We investigated the role of glycosylation in intracellular transport and cell surface expression of the vesicular stomatitis virus glycoprotein (G) in cells expressing G protein from cloned cDNA. The individual contributions of the two asparagine-linked glycans of G protein to cell surface expression were assessed by site-directed mutagenesis of the coding sequence to eliminate one or the other or both of the glycosylation sites. One oligosaccharide at either position was sufficient for cell surface expression of G protein in transfected cells, and the rates of oligosaccharide processing were similar to the rate observed for wild-type protein. However, the nonglycosylated G protein synthesized when both glycosylation sites were eliminated did not reach the cell surface. This protein did appear to reach a Golgi-like region, as determined by indirect immunofluorescence microscopy, however, and was modified with palmitic acid. It was also apparently not subject to increased proteolytic breakdown.

cDNA of the immunoglobulin kappa chain of an Epstein-Barr virus-transformed human lymphoid cell line: partial sequence determination and bacterial expression

We report the isolation, nucleotide sequence determination, and bacterial expression of a partial cDNA for the immunoglobulin kappa chain from the Epstein-Barr virus-transformed human lymphoid cell line GM131. The cDNA, cloned in pBR322 by use of oligo(dG) X oligo(dC) tails, yields two Pst I fragments of 250 and 600 base pairs (bp). Various restriction enzyme fragments of the cDNA were subcloned in the vectors M13 mp10 and M13 mp11 for sequence analysis. As a result of instability of the 250-bp M13 subclones, the base sequence of the 250-bp Pst I fragment could not be determined. The 600-bp Pst I fragment contains coding sequences for part of the variable (V) region (residues 78-95) and all of the joining (J) (residues 96-108) and constant (C) regions (residues 109-212) and extends 148 bp into the 3' flanking region. Although the C- and 3'-flanking-region sequences are identical to germ-line sequences, the J-region sequence does not correspond to any of the five human germ-line J regions. The sequence is most similar to that of J4, with three base changes resulting in one silent mutation and two amino acid substitutions, at residues 103 (Lys----Tyr) and 106 (Ile---Met). The silent mutation appears to be the result of RNA splicing between the J and the C regions. The V-region sequence differs from published V-region germ-line sequences at several codons and from the more common amino acid sequences at two positions, residues 91 and 93. At these positions, histidine residues are found in place of the more common tyrosine and serine, respectively. None of the four amino acid substitutions observed for the GM131 kappa-chain are unique, suggesting that the changes, which most likely contribute to antigenic specificity, are compatible with antibody structure and function. The 600-bp Pst I fragment was subcloned in two prokaryotic expression vectors, pATH11 and pUC8. In both instances, a kappa-chain fusion protein detectable by immunoblotting was produced.

Incorporation of a charged amino acid into the membrane-spanning domain blocks cell surface transport but not membrane anchoring of a viral glycoprotein

The membrane-spanning domain of the vesicular stomatitis virus glycoprotein (G protein) consists of a continuous stretch of 20 uncharged and mostly hydrophobic amino acids. We examined the effects of two mutations which change the amino acid sequence in this domain. These mutations were generated by oligonucleotide-directed mutagenesis of a cDNA clone encoding the G protein, and the altered G proteins were then expressed in animal cells. Replacement of an isoleucine residue in the center of this domain with a strongly polar but uncharged amino acid (glutamine) had no effect on membrane anchoring or transport of the protein to the cell surface. Replacement of this same isoleucine residue with a charged amino acid (arginine) generated a G protein that still spanned intracellular membranes but was not transported efficiently to the cell surface. The protein accumulated in the Golgi region in about 50% of the cells, and about 20% of the cells had detectable protein levels in a punctate pattern on the cell surface. In the remaining cells the protein accumulated in a vesicular pattern throughout the cytoplasm. Models which might explain the abnormal behavior of this protein are discussed.

Glycosylation allows cell-surface transport of an anchored secretory protein

We have previously described the construction and expression of a hybrid gene encoding a membrane-anchored form of rat growth hormone. This protein is anchored in cellular membranes by a carboxy-terminal extension composed of the transmembrane and cytoplasmic domains of the vesicular stomatitis virus glycoprotein. The protein is transported efficiently to the Golgi apparatus but not to the cell surface. To examine the possibility that N-linked glycosylation might be required for protein transport to the cell surface, we created two mutant proteins (using in vitro mutagenesis) in which single amino acids at two random sites in anchored growth hormone were changed to generate consensus sequences required for addition of N-linked carbohydrate. These mutant proteins, and a protein with both glycosylation sites, were glycosylated and were transported to the cell surface. These results suggest that N-linked glycosylation can serve as a signal for protein transport to the cell surface.

Mutants and pseudorevertants of Moloney murine leukemia virus with alterations at the integration site

Soon after infection, retroviruses synthesize a DNA copy of the genomic RNA and insert that DNA into the cellular genome by recombination at inverted repeat sequences at the termini of the viral genome. We have generated mutations that alter one terminus of the genome of Moloney murine leukemia virus (M-MuLV). Some mutations did not prevent integration of the viral DNA even though the very terminal bases were disrupted. Other mutations had dramatic effects on the efficiency of infection; in these cases the formation of preintegrative DNA was normal but the establishment of the productive provirus was prevented. One of these defective mutants gave rise to a pseudorevertant which differed from the wild type but displayed normal infectivity. An unusual number of bases of viral DNA were removed during the integration reaction carried out by this virus.

First identification of an amber nonsense mutation in Schizosaccharomyces pombe: major differences in the efficiency of homologous versus heterologous yeast suppressor tRNA genes

In Saccharomyces cerevisiae ochre and opal, as well as amber mutations are known, whereas in the fission yeast Schizosaccharomyces pombe no amber alleles have been described. We have characterized trp1-566, an amber allele in the trp1 locus of S. pombe. The identification of trp1-566 as an amber allele is based on the following results: (a) The nonsense allele can be converted to an ochre allele by nitrosoguanidine mutagenesis. (b) trp1-566 is suppressed by a bona fide S. pombe amber suppressor tRNA, supSI. The supSI gene was obtained by primer-directed in vitro mutagenesis of a tRNASer from S. pombe. Unexpectedly, an S. cerevisiae amber suppressor tRNASer, supR21, transformed into S. pombe, failed to suppress trp1-566. Northern analysis of S. pombe transformants, containing supRL1 or S. cerevisiae tRNALeu or tRNATyr genes reveals that these genes are not transcribed in the fission yeast. As an additional tool for the analysis of nonsense mutations in S. pombe, we obtained by nitrosoguanidine mutagenesis two unlinked amber suppressor alleles, sup13 and sup14, which act on trp1-566.

Infectivity and in vitro mutagenesis of monomeric cDNA clones of citrus exocortis viroid indicates the site of processing of viroid precursors

Monomeric cDNA clones of citrus exocortis viroid (CEV) were constructed in the plasmid vector pSP6-4 and the infectivity of the clones plus in vitro-synthesized RNA transcripts determined by inoculation onto tomato seedlings. Infectivity was dependent on the site of the viroid molecule used for cloning and the orientation of the cDNA insert. Only the plus BamHI cDNA clone was infectious and produced progeny viroid with wild-type sequence at the region corresponding to the BamHI cloning site. Infectivity correlated with the terminal repetition of 11 nucleotides of viroid sequence, 5'GGATCCCCGGG 3', in the vector adjacent to the insert. The 11-nucleotide sequence lies within the highly conserved central region of viroids. Site-directed mutagenesis of a single nucleotide in the repeat at the 5'-end of the CEV insert to 5' GGATCCCC(T,A)GG 3' gave two point mutants. The two mutant CEV inserts, when excised from the vector, were not infectious. However, plasmid DNA and RNA transcripts from non-excised mutant CEV inserts were infectious. The progeny of one of these clones was examined and contained wild-type sequence. It was concluded that in vivo processing of longer-than-unit-length CEV occurs at one of three adjacent sites in the 11 nucleotide sequence and that the G nucleotide at position 97 is important for viroid replication.

Site-specific mutagenesis of Escherichia coli gltT yields a weak, glutamic acid-inserting ochre suppressor

Of all the Escherichia coli tRNA genes that can give rise to an amber or an ochre suppressor by a single-nucleotide mutation, only the tRNAGlu genes have not been observed to do so. A study of the relationship between the sequences of tRNAs and the codons they translate predicts that the ochre suppressor derived from tRNAGlu would function very poorly on the ribosome. We have used site-specific mutagenesis to create the gene for such a tRNA in order to test this prediction. We cloned the tRNAGlu-Suoc gene into a high copy number plasmid, under control of the lacUV5 promoter. The mutant tRNA suppresses both amber and ochre nonsense mutations. As predicted, it is less efficient than other suppressors expressed under similar conditions.

Adenovirus DNA replication in vitro: site-directed mutagenesis of the nuclear factor I binding site of the Ad2 origin

The template requirements for efficient adenovirus DNA replication were studied in vitro in a reconstituted system with cloned DNA fragments, containing the Ad2 origin region, as templates. Replication is enhanced by nuclear factor I, a cellular protein that binds specifically to the Ad2 origin. This stimulation is shown to be strongly dependent on the concentration of the adenovirus DNA binding protein. Using synthetic oligonucleotides we have constructed plasmids with base substitutions in the nuclear factor I binding region. Footprint analysis and competition filter binding studies show that two of the three small blocks of conserved nucleotides in this region are involved in the binding of nuclear factor I. The binding affinity can be influenced by the base composition of the degenerate region just outside these two blocks. In vitro initiation and DNA chain elongation experiments with the mutants demonstrate that binding of nuclear factor I to the Ad2 origin is necessary for stimulation. However, binding alone is not always sufficient since a mutation which only slightly disturbs binding is strongly impaired in stimulation of DNA replication by nuclear factor I.

Nucleotide sequence binding specificity of the LexA repressor of Escherichia coli K-12

The specificity of LexA protein binding was investigated by quantifying the repressibility of several mutant recA and lexA operator-promoter regions fused to the Escherichia coli galactokinase (galK) gene. The results of this analysis indicate that two sets of four nucleotides, one set at each end of the operator (terminal-nucleotide contacts), are most critical for repressor binding. In addition, our results suggest that the repressor-operator interaction is symmetric in nature, in that mutations at symmetrically equivalent positions in the recA operator have comparable effects on repressibility. The symmetry of this interaction justified reevaluation of the consensus sequence by half-site comparison, which yielded the half-site consensus (5')CTGTATAT. Although the first four positions of this sequence were most important, the last four were well conserved among binding sites and appeared to modulate repressor affinity. The role of the terminal-nucleotide contacts and the mechanism by which the internal sequences affected repressor binding are discussed.

Structural requirements of a membrane-spanning domain for protein anchoring and cell surface transport

The membrane-spanning domain of the vesicular stomatitis virus glycoprotein (G) contains 20 uncharged and mostly hydrophobic amino acids. We created DNAs specifying G proteins with shortened transmembrane domains, by oligonucleotide-directed mutagenesis. Expression of these DNAs showed that G proteins containing 18, 16, or 14 amino acids of the original transmembrane domain assumed a transmembrane configuration and were transported to the cell surface. G proteins containing only 12 or 8 amino acids of this domain also spanned intracellular membranes, but their transport was blocked within a Golgi-like region in the cell. A G protein completely lacking the membrane-spanning domain accumulated in the endoplasmic reticulum and was secreted slowly. These experiments indicate that the size of the transmembrane domain is critical not only for membrane anchoring, but also for normal cell surface transport.

Characterization of Drosophila transcription factors that activate the tandem promoters of the alcohol dehydrogenase gene

Fractionation of a nuclear extract derived from Drosophila tissue culture cells reveals the presence of multiple components involved in accurate transcription of both distal and proximal promoters of the alcohol dehydrogenase (Adh) gene. Transcription of deletion mutants indicates that a region between -24 and -85 upstream of the distal start site contains sequences required for RNA synthesis in vitro. Moreover, sequences that overlap this same upstream control region are specifically bound and protected from DNAase digestion by a promoter-specific transcription factor, Adf-1. Analysis of proximal promoter mutants identified multiple upstream elements that influence transcription, and DNAase footprint analysis detected three specific binding regions. Adf-1 binds at least one of these proximal promoter regions but interaction at this site is not specifically required for transcription. Our results suggest that multiple sequence-specific DNA binding proteins interact differentially with the proximal and distal promoters of Adh to activate transcription.

Mutation of NH2-terminal glycine of p60src prevents both myristoylation and morphological transformation

p60src, the transforming protein kinase of Rous sarcoma virus, contains the 14-carbon saturated fatty acid, myristic acid, linked through an amide bond to the alpha-amino group of its NH2-terminal glycine residue. Myristic acid is known to be attached to four other eukaryotic proteins. In each case the fatty acid is also linked through an amide bond to an NH2-terminal glycine. We have used oligonucleotide-directed mutagenesis to examine the amino acid specificity of the enzyme that myristoylates the NH2 terminus of these proteins. Replacement of the NH2-terminal glycine in p60src with either alanine or glutamic acid prevented myristoylation completely. This indicates that the myristoylating enzyme may have an absolute specificity for glycine. Strikingly, neither nonmyristoylated mutant src protein induced morphological transformation of infected cells, even though wild-type levels of phosphorylation of cellular proteins on tyrosine were observed in these cells. Since conversion of the NH2-terminal residue from glycine to alanine should have little effect on the conformation of p60src, the inability of this mutant p60src protein to induce morphological transformation suggests that the myristoyl moiety is essential for the transforming activity of the protein.

Improved oligonucleotide site-directed mutagenesis using M13 vectors

An improved method is described for the construction of mutations in M13 vectors using synthetic oligonucleotides. The DNA is first cloned into a novel M13 vector (based upon M13mp18 or M13mp19), which carries a genetic marker that can be selected against, such as an EcoK or EcoB site, or an amber mutation in an essential phage gene. In this "coupled priming" technique, one primer is used to construct the silent mutation of interest, and a second primer is used to eliminate the selectable marker on the minus strand. After primer extension and ligation, the heteroduplex DNA is transfected into a strain of E. coli which is repair deficient and selects against the plus strand marker. Over 50 mutants have been constructed with this approach, and the yields can be excellent (up to 70%). For the stepwise construction of mutations using separate rounds of mutagenesis, the EcoK and EcoB markers offer a particular advantage over the amber marker. They permit selection in each round, as it is possible to cycle between the two markers. However for construction of multiple mutations over a short region, long synthetic oligonucleotides with multiple mismatches to the template can offer an alternative strategy.

Incorporation of a charged amino acid into the membrane-spanning domain blocks cell surface transport but not membrane anchoring of a viral glycoprotein

The membrane-spanning domain of the vesicular stomatitis virus glycoprotein (G protein) consists of a continuous stretch of 20 uncharged and mostly hydrophobic amino acids. We examined the effects of two mutations which change the amino acid sequence in this domain. These mutations were generated by oligonucleotide-directed mutagenesis of a cDNA clone encoding the G protein, and the altered G proteins were then expressed in animal cells. Replacement of an isoleucine residue in the center of this domain with a strongly polar but uncharged amino acid (glutamine) had no effect on membrane anchoring or transport of the protein to the cell surface. Replacement of this same isoleucine residue with a charged amino acid (arginine) generated a G protein that still spanned intracellular membranes but was not transported efficiently to the cell surface. The protein accumulated in the Golgi region in about 50% of the cells, and about 20% of the cells had detectable protein levels in a punctate pattern on the cell surface. In the remaining cells the protein accumulated in a vesicular pattern throughout the cytoplasm. Models which might explain the abnormal behavior of this protein are discussed.

Oligonucleotide-directed mutagenesis by microscale 'shot-gun' gene synthesis

We describe a rapid and efficient microscale method for in vitro site-directed mutagenesis by gene synthesis. Mutants are constructed by "shot-gun ligation" of overlapping synthetic oligonucleotides yielding double stranded synthetic DNA of more than 120 nucleotides in length. The terminal oligonucleotides of the DNA segment to be synthesized are designed to create sticky ends complementary to unique restriction sites of a polylinker present in an M13 vector. The oligonucleotides are hybridized and ligated to the M13 vector without any purification of the synthetic DNA segment. After cloning, about half of the progeny from such shot-gun ligations contained the predicted sequence demonstrating the efficacy of this method for gene synthesis and its potential for the extensive mutational analysis of genes.

Redesigning trypsin: alteration of substrate specificity

A general method for modifying eukaryotic genes by site-specific mutagenesis and subsequent expression in mammalian cells was developed to study the relation between structure and function of the proteolytic enzyme trypsin. Glycine residues at positions 216 and 226 in the binding cavity of trypsin were replaced by alanine residues, resulting in three trypsin mutants. Computer graphic analysis suggested that these substitutions would differentially affect arginine and lysine substrate binding of the enzyme. Although the mutant enzymes were reduced in catalytic rate, they showed enhanced substrate specificity relative to the native enzyme. This increased specificity was achieved by the unexpected differential effects on the catalytic activity toward arginine and lysine substrates. Mutants containing alanine at position 226 exhibited an altered conformation that may be converted to a trypsin-like structure upon binding of a substrate analog.

Regulation of the expression of the tufB operon: DNA sequences directly involved in the stringent control

We have located the DNA sequence involved in the stringent control of the Escherichia coli tufB operon. Various deletion and insertion mutants of the promoter locus were constructed by in vitro mutagenesis, and their response to guanosine-5'-diphosphate-3'-diphosphate (ppGpp) was examined in a cell-free transcription system consisting of purified RNA polymerase holoenzyme. The nucleotide sequence (GpCpGpC) from positions -7 to -4 (designating the initiation site of mRNA as position +1) is responsible for the selective inhibition by ppGpp of tufB transcription. Point mutations were then constructed in which each one of the above four nucleotides was replaced by an A or T residue and tested for their response to ppGpp in the in vitro transcription system. The results indicated that the alteration of any nucleotide in the GpCpGpC sequence leads to the loss of the stringent response.

Does unpaired adenosine-66 from helix II of Escherichia coli 5S RNA bind to protein L18?

Adenosine-66 is unpaired within helix II of Escherichia coli 5S RNA and lies in the binding site of ribosomal protein L18. It has been proposed as a recognition site for protein L18. We have investigated further the structural importance of this nucleotide by deleting it. The 5S RNA gene of the rrnB operon of E. coli was subjected to primer-directed mutagenesis. To produce the deletion it was necessary to use simultaneously the mutagenic dodecamer dCGGCGCACGGCG and the universal M13 primer dCCCAGTCACGACGTT, and to employ forced annealing conditions. The mutated gene was expressed in an overproducing plasmid derived from pKK3535. Binding studies with protein L18 revealed that the protein bound much more weakly to the mutated 5S RNA. We consider the most likely explanation of this result is that L18 interacts with adenosine-66, and we present a tentative model for an interaction between the unpaired adenosine and the adjacent guanosine-67 of the RNA and glutamine-19 of the protein L18.

A simple and efficient method for chemical mutagenesis of DNA

A simple and efficient procedure for the generation of random GC to AT transition mutations in a specific DNA segment is described. A restriction fragment is inserted in each orientation into an M13 vector, single-stranded virion DNA from each recombinant phage is treated with methoxylamine, and, after reannealing of the mutagenized strands, a double-stranded restriction fragment is obtained. This methoxylamine-derivatized DNA segment is then joined with linearized M13 RF DNA, competent E. coli is transfected, and mutations are directly identified by sequencing of the phage DNA. Using this technique, single and double nucleotide substitutions were generated at a frequency greater than 50% in a 56-base pair segment of the signal codons of the TEM beta-lactamase.

Duplications of a mutated simian virus 40 enhancer restore its activity

Enhancers are cis-acting control elements which can stimulate at a distance the activity of a variety of eukaryotic promoters. First identified as a repeated 72 base pair (bp) sequence upstream of the simian virus 40 (SV40) early gene promoter, enhancers have since been shown to be associated with numerous other viral and cellular genes. Although there are no strong homologies between the sequences of different enhancers, a number of short and degenerate consensus sequences have been identified, including the 'core' element GTGGA/TA/TA/TG and stretches of alternating purines and pyrimidines which may have the potential to form left-handed Z DNA. To study the functional significance of two alternating purine and pyrimidine sequences in the SV40 enhancer, we have introduced various combinations of point mutations into a modified SV40 enhancer which contained only one copy of the 72 bp element (W.H., Y.G., A. Nordheim and A. Rich, unpublished results); one of these combinations impaired both the activity of the enhancer and growth of SV40. We describe here the structure of 18 revertants of this mutant and suggest that in each of the 18 revertants, the defects of the original mutant have been overcome by simple tandem duplications in the enhancer region, all of which include the 'core' element.

Is sequence conservation in interferons due to selection for functional proteins?

The human alpha-interferon (IFN-alpha) gene family consists of at least 14 potentially functional non-allelic members; the amino acid sequences they encode differ from each other by up to approximately 20% of their residues. Human IFN-beta, which is encoded by a single gene, is distantly related to the IFN-alpha family; it differs in 67% of its residues from IFN-alpha 2. There is considerable evidence that IFN-alpha and -beta compete for the same receptors on their target cells. Comparison of 14 non-allelic human IFN-alpha sequences and the IFN-beta sequence has revealed that 37 of 166 residues are completely conserved and that several of these are arranged in clusters, for example at positions 29-33, 47-50 and 136-150. It is commonly held that evolutionary conservation of amino acids indicates that the residues in question are essential for function. To test this hypothesis in the case of IFNs, we have introduced single site-directed point mutations into the strictly conserved codons 48 and 49 of the IFN-alpha 2 gene which form part of the longest uninterrupted cluster (position 47-50). We report here that the mutant proteins, containing Tyr, Ser and Cys instead of Phe48, or His instead of Gln49, have biological activities indistinguishable from those of wild-type IFN-alpha. In addition, when Glu62, a residue conserved in all known alpha and beta IFNs of man, mouse and cattle, was replaced by Lys, antiviral activity remained unchanged.

Altered Cro repressors from engineered mutagenesis of a synthetic cro gene

A portion of the gene coding for the Cro repressor protein of bacteriophage lambda has been chemically synthesized, incorporating base pair changes that generate restriction endonuclease sites without altering the amino acid coding sequence. These restriction endonuclease sites were used to remove small segments of the synthetic cro gene and the segments were replaced with duplexes carrying desired mutations. Altered Cro proteins produced by mutants constructed in this manner were then assayed for binding to lambda operator OR3 in vivo. Mutations directed into the region of the cro gene encoding the alpha-3 helix produced altered Cro proteins with a range of affinities for operator DNA. These changes suggest which amino acids play an important role in Cro-OR3 complex formation.

Point mutations in the 5' ICR and anticodon region of a Drosophila tRNAArg gene decrease in vitro transcription

We have examined the effects of various nucleotide substitutions in a Drosophila tRNAArg gene on in vitro transcription and stable transcription complex formation in Drosophila KcO and HeLa cell extracts. Substitutions in positions encoding the invariant G18 and G19 residues resulted in decreased transcription, however, the moderate decreases indicate that these nucleotides are not obligatory promoter recognition sites. An A21 to C21 mutation had no effect on transcription levels using homologous extract however, this mutant displayed decreased transcriptional abilities in HeLa cell extract. Nucleotide substitutions within the sequence encoding the anticodon led to a decrease in the transcription activity but not in the ability to form a stable transcription complex.

Synthesis in E. coli of alpha 1-antitrypsin variants of therapeutic potential for emphysema and thrombosis

The primary function of alpha 1-antitrypsin (alpha 1-AT), an antiprotease produced by the liver, is the inhibition of neutrophil elastase, a protease capable of hydrolysing most connective tissue components. The importance of alpha 1-AT is demonstrated by the high incidence of early-onset emphysema in individuals with hereditary alpha 1-AT deficiency (Type PiZZ), in whom serum levels of alpha 1-AT are 10-20% of normal. Oxidants in tobacco smoke can inactivate alpha 1-AT in vitro, and studies have shown that alpha 1-AT from the lungs of individuals who smoke cigarettes may also be partially inactivated, perhaps explaining the high incidence of emphysema associated with cigarette smoking. Oxidative inactivation is probably due to modification of the Met residue (Met358) at the P1 subsite position of the elastase binding site of the protein. To study the possibility of modulating the biological properties of alpha 1-AT, we have introduced selected sequence modifications at the reactive site by in vitro mutation of a cloned alpha 1-AT complementary DNA. We describe here the characterization of two alpha 1-AT analogues produced in Escherichia coli. The first, alpha 1-AT(Met385----Val), is not only fully active as an elastase inhibitor but is also resistant to oxidative inactivation. The other, alpha 1-AT(Met358----Arg), no longer inhibits elastase but is an efficient thrombin inhibitor. The active site of the latter is identical to that of the alpha 1-AT (Pittsburgh) variant, which was associated with a fatal bleeding disorder.

M13 clones carrying point mutations: identification by solution hybridization

A solution hybridization procedure for the rapid identification of M13 clones carrying a particular sequence is described. The method, which employs a radiolabeled oligonucleotide probe, can discriminate between sequences which differ by only a single base, and can therefore be used for the identification of mutant sequences created by oligonucleotide-directed mutagenesis. Samples of phage-containing supernatant from cultures of M13-infected Escherichia coli are incubated with radiolabeled probe in the presence of sodium dodecyl sulfate. The mixtures are then subjected to agarose gel electrophoresis to separate hybrid molecules from unbound probe and hybridization is detected by autoradiography. This solution hybridization procedure is quicker and more convenient than membrane hybridization and has the added advantage that more than one probe can be used on a given gel.

A genetic enrichment for mutations constructed by oligodeoxynucleotide-directed mutagenesis

A genetic enrichment procedure for mutations constructed by oligodeoxynucleotide(oligo)-directed mutagenesis of DNA cloned in M13mp vectors is described. The procedure uses an M13 vector that contains the cloned target DNA and amber (am) mutations within the phage genes I and II. This vector cannot replicate in a suppressor-free (sup degrees) bacterial strain. A gapped heteroduplex is formed by annealing portions of a complementary (-)strand containing wild-type copies of genes I and II to the am-containing template (+)strand. The oligo is annealed to the single-stranded (ss) region and the remaining gaps and nicks are repaired enzymatically to form a closed circular heteroduplex structure. By transfecting the DNA into a sup degrees host we promote the propagation of heteroduplexes with the oligo-containing (-)strand since only this construction contains the wild-type copies of genes I and II. This procedure eliminates the need for any physical separation of the covalently closed circular DNA that contains the oligo from the ss template. Using this technique we have constructed 17 point mutations with mutation frequencies ranging from 2-20% for single base changes and from 0.3-9% for multiple base changes. In addition, we found that the mutation frequencies were affected by the state of DNA methylation in the (+) and (-)strands.

Plasmids pEMBLY: new single-stranded shuttle vectors for the recovery and analysis of yeast DNA sequences

We describe the construction and properties of pEMBLY plasmids. They belong to a new family of yeast shuttle vectors which are derived from plasmid vector pEMBL9 and offer the following improvement: relatively small size; large number of cloning sites; screening for insert-containing plasmids on indicator plates; different combinations of genes which complement auxotrophic deficiencies and sequences that support DNA replication in Saccharomyces cerevisiae; and ability to isolate the plasmid DNA in single-stranded (ss) form. The yeast S. cerevisiae can be efficiently transformed by these plasmids in both the ss and double-stranded (ds) forms. Finally, the presence of the phage f1 intergenic region allows one to obtain the cloned sequences in the ss form upon infection with the wild-type ss phage [Dotto et al., Virology 114 (1981) 463-473].

Cassette mutagenesis: an efficient method for generation of multiple mutations at defined sites

A method is described for the efficient insertion of mutagenic oligodeoxynucleotide cassettes which allow saturation of a target amino acid codon with multiple mutations. Restriction sites are introduced by oligonucleotide-directed mutagenesis procedures to flank closely the target codon in the plasmid containing the gene. The restriction sites to be introduced are chosen based on their uniqueness to the plasmid, proximity to the target codon and conservation of the final amino acid coding sequence. The flanking restriction sites in the plasmid are digested with the cognate restriction enzymes, and short synthetic duplex DNA cassettes (10-25 bp) are inserted. The mutagenic cassette is designed to restore fully the wild-type coding sequence, except over the target codon, and to eliminate one or both restriction sites. Elimination of a restriction site facilitates selection of clones containing the mutagenic oligodeoxynucleotide cassette. To make the cassettes, single-stranded oligodeoxynucleotides and their complements are synthesized in separate pools containing different codons over the target. This method has been successfully applied to generate 19 amino acid substitutions at position 222 in the subtilisin protein sequence.

The nusA recognition site. Alteration in its sequence or position relative to upstream translation interferes with the action of the N antitermination function of phage lambda

The phage lambda transcription antitermination protein, pN, acts with host factors, Nus, at sites on the phage genome, nut, to render RNA polymerase resistant to subsequent downstream termination signals. The NusA protein appears to recognize a seven to eight base-pair consensus sequence (5'Py-G-C-T-C-T-T(T)3') called boxA that is found in the promoter-proximal part of the nut region. Two types of change within or near the boxA sequence in the nutR region are shown to interfere with pN-mediated antitermination of transcription that has initiated at the upstream pR promoter. (1) A change of one base-pair (from G to T at the second position) in the boxA sequence significantly reduces pN action. (2) We prove that a frameshift mutation, cro delta 62, at the end of the gene promoter-proximal to the lambda nutR region, interferes with the pN antitermination reaction by allowing translation to proceed beyond cro into the nutR region. Using a series of plasmid constructions, we now show that the inhibition of antitermination caused by the cro delta 62 mutation can be suppressed when translation is terminated upstream from this mutation.

The complete pattern of mutagenesis arising from the repair of site-specific psoralen crosslinks: analysis by oligonucleotide hybridization

Psoralen crosslinks were site-specifically placed in plasmid pBR322 near the BamHI site in the tet gene by enzymatically inserting mercurated nucleotides and reacting at the target site with a sulfhydryl-containing psoralen. The damaged plasmid was repaired in SOS-induced E. coli cells. Mutants were detected by colony hybridization to oligonucleotides in the target region, and their sequences were determined. The mutations are all base substitutions, 80% transitions and 20% transversions, similar to the mutations previously identified by the loss of tetracycline resistance. However, the mutation sites detected by a physical method, unconstrained by phenotypic changes, follow a broader distribution than those identified genetically. They occur primarily at favored psoralen crosslinking sites, where T-T and T-C interstrand crosslinks can be formed. A majority of these mutations are silent.

The gapped duplex DNA approach to oligonucleotide-directed mutation construction

A simple and efficient method is described to introduce structurally pre-determined mutations into recombinant genomes of filamentous phage M13. The method rests on gapped duplex DNA (gdDNA) molecules of the phage M13 genome as the key intermediate. In this gdDNA, the (+) and the (shorter) (-) strand carry different genetic markers in such a way, that a rigorous selection can be applied for phage carrying the markers of the (-) strand. For introduction of the mutation, a synthetic oligonucleotide with partial homology to a target site within the single stranded DNA region is annealed to the gdDNA. The oligonucleotide subsequently becomes part of the (-) strand by enzymatic DNA gap filling and sealing. This physical linkage is preserved at the genetic level after transfection of a recipient E.coli strain deficient in DNA mismatch correction, so that the synthetic marker can be selected from the phage progeny independent from its potential phenotype. It is demonstrated that by this method mutants can be constructed with marker yields in excess of 70%.

Oligonucleotide-directed mutagenesis: a simple method using two oligonucleotide primers and a single-stranded DNA template

This paper presents a simple and efficient method for oligonucleotide-directed mutagenesis using vectors derived from single-stranded phage. This modification of our previously published procedure (Zoller and Smith, 1982) features the use of two primers, one of which is a standard M13 sequencing primer and the other is the mutagenic oligonucleotide. Both primers are simultaneously annealed to single-stranded template DNA, extended by DNA polymerase I (large fragment), and ligated together to form a mutant wild-type gapped heteroduplex. Escherichia coli is transformed directly with this DNA; the isolation of covalently closed circular DNA as in our previous report is not necessary. Mutants are identified by plaque lift hybridization using the mutagenic oligonucleotide as a probe. As an example of the method, a heptadecanucleotide was used to create a T----G transversion in the MATa gene of Saccharomyces cerevisiae cloned into the vector M13mp5. The efficiency of mutagenesis was approximately 50%. Production of the desired mutation was verified by DNA sequencing. The same procedure has been used without modification to create insertions of restriction sites as well as specific deletions of 500 bases.

Oligonucleotide-directed mutagenesis using plasmid DNA templates and two primers

Oligonucleotide-directed mutagenesis using plasmid vectors has been simplified by introducing two changes to the previous method. First, template preparation has been simplified by using the covalently closed circular plasmid DNA directly for mutagenesis, eliminating the need for a wholly or partially single-stranded circular DNA template. Second, two primers are used, eliminating the need for producing the covalently closed molecule during in vitro replication. The advantages of the approach are discussed.