Genetic assay for small fragments of bacteriophage phi X174 deoxyribonucleic acid

Inverse PCR for Site-Directed Mutagenesis

Inverse PCR is a powerful tool for the rapid introduction of desired mutations at desired positions in a circular double-stranded DNA sequence. In this technique, custom-designed mutant primers oriented in the inverse direction are used to amplify the entire circular template with incorporation of the required mutation(s). By careful primer design, it can be used to perform such diverse modifications as the introduction of point or multiple mutations, the insertion of new sequences, and even sequence deletions. Three primer formats are commonly used, nonoverlapping, partially overlapping, and fully overlapping primers, and here we describe the use of nonoverlapping primers for introduction of a point mutation. Use of such a primer setup in the PCR, with one of the primers containing the desired mismatch mutation, results in the amplification of a linear, double-stranded, mutated product. Methylated template DNA is removed from the non-methylated PCR product by DpnI digestion, and the PCR product is then phosphorylated by polynucleotide kinase treatment before being recircularized by ligation and transformed to E. coli. This relatively simple site-directed mutagenesis procedure is of major importance in biology and biotechnology where it is commonly employed for the study and engineering of DNA, RNA, and proteins.

Inverse PCR for Point Mutation Introduction

Inverse PCR is a powerful tool for the rapid introduction of desired mutations at desired positions in a circular double-stranded DNA sequence. Here, custom-designed mutant primers oriented in the inverse direction are used to amplify the entire circular template with incorporation of the required mutation(s). By careful primer design it can be used to perform such diverse modifications as the introduction of point mutations and multiple mutations, the insertion of new sequences, and even sequence deletions. Three primer formats are commonly used; nonoverlapping, partially overlapping and fully overlapping primers, and here we describe the use of nonoverlapping primers for introduction of a point mutation. Use of such a primer setup in the PCR reaction, with one of the primers containing the desired mismatch mutation, results in the amplification of a linear, double-stranded, mutated product. Methylated template DNA is removed from the nonmethylated PCR product by DpnI digestion and the PCR product is then phosphorylated by polynucleotide kinase treatment before being recircularized by ligation, and transformed to E. coli. This relatively simple site-directed mutagenesis procedure is of major importance in biology and biotechnology today where it is commonly employed for the study and engineering of DNA, RNA, and proteins.

Marker rescue of adeno-associated virus (AAV) capsid mutants: a novel approach for chimeric AAV production

Marker rescue, the restoration of gene function by replacement of a defective gene with a normal one by recombination, has been utilized to produce novel adeno-associated virus (AAV) vectors. AAV serotype 2 (AAV2) clones containing wild-type terminal repeats, an intact rep gene, and a mutated cap gene, served as the template for marker rescue. When transfected alone in 293 cells, these AAV2 mutant plasmids produced noninfectious AAV virions that could not bind heparin sulfate after infection with adenovirus dl309 helper virus. However, the mutation in the cap gene was corrected after cotransfection with AAV serotype 3 (AAV3) capsid DNA fragments, resulting in the production of AAV2/AAV3 chimeric viruses. The cap genes from several independent marker rescue experiments were PCR amplified, cloned, and then sequenced. Sequencing results confirmed not only that homologous recombination occurred but, more importantly, that a mixed population of AAV chimeras carrying 16 to 2,200 bp throughout different regions of the type 3 cap gene were generated in a single marker rescue experiment. A 100% correlation was observed between infectivity and the ability of the chimeric virus to bind heparin sulfate. In addition, many of the AAV2/AAV3 chimeras examined exhibited differences at both the nucleotide and amino acid levels, suggesting that these chimeras may also exhibit unique infectious properties. Furthermore, AAV helper plasmids containing these chimeric cap genes were able to function in the triple transfection method to generate recombinant AAV. Together, the results suggest that DNA from other AAV serotypes can rescue AAV capsid mutants and that marker rescue may be a powerful, yet simple, technique to map, as well as develop, chimeric AAV capsids that display different serotype-specific properties.

Nobel lecture. Synthetic DNA and biology

“Most of the significant work has been summarized in a number of reviews and articles. In these there was, of necessity, a good deal of simplification and omission of detail …. With the passage of time, even 1 find myself accepting such simplified accounts.”

Efficient oligonucleotide-directed construction of mutations in expression vectors by the gapped duplex DNA method using alternating selectable markers

An efficient method for the construction of multiple mutations in a sequential manner is described. It is based on the gapped duplex DNA approach to oligonucleotide-directed mutagenesis (Kramer et al. 1984, Nucl. Acids Res. 12, 9441-9456) and a set of newly constructed phasmid vectors. These are characterized by the following features. Presence of the phage fl replication origin permits ready conversion to the single stranded DNA form. An amber mutation within, alternatively, the bla or cat gene provides a means for ready selection of the strand into which the mutagenic oligonucleotide has been incorporated. By means of the alternating antibiotic resistance markers any number of mutations can be constructed in consecutive rounds of mutagenesis. The optional presence of gene expression signals allows the direct overproduction of structurally altered proteins without re-cloning. Both the mutagenesis and expression aspects were tested using the lacZ gene as a model.

Genetic and biochemical characterization of the thymidine kinase gene from herpesvirus of turkeys

The thymidine kinase gene encoded by herpesvirus of turkeys has been identified and characterized. A viral mutant (ATR0) resistant to 1-beta-D-arabinofuranosylthymine was isolated. This mutant was also resistant to 1-(2-fluoro-2-deoxy-beta-D-arabinofuronosyl)-5-methyluracil and was unable to incorporate [125I]deoxycytidine into DNA. The mutant phenotype was rescued by a cloned region of the turkey herpesvirus genome whose DNA sequence was found to contain an open reading frame similar to that for known thymidine kinases from other viruses. When expressed in Escherichia coli, this open reading frame complemented a thymidine kinase-deficient strain and resulted in thymidine kinase activity in extracts assayed in vitro.

Construction of a synthetic variant of the bacteriophage f1 gene V by assembling oligodeoxynucleotides corresponding to only one strand of DNA

A simple and widely applicable procedure for constructing synthetic variants of a gene, involving the synthesis of only one strand of DNA, has been developed. The method is suited for cases in which a cloned DNA with a sequence related to the gene to be constructed is available. First, a heteroduplex DNA which is single-stranded throughout the region of interest is made. This single-stranded region is then used as a template to correctly align and allow ligation of synthetic oligos corresponding to the entire gene. To favor the replication of the strand encoding the synthetic gene, a template strand containing some substitutions of deoxyuridine for deoxythymidine is used. This procedure was used to construct a synthetic bacteriophage f1 gene V which differs from the wild-type (wt) gene at 45 positions out of 298. The synthetic gene was designed to include nine restriction sites without altering the sequence of the encoded DNA-binding protein. The gene construction was found to be very efficient, and about 40% of the resulting plasmids contained the desired synthetic gene. The synthetic gene was found to be fully active and could substitute for the wt gene in bacteriophage f1.

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

The important features of the protocol described here are as follows: First, the procedure consists of a few simple steps and results in a reasonably high frequency of mutagenesis. Second, using two primers, there is no need to isolate covalently closed double-stranded molecules as in our previous method. Third, the use of vectors derived from single-stranded phage facilitates template preparation, mutagenesis efficiency, screening, and DNA sequencing. Fourth, the same basic steps can be directly applied when using the single-stranded pUC derivatives.

Oligodeoxynucleotide-directed mutagenesis of Escherichia coli and yeast by simple cotransformation of the primer and template

A method of oligodeoxynucleotide-directed mutagenesis is presented which requires no in vitro DNA synthesis. Cotransformation of the synthetic primer and single-stranded template into competent spheroplasts of Escherichia coli or Saccharomyces cerevisiae generates the directed mutation. The desired event is detected genetically or by hybridization screening using the mutagenic oligodeoxynucleotide as a probe. The targeted mutation arises at a frequency of approximately 0.1%. In one extensively studied case in E. coli, involving creation of a 99-bp deletion, this procedure produced many fewer untargeted mutation events than did conventional protocols.

Physical mapping and DNA sequence analysis of the rifampicin resistance locus in vaccinia virus

Rifampicin has been shown to inhibit the maturation of poxviruses at a discrete step in envelope formation (Moss et al., 1969; Pennington et al., 1970; Nagayama et al., 1970; Grimley et al., 1970). A rifampicin-resistant vaccinia virus mutant (RifR) was selected for its ability to grow in the presence of 100 micrograms/ml of rifampicin. Utilizing intact DNA or endonuclease restricted cloned DNA subfragments derived from the RifR mutant virus, the locus specifying rifampicin resistance was physically mapped by marker rescue analysis leftward of the unique XhoI site within the HindIII D fragment. DNA sequencing of a 445 bp fragment encompassing this region revealed an AT to GC transition when compared with the equivalent wild-type DNA fragment. Analysis of the six potential open reading frames within the 445-bp fragment indicated only one available open reading frame. On this basis, the rifampicin-resistant vaccinia virus mutant was shown to have a codon transition from asparagine to aspartic acid.

Expression of Sindbis virus structural proteins via recombinant vaccinia virus: synthesis, processing, and incorporation into mature Sindbis virions

We have obtained a vaccinia virus recombinant which contains a complete cDNA copy of the 26S RNA of Sindbis virus within the thymidine kinase gene of the vaccinia virus genome. This recombinant constitutively transcribed the Sindbis sequences throughout the infectious cycle, reflecting the dual early-late vaccinia promoter used in this construction. The Sindbis-derived transcripts were translationally active, giving rise to both precursor and mature structural proteins of Sindbis virus, including the capsid protein (C), the precursor of glycoprotein E2 (PE2), and the two mature envelope glycoproteins (E1 and E2). These are the same products translated from the 26S mRNA during Sindbis infection, and thus these proteins were apparently cleaved, glycosylated, and transported in a manner analogous to that seen during authentic Sindbis infections. By using epitope-specific antibodies, it was possible to demonstrate that recombinant-derived proteins were incorporated into Sindbis virions during coinfections with monoclonal antibody-resistant Sindbis variants. These results suggest that all the information necessary to specify the proper biogenesis of Sindbis virus structural proteins resides within the 26S sequences and that vaccinia may provide an appropriate system for using DNA molecular genetic manipulations to unravel a variety of questions pertinent to RNA virus replication.

Mutational mechanisms by which an inactive replication origin of bacteriophage M13 is turned on are similar to mechanisms of activation of ras proto-oncogenes

M13 viral strand synthesis is initiated by nicking of the viral strand of the duplex replicative form by the M13 gene II initiator protein at a specific site within a sequence of about 40 base pairs having dyad symmetry. Efficient replication of the M13 viral strand also requires the presence of an adjacent sequence of ca. 100 base pairs. Together these sequences constitute the minimal origin for M13 viral strand synthesis. A pBR322 derivative having a 182-base-pair insert of M13 DNA contains a functional M13 viral strand origin and, when provided with M13 gene functions in trans, replicates under conditions nonpermissive for the parent plasmid. Chimeric plasmids containing deletions within the sequence flanking the viral strand origin are unable to replicate under these conditions. We isolated spontaneous mutants of M13 based on their ability to activate replication of such plasmids. The mutations found in these strains, as well as several produced by oligonucleotide-directed mutagenesis, all result in the substitution of any of at least four different amino acids for a specific glycine residue near the amino-terminal end of the initiator protein. Other studies have shown that overproduction of the wild-type initiator protein also restores replication. These alternate mechanisms are discussed in terms of their striking similarity to the mechanisms of activation of the ras proto-oncogenes which can be activated either by increased expression of the wild-type protein or by substitution of any of several amino acids for a glycine residue near the amino terminus.

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.

Structural requirements for the function of a yeast chromosomal replicator

A sequence closely linked to the Saccharomyces cerevisiae HO gene confers autonomous replication in yeast. I have subjected this putative replication origin to deletion and point mutagenesis in order to identify structural features that are important requirements for autonomous replication in vivo. This analysis identifies a 14 bp core region, which is crucial for function and shows partial sequence conservation between a number of autonomously replicating sequences. Point mutations within the core region can abolish autonomous replication. The core region is flanked on one side by a sequence of about 20 bp, which is important for efficient autonomous replication. Deletion of this flanking sequence reduces, but does not necessarily eliminate, autonomous replication.

In vitro deletional mutagenesis for bacterial production of the 20,000-dalton form of human pituitary growth hormone

The 20,000-dalton (20K) variant form of human growth hormone (hGH) present in extracts from pituitary glands differs from the major form of hGH (22K, 191 amino acids) by the deletion of amino acid residues 32-46. Using oligonucleotide-mediated mutagenesis, the DNA coding for these amino acids was deleted from the gene previously constructed by us (Goeddel et al., 1979) for microbial hGH production. The DNA to be deleted was looped out by the annealing of a synthetic oligodeoxyribonucleotide to the coding strand of the hGH gene contained on recombinant phage M13 mp8 DNA. Resulting heteroduplex structures were stabilized using primer-directed in vitro DNA synthesis in the presence of T4 DNA ligase. On transformation of Escherichia coli, these heteroduplex DNAs yielded phage whose genomes contained either the original or the partially deleted hGH gene, and genotypes were distinguished by in situ plaque hybridization with synthetic oligonucleotide probes. A gene with the correct deletion was used to express the short hGH variant in E. coli.

A genetic system for analysis of staphylococcal nuclease

The gene encoding staphylococcal nuclease (strain Foggi) has been isolated, and its complete nucleotide sequence determined. When inserted into a derivative of plasmid pBR322, the nuc gene is expressed in Escherichia coli at a low level, and nuclease activity in individual colonies is readily assayed by a replica-plating chromogenic test. A set of plasmids with BamHI-linker "bracketed" deletions spanning the nuc gene can be used to map mutations genetically to defined segments of the gene. In combination with present methods for efficient in vitro mutagenesis, this plasmid-based genetic system can be applied to the detailed genetic analysis of this small, biochemically and biophysically well-characterized enzyme.

Directed mutagenesis of DNA cloned in filamentous phage: influence of hemimethylated GATC sites on marker recovery from restriction fragments

Gapped duplex DNA molecules of recombinant genomes of filamentous phage are constructed in vitro. Denatured restriction fragments covering (part of) the precisely constructed gap are hybridized to the gapped duplex DNA molecules to form ternary duplices. The two strands of the ternary duplex molecules carry different genetic markers within the region spanned by the restriction fragment leading to a one base pair mismatch or to an insertion loop of 93 nucleotides, respectively. The two strands also vary with respect to A-methylation in GATC sites. In cases of asymmetrical methylation, transfection of E. coli with these heteroduplex molecules leads to marker recoveries with a pronounced bias in favour of the marker encoded by the methylated strand. This effect at least partly explains the comparably low marker yields achieved in previous directed mutagenesis experiments using filamentous phage as the vector. The results suggest how these procedures can be optimized. Precise construction of a 93 bp insertion of 9.5% marker yield is described.

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

This paper presents a versatile and efficient procedure for the construction of oligodeoxyribonucleotide directed site-specific mutations in DNA fragments cloned into M13 derived vectors. As an example, production of a transition mutation in a clone of the yeast MATa1 gene is described. The oligonucleotide is hybridized to the template DNA and covalently closed closed double stranded molecules are generated by extension of the oligonucleotide primer with E. coli DNA polymerase (large fragment) and ligation with T4 DNA ligase. The resulting double stranded closed circular DNA (CC-DNA) is separated from unligated and incompletely extended molecules by alkaline sucrose gradient centrifugation. This purification is essential for production of mutants at high efficiency. Competent E. coli JM101 cells are transformed with the CC-DNA fraction and single stranded DNA is isolated from individual plaques. The recombinants are screened for mutant molecules by 1) restriction endonuclease screening for the loss of the Hinf I site in the target region, and 2) by dot blot hybridization using the mutagenic oligonucleotide as probe. Double stranded DNA is isolated from the sequencing. Efficiency of mutant production is in the range of 10-45% and no precautions to prevent mismatch repair are required.

Molecular genetics of vaccinia virus: demonstration of marker rescue

Two genomic variants of vaccinia virus isolated from serially propagated stocks were used to demonstrate marker rescue. The smaller (S variant) virus contains a 6.3 megadalton (MDal) deletion of unique DNA sequences present in the 123-MDal larger (L variant) virus. The deletion was mapped at 6.85 MDal from the left terminus of the genome, just outside of the inverted terminal repetition. Rescue of the unique deleted DNA sequences by infectious S variant virus was obtained in CV-1 cells by using the calcium orthophosphate precipitation technique of intact or restriction endonuclease-treated L-variant DNA. Restriction fragments that overlapped the deletion allowed marker rescue, but restriction of the L-variant DNA within the unique deleted sequences gave negative results. Restriction endonuclease analysis of the DNA obtained from twice-plaque-purified recombinant virus derived from the rescue of overlap donor fragments gave a restriction pattern identical to that of L-variant virus, indicating that the donor DNA was inserted into the rescuing virus by double recombination. No amplification of the unique sequences was observed from intact L-variant DNA in the absence of infectious S-variant virus, suggesting that deproteinized vaccinia DNA is noninfectious and that the donor DNA was neither integrated into the host DNA nor present as an episomal structure. By using 1 microgram of intact L-variant DNA per CV-1 monolayer in a 6-cm Petri dish, approximately 1--5% of the plaques contained the L-variant genotype, and the dose--response curve was essentially linear from 0.1 to 2 microgram of DNA.

Adenovirus terminal protein protects single stranded DNA from digestion by a cellular exonuclease

Adenovirus 5 DNA-protein complex is isolated from virions as a duplex DNA molecule covalently attached by the 5' termini of each strand to virion protein of unknown function. The DNA-protein complex can be digested with E. coli exonuclease III to generate molecules analogous to DNA replication intermediates in that they contain long single stranded regions ending in 5' termini bound to terminal protein. The infectivity of pronase digested Adenovirus 5 DNA is greatly diminished by exonuclease III digestion. However, the infectivity of the DNA-protein complex is not significantly altered when up to at least 2400 nucleotides are removed from the 3' ends of each strand. This indicates that the terminal protein protects 5' terminated single stranded regions from digestion by a cellular exonuclease. DNA-protein complex prepared from a host range mutant with a mutation mapping in the left 4% of the genome was digested with exonuclease III, hybridized to a wild type restriction fragment comprising the left 8% of the genome, and transfected into HeLa cells. Virus with wild type phenotype was recovered at high frequency.

The use of R-looping for structural gene identification and mRNA purification

A method is presented for the purification of mRNAs and the identification of structural gene sequences in recombinant DNA molecules. RNA is hybridized to double-stranded linear DNA such that R-loops are formed between most DNAs and their complementary RNA sequences. These R-loops are purified from unhybridized RNAs by gel filtration chromatography in the presence of a high concentration of salt. The complementary RNAs are released from the R-loops by heating, and are assayed by gel electrophoresis or cell free translation to determine their purity and to identify the proteins for which they code. We have demonstrated that recombinant DNAs containing sequences for abundant or moderately abundant mRNAs of Saccharomyces cerevisiae can be identified by this means.

Molecular genetics of herpes simplex virus. III. Fine mapping of a genetic locus determining resistance to phosphonoacetate by two methods of marker transfer

We have transferred a genetic locus determining resistance to phosphonoacetic acid (PAAr) from one herpes simplex viral genome to another by two methods of marker transfer. One method requires recombination between an intact DNA molecule and a restriction endonuclease DNA fragment, whereas the other requires repair of a partial heteroduplex formed between the two DNA molecules. These two methods mapped the PAAr locus between positions 0.45 and 0.53 map units on the physical map of the viral DNA. Fine mapping of the PAAr locus showed that it maps at or near an EcoRI restriction endonuclease site at either 0.46 or 0.49 map units. We also describe and compare the two methods of marker transfer.

Physical mapping of herpes simplex virus type 1 mutations by marker rescue

A generally applicable technique which permits the rescue of selected genetic markers from fragments of herpes simplex virus DNA is described. Baby hamster kidney cells infected at the nonpermissive temperature with intact DNA from temperature-sensitive mutants or with fragmented wild-type DNA produce no, or little, infectious progeny. Coinfection results in an increased yield of virus, demonstrating the rescue of genetic information from the DNA fragments. This progeny virus consists of both wild-type and temperature-sensitive virus, demonstrating that both recombination and complementation can occur in coinfected cells. Rescue experiments using isolated fragments produced with various restriction endonucleases have enabled us to locate five temperature-sensitive mutations on the herpes simplex virus type 1 physical map. An adaptation of the technique has allowed the physical mapping of a mutation which affects the herpes simplex virus type 1 pyrimidine deoxyribonucleoside kinase gene. Comparison of the genetic and physical maps for these mutants reveals several anomalies which are discussed.

Efficient correction of a mutation by use of chemically synthesized DNA

The mutated base in the am3 lysis-defective mutant of the bacteriophage phiX174 has been corrected by a combined in vitro enzymatic DNA synthesis and in vivo replication of the heteroduplex product. Chemically synthesized oligodeoxyribonucleotides carrying the wild-type sequence have been used to prime DNA synthesis with am3 phiX174 DNA serving as a template. The resultant semisynthetic heteroduplex composed of an am3(+) strand and a wild-type (-) strand, with one mismatched base pair at position 587 on the phiX174 DNA sequence, was used to infect spheroplasts. The progeny phage were analyzed by a parallel plaque assay on wild-type host, Escherichia coli C, to screen for wild-type phenotype, and on E. coli HF4714, an amber suppressor strain, to determine the total progeny phage. When a 23-base-long synthetic primer was used, about one-third of total progeny were found to be wild type. Shorter primers yielded lower percentages of wild type; they also had poorer priming activity.

Transfection of Enterobacteriaceae and its applications

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Complementation between temperature-sensitive (ts) and host range nontransforming (hr-t) mutants of polyoma virus

Two major classes of polyoma mutants are defective in cell transformation: early temperature-sensitive mutants of the tsA type which are defective in viral DNA synthesis and transformation at 39 degrees, but not at 32 degrees; and host range nontransforming (hr-t) mutants which fail to transform at either temperature. Mixed infection of mouse 3T3 cells by hr-t mutants and early tsA-type mutants results in enhanced growth of the tsA-type mutants at 39 degrees, indicating that the hr-t mutants can supply the early viral function required for viral DNA synthesis. The hr-t mutants also complement late is mutants which fail to produce infectious progeny at 39 degrees because of alterations in the 45,000-dalton major virion protein. Mixed infection of hamster BHK or rat Y1 cells by hr-t and tsA-type mutants results in efficient transformation at 39 degrees, indicating that the two classes of mutants can complement for transformation. No complementation is observed in pair-wise crosses among the early tsA-type mutants alone. The tsA-type mutants are located in the distal portion of the early region of the polyoma genome [Miller, L. K., and Fried, M. (1976) J. Virol. 18, 824-832]. The hr-t mutants are located in the proximal portion [Feunteun, J., Sompayrac, L., Fluck, M., and Benjamin, T. (1976) Proc. Nat. Acad. Sci. USA]. These results suggest that the early region of the polyoma genome is divided into two functional regions which can complement for transformation. The ts3 mutant of polyoma is located in the proximal portion of the late region.

Localization of gene functions in polyoma virus DNA

Polyoma virus mutants of four functionally distinct groups have been mapped by the marker rescue technique using restriction enzyme fragments of wild-type viral DNA. Nontransforming host-range mutants map in the proximal part of the early region of the viral genome. The same DNA fragment that restores a normal host range also restores normal transforming ability to these mutants. ts-25D, a temperature-sensitive (ts)-a class mutant, maps in the distal part of the early region. ts-3 and ts-1260 map in the proximal and distal parts of the late region, respectively.

Restriction-enzyme-cleavage maps of bacteriophage M13. Existence of an intergenic region on the M13 genome

Replicative form DNA of bacteriophage M13 was cleaved into specific fragments by an endonuclease isolated from Hemophilus aegyptius (endoR.HaeII) and an endonuclease from Arthrobacter luteus (endoR.AluI). The fragments were ordered as to construct a circular map of the phage M13 genome by: (a) using each fragment as a primer for the synthesis in vitro of its respective neighbour and (b) digesting the isolated fragments with the Hemophilus aegyptius enzyme endoR.HaeII or the Hemophilus aphirophilus enzyme endoR.HapII and subsequent analysis of the overlapping sets of fragments. The resulting physical map was correlated with the M13 genetic map by marker rescue experiments with amber mutant phage DNAs and purified wild-type fragments. From the results of these analyses it has been concluded that gene II and gene V are contiguous on the genetic map. Evidence is provided that there is an internal start of RNA synthesis within the C-terminal region of gene II which then ultimately leads to the synthesis of X protein. Furthermore, we conclude that there is an intergenic space of considerable length (450-500 base pairs) which is located between gene II and gene IV on the M13 genome. The function of this intergenic region as the origin site for phage DNA replication is discussed.

Direct biochemical mapping of eukaryotic viral DNA by means of a linked transcription-translation cell-free system

A method is described for mapping regions of eukaryotic viral DNA coding for specific proteins, utilizing a linked transcription-translation cell-free system primed with DNA fragments generated by restriction endonucleases. Three simian virus 40 (SV40) DNA fragments derived from that region of the DNA expressed late in lytic infection were purified. They were: Hpa I-A (0.76-0.175 map units), Bgl I-EcoRI-B (0.672-0), and Hpa II-EcoRI-B (0.735-0). (Fragments are named from the cleaving restriction endonuclease and electrophoretic mobility. End positions on the conventional map are in clockwise order.) These fragments efficiently stimulated the incorporation of [3H]UTP and [35S]methionine into trichloroacetic-acid-insoluble material in the linkec system. The location of the region of DNA coding for the viral structural proteins VPI, VP2 and VP3 was determined from the spectrum of polypeptide synthesis directed by the individual intact fragments and their specific endonucleolytic digests. The polypeptides synthesized in the cell-free system were characterized on urea-sodium dodecyl sulfate polyacrylamide gradient gels and by two-dimensional tryptic peptide analysis. ..

Incorporation of 5'-amino-5'-deoxythymidine5'-phosphate in polynucleotides by use of DNA polymerase I and a phiX174 DNA template

An aqueous solution of 5'-amino-5'-deoxythymidine 5'-triphosphate, prepared by incubation of equimolar solutions of 5'-amino-5'-deoxythymidine and sodium trimetaphosphate, stimulates synthesis of acid-precipitable polynucleotides in a system containing single-strand phiX174 DNA template, random oligonucleotide primers, dATP, dCTP,dGTP, Escherichia coli DNA polymerase I, and either magnesium or manganese ion. Approximately onefold synthesis on the template can be achieved and each of the indicated reagents is essential for extensive synthesis. The reaction is slower than the corresponding reaction of dTTP as a consequence of a lower V max and a higher Km for the amino analogue. That aminodeoxythymidine phosphate is incorporated into the synthetic polynucleotides was shown by a double-labeling experiment with [14C]dATP and [32P]-5'-amino-5'-deoxythymidine 5'-triphosphate and by the unusually high lability of the phosphoramidate polynucleotides toward acid. The phosphoramidate polynucleotides range in size from about 100 nucleotide units to well over a thousand nucleotide units, and the size is increased by addition of DNA ligase to the system. These experiments indicate that synthetic polynucleotides in which oligonucleotide blocks have been joined by means of phosphoramidate bonds should prove useful as primers for enzymatic syntheses with DNA polymerase I.

Construction of the genetic map of the polyoma genome

Seven early mutants, three late mutants, and one plaque morphology mutant of polyoma have been mapped by marker rescue using wild-type restriction endonuclease fragments. The early mutants map between 1.0 and 26.4 units from the Eco RI site, a region previously shown to correspond to the 3'-OH termainal half of "early" RNA (Kamen et al., 1974). The late mutants as well as the plaque morphology mutant map between 26.6 and 45.4 map units, a region previously shown to correspond to the 3'-OH terminal half of "late" RNA (Kamen et al., 1974). Analysis of the genotype of rescued virus demonstrated that the modification of the mutant DNA during marker rescue was limited to the region of the genome covered by the wild-type restriction endonuclease fragment tested.