Single-stranded DNA binding proteins unwind the newly synthesized double-stranded DNA of model miniforks

Single-stranded DNA binding (SSB) proteins are essential proteins of DNA metabolism. We characterized the binding of the bacteriophage T4 SSB, Escherichia coli SSB, human replication protein A (hRPA), and human hSSB1 proteins onto model miniforks and double-stranded-single-stranded (ds-ss) junctions exposing 3' or 5' ssDNA overhangs. T4 SSB proteins, E. coli SSB proteins, and hRPA have a different binding preference for the ss tail exposed on model miniforks and ds-ss junctions. The T4 SSB protein preferentially binds substrates with 5' ss tails, whereas the E. coli SSB protein and hRPA show a preference for substrates with 3' ss overhangs. When interacting with ds-ss junctions or miniforks, the T4 SSB protein, E. coli SSB protein, and hRPA can destabilize not only the ds part of a ds-ss junction but also the daughter ds arm of a minifork. The T4 SSB protein displays these unwinding activities in a polar manner. Taken together, our results position the SSB protein as a potential key player in the reversal of a stalled replication fork and in gap repair-mediated repetitive sequence expansion.     

Seamless gene engineering using RNA- and DNA-overhang cloning

Here we describe two methods for generating DNA fragments with single-stranded overhangs, like those generated by the activity of many restriction enzymes, by simple methods that do not involve DNA digestion. The methods, RNA-overhang cloning (ROC) and DNA-overhang cloning (DOC), generate polymerase chain reaction (PCR) products composed of double-stranded (ds) DNA flanked by single-stranded (ss) RNA or DNA overhangs. The overhangs can be used to recombine DNA fragments at any sequence location, creating "perfect" chimeric genes composed of DNA fragments that have been joined without the insertion, deletion, or alteration of even a single base pair. The ROC method entails using PCR primers that contain regions of RNA sequence that cannot be copied by certain thermostable DNA polymerases. Using such a chimeric primer in PCR would yield a product with a 5' overhang identical to the sequence of the RNA component of the primer, which can be used for directional ligation of the amplified product to other preselected DNA molecules. This method provides complete control over both the length and sequence of the overhangs, and eliminates the need for restriction enzymes as tools for gene engineering.     

Illegitimate integration of single-stranded DNA in Saccharomyces cerevisiae

We studied illegitimate recombination by transforming yeast with a single-stranded (ss) non-replicative plasmid. Plasmid pCW12, containing the ARG4gene, was used for transformation of yeast strains deleted for the ARG4, either in native (circular) form or after linearization within the vector sequence by the restriction enzyme ScaI. Both circular and linearized ss plasmids were shown to be much more efficient in illegitimate integration than their double-stranded (ds) counterparts and more than two-thirds of the transformants analysed contained multiple tandem integrations of the plasmid. Pulsed-field gel electrophoresis of genomic DNA revealed significant changes in the karyotype of some transformants. Plasmid DNA was frequently detected on more than one chromosome and on mitotically unstable, autonomously replicating elements. Our results show that the introduction of nonhomologous ss DNA into yeast cells can lead to different types of alterations in the yeast genome.     

Maize streak virus coat protein is karyophyllic and facilitates nuclear transport of viral DNA.

Transport of maize streak virus (MSV) DNA into the nucleus of host cells is essential for virus replication and the presence of virus particles in the nuclei of infected cells implies that coat protein (CP) must enter the nucleus. To see if CP is imported into the nucleus in the absence of other viral gene products, the MSV CP gene was expressed in insect cells with a baculovirus vector system, and also in tobacco protoplasts with a cauliflower mosaic virus (CaMV) 35S promoter-driven transient gene expression vector. Immunofluorescent staining showed that the CP accumulated in the nuclei of both insect and tobacco cells. Mutagenesis of a potential nuclear localization signal in the CP resulted in cytoplasmic accumulation of the mutant protein. We have shown previously that the CP binds to single-stranded (ss) and double-stranded (ds) viral DNA. To investigate if CP might also be involved in viral DNA nuclear transport, Escherichia coli-expressed CP, together with TOTO-1-labeled viral ss or ds DNA, was microinjected into maize and tobacco epidermal cells. Both ss and ds DNA moved into the nucleus when co-injected with the CP but not with E. coli proteins alone. These results suggest that, in addition to entering the nucleus where it is required for encapsidation of the viral ss DNA, the MSV CP facilitates the rapid transport of viral (ss or ds) DNA into the nucleus.     

Yeast DNA topoisomerase II is encoded by a single-copy, essential gene

The gene TOP2 encoding yeast topoisomerase II has been cloned by immunological screening of a yeast genomic library constructed in the phage lambda expression vector, lambda gt11. The ends of the message encoded by the cloned DNA fragment were delimited by the Berk and Sharp procedure (S1 nuclease mapping) for the 5' end and mapping of the polyA tail portion of a cDNA fragment for the 3' end. The predicted size of the message agrees with the length of the message as determined by Northern blot hybridization analysis. The identity of the gene was confirmed by expressing the gene in E. coli from the E. coli promoter lac UV5 to give catalytically active yeast DNA topoisomerase II. Disruption of one copy of the gene in a diploid yeast creates a recessive lethal mutation, indicating that the single DNA topoisomerase II gene of yeast has an essential function.     

Illegitimate integration of single-stranded DNA in Saccharomyces cerevisiae

 We studied illegitimate recombination by transforming yeast with a single-stranded (ss) non-replicative plasmid. Plasmid pCW12, containing the ARG4gene, was used for transformation of yeast strains deleted for the ARG4, either in native (circular) form or after linearization within the vector sequence by the restriction enzyme ScaI. Both circular and linearized ss plasmids were shown to be much more efficient in illegitimate integration than their double-stranded (ds) counterparts and more than two-thirds of the transformants analysed contained multiple tandem integrations of the plasmid. Pulsed-field gel electrophoresis of genomic DNA revealed significant changes in the karyotype of some transformants. Plasmid DNA was frequently detected on more than one chromosome and on mitotically unstable, autonomously replicating elements. Our results show that the introduction of nonhomologous ss DNA into yeast cells can lead to different types of alterations in the yeast genome. Received: 9 February 1996/Accepted: 7 July 1996     

Sequence of a yeast DNA fragment containing a chromosomal replicator and the TRP1 gene

The DNA sequence of a 1.45 kb EcoRI fragment from the yeast (Saccharomyces cerevisiae) TRP1 region has been determined. The fragment contains the TRP1 gene and a yeast chromosomal replicator. The TRP1 gene has been located on the fragment by analysis of potential initiation and termination codons in the DNA sequence. This location has been confirmed by subcloning portions of the fragment. Both the 5' and 3' noncoding regions of the TRP1 gene contain sequence homologies with analogous areas surrounding other yeast genes. The yeast replicator has been localized in a region near the 3' end of the TRP1 gene. The DNA sequence in this region contains several structural features which may be involved in the initiation of DNA replication.     

Direct cloning of a long restriction fragment aided with a jumping clone.

Long-range physical mapping with rare-cutting restriction enzymes (rare cutters) is an important step for structural analysis of complex genomes. Combination of two types of DNA clones bearing the rare-cutter sites, linking clones and jumping clones (Fig. 1a), facilitates the physical mapping [Poustka et al., Nature 325 (1987) 353-355]. A step followed by the physical mapping is the cloning of the large (rare-cutter-generated) restriction fragment of interest. For facilitating this step, we devised a method to directly clone a long restriction fragment without constructing the whole genomic DNA library using the jumping clone as starting material. The short DNA segments of a jumping clone, which are derived from the 5' and 3' terminal regions of the large restriction fragment, are inserted into the yeast artificial chromosome plasmid (pYAC) vector, and then converted into single strands with T7 gene 6-encoded 5'----3' exonuclease. The total genomic DNA digested with the restriction enzyme is also treated with the exonuclease to convert the terminal regions of the restriction fragments into single strands. In the resulting products, only the fragment corresponding to the jumping clone can form hybrids with the just-mentioned, single-stranded DNAs, which are connected to the pYAC, and only this fragment is cloned in yeast. We describe the protocol of this method with Escherichia coli DNA as a model experiment. Judging from the cloning efficiency, this method could be applied to cloning single-copy regions of the human genome, provided a jumping clone is available. The instability of inserts in the pYAC vector is also discussed.     

Plasmid vectors for positive galactose-resistance selection of cloned DNA in Escherichia coli

Insertion of a HindIII-EcoRI fragment carrying part of the gal operon from lambda gal+ into pBR322 yields a plasmid (pAA3) which confers strong galactose sensitivity on E. coli strains deleted for the gal operon. Sensitivity to galactose is caused by the expression of kinase and transferase (but not epimerase) genes from a promoter located in the tet gene of pBR322. Insertion of a DNA fragment carrying Tn9 at the HindIII junction blocks gal expression and produces a galactose-resistant phenotype. Hence, galactose resistance can be used to select DNA fragments cloned at the HindIII site. The system was used efficiently for cloning lambda, yeast, and human DNA. The cloned fragments can be screened directly for the presence of promoters by testing for tetracycline resistance. Alternatively, these plasmids can be used as cosmids for cloning large fragments of DNA at a number of sites. Construction of several related vectors is described.     

The isolation, characterization and nucleotide sequence of the phosphoglucoisomerase gene of Saccharomyces cerevisiae

We have isolated the gene which encodes the glycolytic enzyme phosphoglucoisomerase (PGI) from the yeast Saccharomyces cerevisiae by functional complementation of a yeast mutant deficient in PGI activity with DNA from a wild-type yeast genomic library. The cloned gene has been localized by hybridization of specific DNA fragments to total yeast poly(A)+ RNA and by complementation of the mutant phenotype with subclones. The gene is expressed as an abundant mRNA of 1.9-kb and encodes a protein of 554 amino acids with an Mr of 61310. The nucleotide sequence of the gene as well as the 5' and 3' flanking regions are presented. The predicted PGI amino acid sequence shows a high degree of homology with the sequence predicted for human and mouse neuroleukin, a putative neurotropic factor. The codon usage within the coding region is very restricted, characteristic of a highly expressed yeast gene.     

Construction of plasmid vectors that facilitate subcloning and recovery of yeast and Escherichia coli DNA fragments

We have constructed a plasmid vector (pNF2) which is a derivative of the multicopy yeast cloning vehicle YEp24. This derivative contains a single BamHI site flanked immediately on each side by SalI sites. The latter site was selected because it appears to be infrequent in yeast nuclear DNA. Thus, DNA fragments produced by partial digestion with enzymes (such as Sau3A) that cut at frequent intervals and leave single-stranded ends that have sequence homology with BamHI sites, can be conveniently subcloned into this site. Such fragments can then be excised intact by digestion with SalI enzyme. Plasmid pNF2 also contains the kanamycin-resistance (kanR) gene derived from Tn903 and confers resistance in yeast to the antibiotic G418. pNF2 was converted into an integrating vector (pNF3) by deleting a 2.2-kb EcoRI fragment containing a sequence that determines autonomous replication in yeast. Further deletion of a HindIII fragment containing the yeast URA3 gene converts the plasmid into one containing only pBR322 sequences plus the kanR gene (pNF4).     

Intracellular viral processing, not single-stranded DNA accumulation, is crucial for recombinant adeno-associated virus transduction

Adeno-associated virus (AAV) is a unique gene transfer vector which takes approximately 4 to 6 weeks to reach its expression plateau. The mechanism for this slow-rise expression profile was proposed to be inefficient second-strand DNA synthesis from the input single-stranded (ss) DNA viral genome. In order to clarify the status of ss AAV genomes, we generated AAV vectors labeled with bromodeoxyuridine (BrdU), a nucleotide analog that can be incorporated into the AAV genome and packaged into infectious virions. Since BrdU-DNA can be detected only by an anti-BrdU antibody when DNA is in an ss form, not in a double-stranded (ds) form, ss AAV genomes with BrdU can be readily tracked in situ. Although ss AAV DNA was abundant by Southern blot analysis, free ss AAV genomes were not detectable after AAV transduction by this new detection method. Further Southern blot analysis of viral DNA and virions revealed that ss AAV DNA was protected within virions. Extracted cellular fractions demonstrated that viral particles in host cells remained infectious. In addition, a significant amount of AAV genomes was degraded after AAV transduction. Therefore, we conclude that the amount of free ss DNA is not abundant during AAV transduction. AAV transduction is limited by the steps that affect AAV ss DNA release (i.e., uncoating) before second-strand DNA synthesis can occur. AAV ss DNA released from viral uncoating is either converted into ds DNA efficiently or degraded by cellular DNA repair mechanisms as damaged DNA. This study elucidates a mechanism that can be exploited to develop new strategies to improve AAV vector transduction efficiency.     

Mammalian DNA polymerase beta: characterization of a 16-kDa transdomain fragment containing the nucleic acid-binding activities of the native enzyme.

The 39-kDa DNA polymerase beta (beta-Pol) molecule can be readily converted into two constituent domains by mild proteolysis; these domains are represented in an 8-kDa N-terminal fragment and a 31-kDa C-terminal fragment [Kumar et al. (1990a) J. Biol. Chem. 265, 2124-2131]. Intact beta-Pol is a sequence-nonspecific nucleic acid-interactive protein that binds both double-stranded (ds) and single-stranded (ss) polynucleotides. These two activities appear to be contributed by separate portions of the enzyme, since the 31-kDa domain binds ds DNA but not ss DNA, and conversely, the 8-kDa domain binds ss DNA but not ds DNA [Casas-Finet et al. (1991) J. Biol. Chem. 266, 19618-19625]. Truncation of the 31-kDa domain at the N-terminus with chymotrypsin, to produce a 27-kDa fragment (residues 140-334), eliminated all DNA-binding activity. This suggested that the ds DNA-binding capacity of the 31-kDa domain may be carried in the N-terminal segment of the 31-kDa domain. We used CNBr to prepare a 16-kDa fragment (residues 18-154) that spans the ss DNA-binding region of the 8-kDa domain along with the N-terminal portion of the 31-kDa domain. The purified 16-kDa fragment was found to have both ss and ds polynucleotide-binding capacity. Thermodynamic binding properties for these activities are similar to those of the intact enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

PIF1: a DNA helicase in yeast mitochondria.

The PIF1 gene is involved in repair and recombination of mitochondrial DNA (mtDNA). In this study, the PIF1 gene product, which cannot be identified in normal yeast cells, has been overproduced from the GALI promoter to detectable protein levels. Location of PIF1 in mitochondria has been shown by immunoelectron microscopy and in vivo import experiments using ts mas1 mutants deficient in the mitochondrial matrix-localized processing protease. Overproduction of PIF1 protein in pif1 mutants restores mtDNA recombination proficiency but is toxic to yeast cells as observed by slower growth. The overproduced PIF1 protein, which is firmly associated with insoluble mitochondrial structures, has been partially purified in a mitochondrial nuclease deficient nuc1 strain by a procedure including solubilization by urea and renaturation by dialysis at alkaline pH. PIF1 is a single-stranded (ss) DNA-dependent ATPase and a DNA helicase which unwinds partially DNA duplexes in a 5' to 3' direction with respect to the ss DNA on which it binds first.     

Identification of novel DNA forms in tomato golden mosaic virus infected tissue. Evidence for a two component viral genome.

Extracts obtained from cells infected with the geminivirus tomato golden mosaic (TGMV) are shown to contain, in addition to viral single-stranded DNA, several novel species of virus-specific single- and double- stranded DNA (ss and ds DNA). The results of nuclease studies and electron microscopy suggest that three of the intracellular DNAs are unit-genome length duplexes of closed circular, relaxed circular, and linear form. The remaining ds DNA species are of high molecular weight and appear to be concatamers consisting of two or more unit-length circular ds TGMV DNA resulted in fragments whose combined size is twice the unit-genome length. Thus ds TGMV is composed of two components of nearly identical size but different nucleotide sequence.     

Identification of the yeast TOP3 gene product as a single strand-specific DNA topoisomerase.

The TOP3 gene of the yeast Saccharomyces cerevisiae was postulated to encode a DNA topoisomerase, based on its sequence homology to Escherichia coli DNA topoisomerase I and the suppression of the poor growth phenotype of top3 mutants by the expression of the E. coli enzyme (Wallis, J.W., Chrebet, G., Brodsky, G., Golfe, M., and Rothstein, R. (1989) Cell 58, 409-419). We have purified the yeast TOP3 gene product to near homogeneity as a 74-kDA protein from yeast cells lacking DNA topoisomerase I and overexpressing a plasmid-borne TOP3 gene linked to a phosphate-regulated yeast PHO5 gene promoter. The purified protein possesses a distinct DNA topoisomerase activity: similar to E. coli DNA topoisomerases I and III, it partially relaxes negatively but not positively supercoiled DNA. Several experiments, including the use of a negatively supercoiled heteroduplex DNA containing a 29-nucleotide single-stranded loop, indicate that the activity has a strong preference for single-stranded DNA. A protein-DNA covalent complex in which the 74-kDa protein is linked to a 5' DNA phosphoryl group has been identified, and the nucleotide sequences of 30 sites of DNA-protein covalent complex formation have been determined. These sequences differ from those recognized by E. coli DNA topoisomerase I but resemble those recognized by E. coli DNA topoisomerase III. Based on these results, the yeast TOP3 gene product can formally be termed S. cerevisiae DNA topoisomerase III. Analysis of supercoiling of intracellular yeast plasmids in various DNA topoisomerase mutants indicates that yeast DNA topoisomerase III has at most a weak activity in relaxing negatively supercoiled double-stranded DNA in vivo, in accordance with the characteristics of the purified enzyme.     

Saccharomyces cerevisiae RAD27 complements its Escherichia coli homolog in damage repair but not mutation avoidance

In eukaryotes, the flap endonuclease of Rad27/Fen-1 is thought to play a critical role in lagging-strand DNA replication by removing ribonucleotides present at the 5' ends of Okazaki fragments, and in base excision repair by cleaving a 5' flap structure that may result during base excision repair. Saccharomyces cerevisiae rad27Delta mutants further display a repeat tract instability phenotype and a high rate of forward mutations to canavanine resistance that result from duplications of DNA sequence, indicating a role in mutation avoidance. Two conserved motifs in Rad27/Fen-1 show homology to the 5' --> 3' exonuclease domain of Escherichia coli DNA polymerase I. The strain defective in the 5' --> 3' exonuclease domain in DNA polymerase I shows essentially the same phenotype as the yeast rad27Delta strain. In this study, we expressed the yeast RAD27 gene in an E. coli strain lacking the 5' --> 3' exonuclease domain in DNA polymerase I in order to test whether eukaryotic RAD27/FEN-1 can complement the defect of its bacterial homolog. We found that the yeast Rad27 protein complements sensitivity to methyl methanesulfonate in an E. coli mutant. On the other hand, Rad27 protein did not reduce the high rate of spontaneous mutagenesis in the E. coli tonB gene which results from duplication of DNA. These results indicate that the yeast Rad27 and E. coli 5' --> 3' exonuclease act on the same substrate. We argue that the lack of mutation avoidance of yeast RAD27 in E. coli results from a lack of interaction between the yeast Rad27 protein and the E. coli replication clamp (beta-clamp).     

An alternative approach in gene synthesis: use of long selfpriming oligodeoxynucleotides for the construction of double-stranded DNA

A novel approach for the synthesis of double-stranded DNA fragments from only one long oligodeoxynucleotide (oligo) is presented. The basic strategy is to use oligos which possess a short inverted repeat at their 3' end resulting in the formation of a hairpin structure. The 3' end of this hairpin then serves as a primer in the Klenow (large) fragment of E. coli DNA polymerase I-mediated synthesis of the second DNA strand. Removal of the loop structure as well as generation of sticky ends for subsequent cloning is achieved by digestion with restriction enzymes. Several oligos ranging in size from 130 to 147 nt were synthesized and successfully used in the cloning of gene fragments of up to 120 bp in length. Furthermore, a strategy for the simultaneous cloning of two synthetic DNA fragments is outlined yielding even larger gene fragments. By sequential cloning of these gene fragments the methodology presented here will allow the synthesis of genes of any size. The proposed methodology should also be useful for site-directed mutagenesis as well as saturation mutagenesis.