In vitro site-directed mutagenesis with synthetic DNA oligonucleotides yields unexpected deletions and insertions at high frequency.

We have used in vitro site-directed mutagenesis with synthetic DNA oligonucleotides to introduce single nucleotide mutations in yeast mtDNA. In addition to the expected DNA alterations we also recovered with high frequency mutants with large deletions and insertions which arose through interaction with the synthetic DNA fragment. Characterization of a number of these by DNA sequence analysis has permitted reconstruction of the mutagenic events. In all cases, the DNA fragment had base paired with non-adjacent DNA sequences sometimes more than 1000 nucleotides apart from each other on the target strand. The products of such interactions cannot be avoided due to the non-stringent annealing conditions during complementary DNA strand synthesis. However, deliberate mispairing can be directed precisely, as shown by our ability to specifically delete the 1143-bp intron from the yeast mitochondrial gene coding for large ribosomal RNA with a synthetic DNA fragment consisting of the sequence of the exon borders flanking the intron.     

Mutations predetermined by the primary structure of DNA

This study is concerned with an experimental verification of hypotheses postulating the involvement of self-complementary nucleotide sequences in the formation of deletions and insertions. It was suggested that deletions can arise in the regions of self-complementary nucleotide sequences, which allows the formation of the hairpin structures in a single-stranded DNA, arising during excision repair. These hairpin structures can be eliminated by nucleases or during DNA replication. Insertions can arise as a result of homologous recombination, when a migrating DNA strand contains a self-complementary sequence which forms hairpin structure. Model experiments were carried out with the pBR322 plasmid. A plasmid DNA with premutational damage in the palindrome-containing region was constructed by in vitro dimethylsulfate modification of one strand of EcoRI-BamHI restriction fragment. The plasmid was used for transformation of Escherichia coli. Restriction mapping and nucleotide analysis of the mutant DNAs demonstrated that they all contained deletions. The end points of the deletions coincide with the palindrome. To model homologous recombination, a plasmid with D-loop was constructed. A single-stranded DNA fragment containing palindrome forming a hairpin structure was introduced into the plasmid DNA and covalently fixed in the complex. When E. coli cells were transfected with this DNA, plasmid mutants containing insertions predetermined by palindromic structure arose. The evolutionary role of mutations predetermined by primary DNA structure is discussed.     

Site-directed mutagenesis using positive antibiotic selection

Various mutsgenesis protocols have been established that use the hybridization of a mismatched oligonucleotide to prime DNA synthesis on an M13 phagemid template. For efficient mutagenesis, all of these methods require a means to select for the mutant strand before or during amplification in anEscherichia coli host. In the Altered Sites II protocol, the mismatched oligonucleotide and an oligonucleotide that restores antibiotic resistance to the phagemid are simultaneously hybridized to the template and coupled by DNA synthesis and ligation. The restored antibiotic resistance is then used to select only those phagemids which incorporate the antibiotic repair oligonucleotide. Generally, between 60 and 90% of the phagemids recovered will incorporate both oligonucleotides. This method provides a simple an efficient technique for introducing specific mutations into DNA.     

Substrate-induced DNA strand misalignment during catalytic cycling by DNA polymerase lambda

The simple deletion of nucleotides is common in many organisms. It can be advantageous when it activates genes beneficial to microbial survival in adverse environments, and deleterious when it mutates genes relevant to survival, cancer or degenerative diseases. The classical idea is that simple deletions arise by strand slippage. A prime opportunity for slippage occurs during DNA synthesis, but it remains unclear how slippage is controlled during a polymerization cycle. Here, we report crystal structures and molecular dynamics simulations of mutant derivatives of DNA polymerase lambda bound to a primer-template during strand slippage. Relative to the primer strand, the template strand is in multiple conformations, indicating intermediates on the pathway to deletion mutagenesis. Consistent with these intermediates, the mutant polymerases generate single-base deletions at high rates. The results indicate that dNTP-induced template strand repositioning during conformational rearrangements in the catalytic cycle is crucial to controlling the rate of strand slippage.     

Plasmid rolling circle replication: identification of the RNA polymerase-directed primer RNA and requirement for DNA polymerase I for lagging strand synthesis.

Plasmid rolling circle replication involves generation of single-stranded DNA (ssDNA) intermediates. ssDNA released after leading strand synthesis is converted to a double-stranded form using solely host proteins. Most plasmids that replicate by the rolling circle mode contain palindromic sequences that act as the single strand origin, sso. We have investigated the host requirements for the functionality of one such sequence, ssoA, from the streptococcal plasmid pLS1. We used a new cell-free replication system from Streptococcus pneumoniae to investigate whether host DNA polymerase I was required for lagging strand synthesis. Extracts from DNA polymerase I-deficient cells failed to replicate, but this was corrected by adding purified DNA polymerase I. Efficient DNA synthesis from the pLS1-ssoA required the entire DNA polymerase I (polymerase and 5'-3' exonuclease activities). ssDNA containing the pLS1-ssoA was a substrate for specific RNA polymerase binding and a template for RNA polymerase-directed synthesis of a 20 nucleotide RNA primer. We constructed mutations in two highly conserved regions within the ssoA: a six nucleotide conserved sequence and the recombination site B. Our results show that the former seemed to function as a terminator for primer RNA synthesis, while the latter may be a binding site for RNA polymerase.     

Highly efficient deletion method for the engineering of plasmid DNA with single-stranded oligonucleotides

The lamda phage Red recombination system has been used to modify plasmid, bacterial artificial chromosome (BAC), and chromosomal DNA in a highly precise and versatile manner Linear double-stranded DNA fragments or synthetic single-stranded oligonucleotides (SSOs) with short flanking homologies (<50 bp) to the target loci can be used as substrates to direct changes, including point mutations, insertions, and deletions. In attempts to explore mechanistic bases under this recombination process, we and others have previously identified factors that influence SSO-mediated single base substitutions. In this report, we focus our study on SSO-mediated deletion on plasmids. We found that SSOs as short as 63 bp were sufficient to mediate deletion as long as 2 kb with efficiency higher than 1%. Strand bias was consistently observed, and SSOs with sequences identical to the nascent lagging strand during replication always resulted in higher efficiency. Unlike SSO-mediated single nucleotide substitution, homology on each side of SSO flanking the fragment to be deleted was important for successful deletion, and abolishing the host methyl-directed mismatch repair (MMR) system did not lead to detectable changes in deletion efficiency. Finally, we showed that by optimizing its design, SSO-mediated deletion was efficient enough to make it possible to manipulate plasmids without selectable markers.     

A PCR-mediated gene synthesis strategy involving the assembly of oligonucleotides representing only one of the strands.

A modification of PCR-mediated gene synthesis strategy is introduced. This modification enables the synthesis of a gene from oligonucleotides comprising only one of the two strands. Bridging oligonucleotides (approximately 20-mers in length) complementary to the junctions of template strand oligonucleotides and two outer primers are also needed for PCR. A two-step PCR containing a first step of 10 cycles, followed by a second step of 20 cycles, differing only in the annealing conditions was used. A single-step PCR combining the two different cycle conditions could also be used successfully. Optimal conditions for gene synthesis (and amplification) are described. Human and porcine colipase genes (297 and 309 bp, respectively) have been successfully synthesized, cloned into the Invitrogen TA cloning vector and sequenced. There was absolutely no error in the clones that were sequenced.     

Bacteriophage T4 RNase H removes both RNA primers and adjacent DNA from the 5' end of lagging strand fragments

Bacteriophage T4 RNase H belongs to a family of prokaryotic and eukaryotic nucleases that remove RNA primers from lagging strand fragments during DNA replication. Each enzyme has a flap endonuclease activity, cutting at or near the junction between single- and double-stranded DNA, and a 5'- to 3'-exonuclease, degrading both RNA.DNA and DNA.DNA duplexes. On model substrates for lagging strand synthesis, T4 RNase H functions as an exonuclease removing short oligonucleotides, rather than as an endonuclease removing longer flaps created by the advancing polymerase. The combined length of the DNA oligonucleotides released from each fragment ranges from 3 to 30 nucleotides, which corresponds to one round of processive degradation by T4 RNase H with 32 single-stranded DNA-binding protein present. Approximately 30 nucleotides are removed from each fragment during coupled leading and lagging strand synthesis with the complete T4 replication system. We conclude that the presence of 32 protein on the single-stranded DNA between lagging strand fragments guarantees that the nuclease will degrade processively, removing adjacent DNA as well as the RNA primers, and that the difference in the relative rates of synthesis and hydrolysis ensures that there is usually only a single round of degradation during each lagging strand cycle.     

Use of Modified Flap Structures for Study of Base Excision Repair Proteins

To investigate interactions between proteins participating in the long-patch pathway of base excision repair (BER), DNA duplexes with flap strand containing modifications in sugar phosphate backbone within the flap-forming oligonucleotides were designed. When the flap-forming oligonucleotide consisted of two sequences bridged by a decanediol linker located in the flap strand near the branch point, the efficiency and position of cleavage by flap endonuclease 1 (FEN1) differed from those for natural flap. The cleavage rate of chimeric structure by FEN1 was lower than that of a normal substrate. When we introduced the second modification in the flap-forming oligonucleotide, the cleavage rate decreased significantly. To estimate efficiency of recognition and processing of the chimeric structures by BER proteins, we studied the rate of DNA synthesis by DNA polymerase beta (Pol beta) and the rate of nucleotide excision at the 3'-end of the initiating primer by apurinic/apyrimidinic endonuclease 1 (APE1) compared with those for the natural DNA duplexes. Efficiency of strand-displacement DNA synthesis catalyzed by Pol beta was shown to be higher for flap structures containing non-nucleotide linkers. The chimeric structures were processed by the 3'-exonuclease activity of APE1 with efficiency lower than that for a normal flap structure. Thus, DNA duplexes with modifications in sugar phosphate backbone can be used to mimic intermediates of the long-patch pathway of BER in reconstituted systems containing FEN1. Based on chimeric and natural oligonucleotides, photoreactive DNA structures were designed. The photoreactive dCMP moiety was introduced into the 3'-end of DNA primer via the activity of Pol beta. The photoreactive DNA duplexes--3'-recessed DNA, nicked DNA, and flap structures containing natural and chimeric oligonucleotides--were used for photoaffinity labeling of BER proteins.     

Deletion analysis of the cloned replication origin region from bacteriophage M13.

A cloned 270-nucleotide fragment from the origin region of the M13 duplex replicative form DNA confers an M13-dependent replication mechanism upon the plasmid vector pBR322. This M13 insert permits M13 helper-dependent replication of the hybrid plasmid in polA cells which are unable to replicate the pBR322 replicon alone. Using in vitro techniques, we have constructed several plasmids containing deletions in the M13 DNa insert. The endpoints of these deletions have been determined by DNA sequence analysis and correlated with the transformation and replication properties of each plasmid. Characterization of these deletion plasmids allows the following conclusions. (i) The initiation site for M13 viral strand replication is required for helper-dependent propagation of the chimeric plasmid. (ii) A DNA sequence in the M13 insert, localized between 89 and 129 nucleotides from the viral strand initiation site, is necessary for efficient transformation of polA cells. A chimeric plasmid containing the viral strand initiation site, but lacking this additional 40 nucleotide M13 sequence, transforms helper-infected cells at a frequency approximately 10(4)-fold less than that of plasmids containing this additional DNA segment. (iii) The entire M13 complementary strand origin can be deleted without affecting M13-dependent transformation by the hybrid plasmids. We propose a model in which replication of one strand of duplex chimera initiates by nicking at the gene II protein nicking site in the viral strand of the M13 insert, followed by asymmetric single-strand synthesis. Initiation of the complementary strand possibly occurs within plasmid sequences.     

Both substrate and target oligonucleotide sequences affect in vitro integration mediated by human immunodeficiency virus type 1 integrase protein produced in Saccharomyces cerevisiae.

Integration of retroviral DNA into the host cell genome requires the interaction of retroviral integrase (IN) protein with the outer ends of both viral long terminal repeats (LTRs) to remove two nucleotides from the 3' ends (3' processing) and to join the 3' ends to newly created 5' ends in target DNA (strand transfer). We have purified the IN protein of human immunodeficiency virus type 1 (HIV-1) after production in Saccharomyces cerevisiae and found it to have many of the properties described for retroviral IN proteins. The protein performs both 3' processing and strand transfer reactions by using HIV-1 or HIV-2 attachment (att) site oligonucleotides. A highly conserved CA dinucleotide adjacent to the 3' processing site of HIV-1 is important for both the 3' processing and strand transfer reactions; however, it is not sufficient for full IN activity, since alteration of nucleotide sequences internal to the HIV-1 U5 CA also impairs IN function, and Moloney murine leukemia virus att site oligonucleotides are poor substrates for HIV-1 IN. When HIV-1 att sequences are positioned internally in an LTR-LTR circle junction substrate, HIV-1 IN fails to cleave the substrate preferentially at positions coinciding with correct 3' processing, implying a requirement for positioning att sites near DNA ends. The 2 bp normally located beyond the 3' CA in linear DNA are not essential for in vitro integration, since mutant oligonucleotides with single-stranded 3' or 5' extensions or with no residues beyond the CA dinucleotide are efficiently used. Selection of target sites is nonrandom when att site oligonucleotides are joined to each other in vitro. We modified an in vitro assay to distinguish oligonucleotides serving as the substrate for 3' processing and as the target for strand transfer. The modified assay demonstrates that nonrandom usage of target sites is dependent on the target oligonucleotide sequence and independent of the oligonucleotide used as the substrate for 3' processing.     

Determination of a nucleotide sequence in bacteriophage f1 DNA by primed synthesis with DNA polymerase

A method is described for the determination of nucleotide sequences in DNA by using specific oligonucleotides as primers for copying specific regions by DNA polymerase. The method was applied to bacteriophage f1 DNA using the synthetic octanucleotide A-C-C-A-T-C-C-A as primer and a sequence (sequence A) of 81 nueleotides was determined. Synthesis was carried out in the presence of manganese and with one of the deoxyribotriphosphates (dCTP or dGTP) replaced by the corresponding ribotriphosphate so that mixed oligonucleotides were found which could be specifically split at the ribonucleotide residues by the appropriate ribonuclease or by alkali. The relative order of the digestion products was determined by fractionating the undigested oligonucleotides according to size on a two-dimensional system and digesting the isolated products. In the presence of rGTP the octanucleotide appeared to prime at a second site giving rise to a second sequence (B) besides sequence A. The complementary sequence to sequence A, which corresponds to the plus strand of f1 DNA and to the messenger RNA, contains five nonsense codons, four of which are in the same phase, and two possible initiation codons. It also contains a repetitive sequence which suggests its evolutionary origin by duplication.     

Listeria monocytogenes induces host DNA damage and delays the host cell cycle to promote infection

Listeria monocytogenes (Lm) is a human intracellular pathogen widely used to uncover the mechanisms evolved by pathogens to establish infection. However, its capacity to perturb the host cell cycle was never reported. We show that Lm infection affects the host cell cycle progression, increasing its overall duration but allowing consecutive rounds of division. A complete Lm infectious cycle induces a S-phase delay accompanied by a slower rate of DNA synthesis and increased levels of host DNA strand breaks. Additionally, DNA damage/replication checkpoint responses are triggered in an Lm dose-dependent manner through the phosphorylation of DNA-PK, H2A.X, and CDC25A and independently from ATM/ATR. While host DNA damage induced exogenously favors Lm dissemination, the override of checkpoint pathways limits infection. We propose that host DNA replication disturbed by Lm infection culminates in DNA strand breaks, triggering DNA damage/replication responses, and ensuring a cell cycle delay that favors Lm propagation.     

Targeted nucleotide repair of cyc1 mutations in Saccharomyces cerevisiae directed by modified single-stranded DNA oligonucleotides

Modified single-stranded DNA oligonucleotides have been used to direct base changes in the CYC1 gene of Saccharomyces cerevisiae. In this process, the oligonucleotide is believed to hybridize to the target site through the action of a DNA recombinase and, once bound, DNA repair enzymes act to excise the nucleotide, replace it, and revert the gene to wild-type status. Nucleotide exchange exhibits a strand bias as, in most cases, a higher level of base reversal appears in cells in which the oligonucleotide is designed to hybridize to the nontemplate strand. But, in one case, a higher level was observed when an oligonucleotide complementary to the transcribed strand was used. Mutant haploid and diploid strains are reverted to wild type at this locus with approximately the same frequency and all strains take up the oligonucleotide with approximately equal efficiency. Some repair preference for certain base mismatches was observed; for example, T/T and C/C mispairs exhibited the highest degree of reactivity. Finally, we demonstrate that proteins involved in DNA pairing can enhance the repair activity up to 22-fold, while others affect the reaction minimally. Taken together, these results confirm the importance and versatility of yeast as a model system to elucidate the factors regulating the frequency of nucleotide exchange directed by oligonucleotides.     

Mapping of HIV-1 integrase preferences for target site selection with various oligonucleotides

HIV integrase (IN) catalyzes the insertion of proviral DNA into the host cell chromosome. While IN has strict sequence requirements for the viral cDNA ends, the integration site preference has been shown to be very diverse. Here, we mapped the HIV IN strand transfer reaction requirements using various short oligonucleotides (ON) that mimic the target DNA. Most double stranded DNA dodecamers served as excellent IN targets with variable integration efficiency depending mostly on the ON sequences. The preferred integration was lost with any changes in the geometry of the DNA double helical structures. Various hairpin-loop-forming ONs also served as efficient integration targets. Similar integration preferences were also observed for ONs, in which the nucleotide hairpin loop was replaced with a flexible aliphatic linker. The integration biases with all target DNA structures tested were significantly influenced by changes in the resulting secondary ON structures.     

Reaction parameters of targeted gene repair in mammalian cells

Targeted gene repair uses short DNA oligonucleotides to direct a nucleotide exchange reaction at a designated site in a mammalian chromosome. The widespread use of this technique has been hampered by the inability of workers to achieve robust levels of correction. Here, we present a mammalian cell system in which DLD-1 cells bearing integrated copies of a mutant eGFP gene are repaired by modified single-stranded DNA oligonucleotides. We demonstrate that two independent clonal isolates, which are transcribed at different levels, are corrected at different frequencies. We confirm the evidence of a strand bias observed previously in other systems, wherein an oligonucleotide designed to be complementary to the nontranscribed strand of the target directs a higher level of repair than one targeting the transcribed strand. Higher concentrations of cell oligonucleotides in the electroporation mixture lead to higher levels of correction. When the target cell population is synchronized into S phase then released before electroporation, the correction efficiency is increased within the entire population. This model system could be useful for pharmacogenomic applications of targeted gene repair including the creation of cell lines containing single-base alterations.     

Mutagenesis at a specific position in a DNA sequence

Predefined changes in a known DNA sequence were introduced by a general method. Oligodeoxyribonucleotides complementary to positions 582 to 593 of the viral DNA strand of the bacteriophage phiX174 am3 mutant (pGTATCCTACAAA), and to the wild type sequence in this region (pGTATCCTACAAA), were synthesized and used as specific mutagens. Each of these oligonucleotides was incorporated into a complete circular complementary strand when used as primer on a genetically heterologous viral strand template, by the combined action of subtilisin-treated Escherichia coli DNA polymerase I and T4 DNA ligase. Incomplete duplexes were removed or were inactivated by nuclease S1 and the products were used to transfect spheroplasts of E. coli. Both oligonucleotides induced specific mutations at high efficiency when used with heterologous template (15% mutants among progeny phage). The am phages isolated by this procedure are phenotypically gene E mutants, and contain A at position 587 of the viral strand. They thus appear identical with am3 and provide evidence that the change G leads to A at position 587 is sufficient to produce a defective E function. Since the template for the induction of am mutants carried another genetic marker (sB1), the strains carrying the induced mutations have the new genotype am3 sB1. It should be possible to introduce the am3 mutation into any known mutant strain of phi174 using this same oligonucleotide. Both possible transition mutations were induced in these experiments. In principle, the method could also induce transversions, insertions, and deletions. The method should be applicable to other circular DNAs of similar size, for example recombinant DNA plasmids.