The role of palindromic and non-palindromic sequences in arresting DNA synthesis in vitro and in vivo

The DNA-Binding Domain of S. pombe Mrc1 (Claspin) Acts to Enhance Stalling at Replication Barriers

During S-phase replication forks can stall at specific genetic loci. At some loci, the stalling events depend on the replisome components Schizosaccharomyces pombe Swi1 (Saccharomyces cerevisiae Tof1) and Swi3 (S. cerevisiae Csm3) as well as factors that bind DNA in a site-specific manner. Using a new genetic screen we identified Mrc1 (S. cerevisiae Mrc1/metazoan Claspin) as a replisome component involved in replication stalling. Mrc1 is known to form a sub-complex with Swi1 and Swi3 within the replisome and is required for the intra-S phase checkpoint activation. This discovery is surprising as several studies show that S. cerevisiae Mrc1 is not required for replication barrier activity. In contrast, we show that deletion of S. pombe mrc1 leads to an approximately three-fold reduction in barrier activity at several barriers and that Mrc1’s role in replication fork stalling is independent of its role in checkpoint activation. Instead, S. pombe Mrc1 mediated fork stalling requires the presence of a functional copy of its phylogenetically conserved DNA binding domain. Interestingly, this domain is on the sequence level absent from S. cerevisiae Mrc1. Our study indicates that direct interactions between the eukaryotic replisome and the DNA are important for site-specific replication stalling.

Probing mercury(II)-DNA interactions by nanopore stochastic sensing

In this work, DNA-Hg(II) interactions were investigated by monitoring the translocation of DNA hairpins in a protein ion channel in the absence and presence of metal ions. Our experiments demonstrate that target-specific hairpin structures could be stabilized much more significantly by mercuric ions than by the stem length and the loop size of the hairpin due to the formation of Thymine-Hg(II)-Thymine complexes. In addition, the designed DNA probe allows the development of a highly sensitive nanopore sensor for Hg(2+) with a detection limit of 25 nM. Further, the sensor is specific, and other tested metal ions including Pb(2+), Cu(2+), Cd(2+), and so on with concentrations of up to 2 orders of magnitude greater than that of Hg(2+) would not interfere with the mercury detection.

Polyomavirus JC in the context of immunosuppression: a series of adaptive, DNA replication-driven recombination events in the development of progressive multifocal leukoencephalopathy

Polyomavirus JC (JCV) is the etiological agent of progressive multifocal leukoencephalopathy (PML), a demyelinating infection of oligodendrocytes in the brain. PML, a frequently fatal opportunistic infection in AIDS, has also emerged as a consequence of treatment with several new immunosuppressive therapeutic agents. Although nearly 80% of adults are seropositive, JCV attains an ability to infect glial cells in only a minority of people. Data suggest that JCV undergoes sequence alterations that accompany this ability, and these changes can be derived from an archetype strain by mutation, deletion, and duplication. While the introductory source and primary tissue reservoir of JCV remain unknown, lymphoid cells have been identified as potential intermediaries in progression of JCV to the brain. This review is focused on sequence changes in the noncoding control region (NCCR) of the virus. We propose an adaptive mechanism that involves a sequential series of DNA replication-driven NCCR recombination events involving stalled DNA replication forks at NCCR palindromic secondary structures. We shall describe how the NCCR sequence changes point to a model in which viral DNA replication drives NCCR recombination, allowing JCV adaptation to different cell types in its progression to neurovirulence.

Replication fork stalling and checkpoint activation by a PKD1 locus mirror repeat polypurine-polypyrimidine (Pu-Py) tract

DNA sequences prone to forming noncanonical structures (hairpins, triplexes, G-quadruplexes) cause DNA replication fork stalling, activate DNA damage responses, and represent hotspots of genomic instability associated with human disease. The 88-bp asymmetric polypurine-polypyrimidine (Pu-Py) mirror repeat tract from the human polycystic kidney disease (PKD1) intron 21 forms non-B DNA secondary structures in vitro. We show that the PKD1 mirror repeat also causes orientation-dependent fork stalling during replication in vitro and in vivo. When integrated alongside the c-myc replicator at an ectopic chromosomal site in the HeLa genome, the Pu-Py mirror repeat tract elicits a polar replication fork barrier. Increased replication protein A (RPA), Rad9, and ataxia telangiectasia- and Rad3-related (ATR) checkpoint protein binding near the mirror repeat sequence suggests that the DNA damage response is activated upon replication fork stalling. Moreover, the proximal c-myc origin of replication was not required to cause orientation-dependent checkpoint activation. Cells expressing the replication fork barrier display constitutive Chk1 phosphorylation and continued growth, i.e. checkpoint adaptation. Excision of the Pu-Py mirror repeat tract abrogates the DNA damage response. Adaptation to Chk1 phosphorylation in cells expressing the replication fork barrier may allow the accumulation of mutations that would otherwise be remediated by the DNA damage response.

Genetic variability of human respiratory syncytial virus A strains circulating in Ontario: a novel genotype with a 72 nucleotide G gene duplication

Human respiratory syncytial virus (HRSV) is the main cause of acute lower respiratory infections in children under 2 years of age and causes repeated infections throughout life. We investigated the genetic variability of RSV-A circulating in Ontario during 2010–2011 winter season by sequencing and phylogenetic analysis of the G glycoprotein gene.

Among the 201 consecutive RSV isolates studied, RSV-A (55.7%) was more commonly observed than RSV-B (42.3%). 59.8% and 90.1% of RSV-A infections were among children ≤12 months and ≤5 years old, respectively. On phylogenetic analysis of the second hypervariable region of the 112 RSV-A strains, 110 (98.2%) clustered within or adjacent to the NA1 genotype; two isolates were GA5 genotype. Eleven (10%) NA1-related isolates clustered together phylogenetically as a novel RSV-A genotype, named ON1, containing a 72 nucleotide duplication in the C-terminal region of the attachment (G) glycoprotein. The predicted polypeptide is lengthened by 24 amino acids and includes a23 amino acid duplication. Using RNA secondary structural software, a possible mechanism of duplication occurrence was derived. The 23 amino acid ON1 G gene duplication results in a repeat of 7 potential O-glycosylation sites including three O-linked sugar acceptors at residues 270, 275, and 283. Using Phylogenetic Analysis by Maximum Likelihood analysis, a total of 19 positively selected sites were observed among Ontario NA1 isolates; six were found to be codons which reverted to the previous state observed in the prototype RSV-A2 strain. The tendency of codon regression in the G-ectodomain may infer a decreased avidity of antibody to the current circulating strains. Further work is needed to document and further understand the emergence, virulence, pathogenicity and transmissibility of this novel RSV-A genotype with a72 nucleotide G gene duplication.

Mechanism of strand displacement synthesis by DNA replicative polymerases

Replicative holoenzymes exhibit rapid and processive primer extension DNA synthesis, but inefficient strand displacement DNA synthesis. We investigated the bacteriophage T4 and T7 holoenzymes primer extension activity and strand displacement activity on a DNA hairpin substrate manipulated by a magnetic trap. Holoenzyme primer extension activity is moderately hindered by the applied force. In contrast, the strand displacement activity is strongly stimulated by the applied force; DNA polymerization is favoured at high force, while a processive exonuclease activity is triggered at low force. We propose that the DNA fork upstream of the holoenzyme generates a regression pressure which inhibits the polymerization-driven forward motion of the holoenzyme. The inhibition is generated by the distortion of the template strand within the polymerization active site thereby shifting the equilibrium to a DNA-protein exonuclease conformation. We conclude that stalling of the holoenzyme induced by the fork regression pressure is the basis for the inefficient strand displacement synthesis characteristic of replicative polymerases. The resulting processive exonuclease activity may be relevant in replisome disassembly to reset a stalled replication fork to a symmetrical situation. Our findings offer interesting applications for single-molecule DNA sequencing.

Evolution of coordinated mutagenesis and somatic hypermutation in VH5

The VH5 human antibody gene was analyzed using a computer program (mfg) which simulates transcription, to better understand transcription-driven mutagenesis events that occur during "phase 1" of somatic hypermutation. Results show that the great majority of mutations in the non-transcribed strand occur within loops of two predicted high-stability stem-loop structures, termed SLSs 14.9 and 13.9. In fact, 89% of the 2505 mutations reported are within the encoded complementarity-determining region (CDR) and occur in loops of these high-stability structures. In vitro studies were also done and verified the existence of SLS 14.9. Following the formation of SLSs 14.9 and 13.9, a sustained period of transcriptional activity occurs within a window size of 60-70 nucleotides. During this period, the stability of these two SLSs does not change, and may provide the substrate for base exchanges and mutagenesis. The data suggest that many mutable bases are exposed simultaneously at pause sites, allowing for coordinated mutagenesis.

Cationic modified nucleic acids for use in DNA hairpins and parallel triplexes

Non-nucleosidic DNA monomers comprising partially protonated amines at low pH have been designed and synthesized. The modifications were incorporated into DNA oligonucleotides via standard DNA phosphoramidite synthesis. The ability of cationic modifications to stabilize palindromic DNA hairpins and parallel triplexes were evaluated using gel electrophoresis, circular dichroism and thermal denaturation measurements. The non-nucleosidic modifications were found to increase the thermal stability of palindromic hairpins at pH 8.0 as compared with a nucleosidic tetraloop (TCTC). Incorporation of modifications at the 5'-end of a triplex forming oligonucleotide resulted in a significant increase in thermal stability at low pH when the modifications were placed as the 5'-dangling end.

Active site mutations in mammalian DNA polymerase delta alter accuracy and replication fork progression

DNA polymerase δ (pol δ) is one of the two main replicative polymerases in eukaryotes; it synthesizes the lagging DNA strand and also functions in DNA repair. In previous work, we demonstrated that heterozygous expression of the pol δ L604G variant in mice results in normal life span and no apparent phenotype, whereas a different substitution at the same position, L604K, is associated with shortened life span and accelerated carcinogenesis. Here, we report in vitro analysis of the homologous mutations at position Leu-606 in human pol δ. Four-subunit human pol δ variants that harbor or lack 3' → 5'-exonucleolytic proofreading activity were purified from Escherichia coli. The pol δ L606G and L606K holoenzymes retain catalytic activity and processivity similar to that of wild type pol δ. pol δ L606G is highly error prone, incorporating single noncomplementary nucleotides at a high frequency during DNA synthesis, whereas pol δ L606K is extremely accurate, with a higher fidelity of single nucleotide incorporation by the active site than that of wild type pol δ. However, pol δ L606K is impaired in the bypass of DNA adducts, and the homologous variant in mouse embryonic fibroblasts results in a decreased rate of replication fork progression in vivo. These results indicate that different substitutions at a single active site residue in a eukaryotic polymerase can either increase or decrease the accuracy of synthesis relative to wild type and suggest that enhanced fidelity of base selection by a polymerase active site can result in impaired lesion bypass and delayed replication fork progression.

Single-molecule study of DNA polymerization activity of HIV-1 reverse transcriptase on DNA templates

HIV-1 RT (human immunodeficiency virus-1 reverse transcriptase) is a multifunctional polymerase responsible for reverse transcription of the HIV genome, including DNA replication on both RNA and DNA templates. During reverse transcription in vivo, HIV-1 RT replicates through various secondary structures on RNA and single-stranded DNA (ssDNA) templates without the need for a nucleic acid unwinding protein, such as a helicase. In order to understand the mechanism of polymerization through secondary structures, we investigated the DNA polymerization activity of HIV-1 RT on long ssDNA templates using a multiplexed single-molecule DNA flow-stretching assay. We observed that HIV-1 RT performs fast primer extension DNA synthesis on single-stranded regions of DNA (18.7 nt/s) and switches its activity to slow strand displacement synthesis at DNA hairpin locations (2.3 nt/s). Furthermore, we found that the rate of strand displacement synthesis is dependent on the GC content in hairpin stems and template stretching force. This indicates that the strand displacement synthesis occurs through a mechanism that is neither completely active nor passive: that is, the opening of the DNA hairpin is driven by a combination of free energy released during dNTP (deoxyribonucleotide triphosphate) hydrolysis and thermal fraying of base pairs. Our experimental observations provide new insight into the interchanging modes of DNA replication by HIV-1 RT on long ssDNA templates.

Checkpoint responses to unusual structures formed by DNA repeats

DNA sequences that are prone to adopting non-B DNA secondary structures are associated with hotspots of genomic instability. The fine mechanisms by which alternative DNA structures induce phenomena such as repeat expansions, chromosomal fragility, or gross chromosomal rearrangements are under intensive studies. It is well established that DNA damage checkpoint responses play a crucial role in maintaining a stable genome. It is far less clear, however, whether and how the checkpoint machinery responds to alternative DNA structures. This review discusses the role of the interplay between DNA damage checkpoints and alternative DNA structures in genome maintenance.

I. VH gene transcription creates stabilized secondary structures for coordinated mutagenesis during somatic hypermutation

During the adaptive immune response, antigen challenge triggers a million-fold increase in mutation rates in the variable-region antibody genes. The frequency of mutation is causally and directly linked to transcription, which provides ssDNA and drives supercoiling that stabilizes secondary structures containing unpaired, intrinsically mutable bases. Simulation analysis of transcription in VH5 reveals a dominant 65nt secondary structure in the non-transcribed strand containing six sites of mutable ssDNA that have also been identified independently in human B cell lines and in primary mouse B cells. This dominant structure inter-converts briefly with less stable structures and is formed repeatedly during transcription, due to periodic pauses and backtracking. In effect, this creates a stable yet dynamic "mutability platform" consisting of ever-changing patterns of unpaired bases that are simultaneously exposed and therefore able to coordinate mutagenesis. Such a complex of secondary structures may be the source of ssDNA for enzyme-based diversification, which ultimately results in high affinity antibodies.

Gross genomic rearrangements involving deletions in the CFTR gene: characterization of six new events from a large cohort of hitherto unidentified cystic fibrosis chromosomes and meta-analysis of the underlying mechanisms

Gross genomic rearrangements involving deletions in the CFTR gene have recently been found to account for approximately 20% of unidentified cystic fibrosis (CF) chromosomes in both French and Italian patients. Using QMPSF and walking quantitative DHPLC, six novel mutations (three simple deletions, two complex deletions with short insertions of 3-6 bp, and a complex deletion with a 182 bp inverted downstream sequence) were characterized by screening 274 unidentified CF chromosomes from 10 different countries. These lesions increase the total number of fully characterized large CFTR genomic rearrangements involving deletions to 21. Systematic analysis of the 42 associated breakpoints indicated that all 21 events were caused by nonhomologous recombination. Whole gene complexity analysis revealed a significant correlation between regions of low sequence complexity and the locations of the deletion breakpoints. Known recombination-promoting motifs were noted in the vicinity of the breakpoints. A total of 11 simple deletions were potentially explicable in terms of the classical model of replication slippage. However, the complex deletions appear to have arisen via multiple mechanisms; three of the five complex deletions with short insertions and both examples of large inverted insertions (299 and 182 bp, respectively) can be explained by either a model of serial replication slippage in cis (SRScis) or SRS in trans (SRStrans). Finally, the nature and distribution of large genomic rearrangements in the CFTR gene were compared and contrasted with those of two other genes, DMD and MSH2, with a view to gaining a broader understanding of DNA sequence context in mediating the diverse underlying mutational mechanisms.

AT-rich sequences from the arbuscular mycorrhizal fungus Gigaspora rosea exhibit ARS function in the yeast Saccharomyces cerevisiae

Autonomous replicating sequences are DNA elements that trigger DNA replication and are widely used in the development of episomal transformation vectors for fungi. In this paper, a genomic library from the mycorrhizal fungus Gigaspora rosea was constructed in the integrative plasmid YIp5 and screened in the budding yeast Saccharomyces cerevisiae for sequences that act as ARS and trigger plasmid replication. Two genetic elements (GrARS2, GrARS6) promoted high-rates of yeast transformation. Sequence analysis of these elements shows them to be AT-rich (72-80%) and to contain multiple near-matches to the yeast autonomous consensus sequences ACS and EACS. GrARS2 contained a putative miniature inverted-repeat transposable element (MITE) delimited by 28-bp terminal inverted repeats (TIRs). Disruption of this element and removal of one TIR increased plasmid stability several fold. The potential for palindromes to affect DNA replication is discussed.

Synthesis and bioconjugation of diene-modified oligonucleotides

The preparation of diene-modified oligonucleotides as well as their properties and further derivatization are described. Self-complementary oligonucleotides containing a diene moiety in the loop region form stable, hairpin-like secondary structures. These hairpin mimics can be further derivatized via the Diels-Alder reaction. Diene modification in the stem region leads, in contrast, to a marked destabilization of the hairpin structure. No further reduction in stability is observed, however, upon conjugation of the stem-modified derivatives via the Diels-Alder reaction with an N-substituted maleimide dienophile.

DNA replication origin plasticity and perturbed fork progression in human inverted repeats

The stability of metazoan genomes during their duplication depends on the spatiotemporal activation of origins and the progression of forks. Human rRNA genes represent a unique challenge to DNA replication since a large proportion of them exist as noncanonical palindromes in addition to canonical tandem repeats. Whether origin usage and/or fork elongation can cope with the variable structure of these genes is unknown. By analyzing single combed DNA molecules from HeLa cells, we studied the rRNA gene replication program according to the organization of canonical versus noncanonical rRNA genes. Origin positioning, spacing, and timing were not affected by the underlying rRNA gene physical structure. Conversely, fork arrest, both temporary and permanent, occurred more frequently when rRNA gene palindromes were encountered. These findings reveal that while initiation mechanisms are flexible enough to adapt to an rRNA gene structure of any arrangement, palindromes represent obstacles to fork progression, which is a likely source of genomic instability.

A Metal-Coordinating DNA Hairpin Mimic

A self-complementary oligodeoxynucleotide containing a 6,6"-substituted terpyridine was found to adopt a highly stable, hairpin-like structure. In addition to serving as a hairpin-loop mimic, the terpyridine can act as a coordination site for metals. Thus, the binding of several divalent transition metals (Zn(2+), Co(2+), Ni(2+), Cu(2+) and Pd(2+)) to the terpyridine hairpin mimic was investigated. The terpyridine-modified hairpin mimic forms a stable secondary structure in the presence of these metals. The stability of the metal-coordinated hairpin mimic was found to be lower than in the absence of metal. Furthermore, the T(m) of the metallohairpin is strongly influenced by the type of the bound metal, with T(m)'s increasing in the order Co(2+) approximately Ni(2+) < Zn(2+) < Cu(2+) < Pd(2+). Model considerations suggest that a conformational change of the terpyridine ligand is required to allow coordination of the metal.

How transcription factors regulate origins of DNA replication in eukaryotic cells

Eukaryotic chromosomes contain a few thousand origins of DNA replication, which are activated in a temporal and spatial order during S phase. One parameter that is strongly implicated in determining the order of replication is transcription. This review focuses on the role of transcription factors in activating origins of replication in eukaryotic cells. Studies of viral and mitochondrial replication origins have revealed several mechanisms by which transcription factors activate origins, but it remains to be seen whether any of these are used to regulate cellular chromosome replication.

Translocation and gross deletion breakpoints in human inherited disease and cancer I: Nucleotide composition and recombination-associated motifs

Translocations and gross deletions are important causes of both cancer and inherited disease. Such gene rearrangements are nonrandomly distributed in the human genome as a consequence of selection for growth advantage and/or the inherent potential of some DNA sequences to be frequently involved in breakage and recombination. Using the Gross Rearrangement Breakpoint Database [GRaBD; www.uwcm.ac.uk/uwcm/mg/grabd/grabd.html] (containing 397 germ-line and somatic DNA breakpoint junction sequences derived from 219 different rearrangements underlying human inherited disease and cancer), we have analyzed the sequence context of translocation and deletion breakpoints in a search for general characteristics that might have rendered these sequences prone to rearrangement. The oligonucleotide composition of breakpoint junctions and a set of reference sequences, matched for length and genomic location, were compared with respect to their nucleotide composition. Deletion breakpoints were found to be AT-rich whereas by comparison, translocation breakpoints were GC-rich. Alternating purine-pyrimidine sequences were found to be significantly over-represented in the vicinity of deletion breakpoints while polypyrimidine tracts were over-represented at translocation breakpoints. A number of recombination-associated motifs were found to be over-represented at translocation breakpoints (including DNA polymerase pause sites/frameshift hotspots, immunoglobulin heavy chain class switch sites, heptamer/nonamer V(D)J recombination signal sequences, translin binding sites, and the chi element) but, with the exception of the translin-binding site and immunoglobulin heavy chain class switch sites, none of these motifs were over-represented at deletion breakpoints. Alu sequences were found to span both breakpoints in seven cases of gross deletion that may thus be inferred to have arisen by homologous recombination. Our results are therefore consistent with a role for homologous unequal recombination in deletion mutagenesis and a role for nonhomologous recombination in the generation of translocations.

External-loop free energy affects dye-labeled terminators premature terminations in DNA cycle-sequencing reactions

Although dideoxy terminators labeled with energy-transfer dyes (BigDyes) provide the most versatile method of automated DNA sequencing, premature terminations result in a substantially reduced reading length of the DNA sequence. I recently demonstrated that combining the annealing step with the extension step at a single temperature (60 degrees C) reduces premature terminations of DNA sequences that ordinarily contain premature terminations when three temperature steps are used in sequencing. I studied a novel class of DNA sequences of 100-bp length and located upstream from the point that causes premature terminations. I determined the thermodynamics of 49 DNA sequences with premature terminations at three temperature steps by using DNA mfold profiles. Sequencing results for 28 samples were improved with two-step cycle sequencing, whereas two-step cycle-sequencing reactions did not improve the results for 21 sequences. Nearest-neighbor thermodynamic parameters for all 49 sequences were compared at temperatures 50 degrees C and 60 degrees C. The parameters predicted that thermodynamic free-base (external-loop) energies (delta delta G degree) were significantly different for these two study groups of samples. The results indicate that changes in free energy in single-strand base (external-loop) sequences can have a significant effect in reducing premature terminations in DNA sequencing reactions run with energy-transfer-based fluorescent-dye terminators.

Replication slippage involves DNA polymerase pausing and dissociation

Genome rearrangements can take place by a process known as replication slippage or copy-choice recombination. The slippage occurs between repeated sequences in both prokaryotes and eukaryotes, and is invoked to explain microsatellite instability, which is related to several human diseases. We analysed the molecular mechanism of slippage between short direct repeats, using in vitro replication of a single-stranded DNA template that mimics the lagging strand synthesis. We show that slippage involves DNA polymerase pausing, which must take place within the direct repeat, and that the pausing polymerase dissociates from the DNA. We also present evidence that, upon polymerase dissociation, only the terminal portion of the newly synthesized strand separates from the template and anneals to another direct repeat. Resumption of DNA replication then completes the slippage process.

Mechanisms of dinucleotide repeat instability in Escherichia coli

The high level of polymorphism of microsatellites has been used for a variety of purposes such as positional cloning of genes associated with diseases, forensic medicine, and phylogenetic studies. The discovery that microsatellites are associated with human diseases, not only as markers of risk but also directly in disease pathogenesis, has triggered a renewed interest in understanding the mechanism of their instability. In this work we have investigated the role of DNA replication, long patch mismatch repair, and transcription on the genetic instability of all possible combinations of dinucleotide repeats in Escherichia coli. We show that the (GpC) and (ApT) self-complementary sequence repeats are the most unstable and that the mode of replication plays an important role in their instability. We also found that long patch mismatch repair is involved in avoiding both short deletion and expansion events and also in instabilities resulting from the processing of bulges of 6 to 8 bp for the (GpT/ApC)- and (ApG/CpT)- containing repeats. For each dinucleotide sequence repeat, we propose models for instability that involve the possible participation of unusual secondary structures.

Eukaryotic DNA replication

One of the fundamental characteristics of life is the ability of an entity to reproduce itself, which stems from the ability of the DNA molecule to replicate itself. The initiation step of DNA replication, where control over the timing and frequency of replication is exerted, is poorly understood in eukaryotes in general, and in mammalian cells in particular. The cis-acting DNA element defining the position and providing control over initiation is the replication origin. The activation of replication origins seems to be dependent on the presence of both a particular sequence and of structural determinants. In the past few years, the development of new methods for identification and mapping of origins of DNA replication has allowed some understanding of the fundamental elements that control the replication process. This review summarizes some of the major findings of this century, regarding the mechanism of DNA replication, emphasizing what is known about the replication of mammalian DNA. J. Cell. Biochem. Suppls. 32/33:1-14, 1999.

Long inverted repeats are an at-risk motif for recombination in mammalian cells

Certain DNA sequence motifs and structures can promote genomic instability. We have explored instability induced in mouse cells by long inverted repeats (LIRs). A cassette was constructed containing a herpes simplex virus thymidine kinase (tk) gene into which was inserted an LIR composed of two inverted copies of a 1.1-kb yeast URA3 gene sequence separated by a 200-bp spacer sequence. The tk gene was introduced into the genome of mouse Ltk(-) fibroblasts either by itself or in conjunction with a closely linked tk gene that was disrupted by an 8-bp XhoI linker insertion; rates of intrachromosomal homologous recombination between the markers were determined. Recombination between the two tk alleles was stimulated 5-fold by the LIR, as compared to a long direct repeat (LDR) insert, resulting in nearly 10(-5) events per cell per generation. Of the tk(+) segregants recovered from LIR-containing cell lines, 14% arose from gene conversions that eliminated the LIR, as compared to 3% of the tk(+) segregants from LDR cell lines, corresponding to a >20-fold increase in deletions at the LIR hotspot. Thus, an LIR, which is a common motif in mammalian genomes, is at risk for the stimulation of homologous recombination and possibly other genetic rearrangements.

Generation of adenovirus vectors devoid of all viral genes by recombination between inverted repeats

Direct or inverse repeated sequences are important functional features of prokaryotic and eukaryotic genomes. Considering the unique mechanism, involving single-stranded genomic intermediates, by which adenovirus (Ad) replicates its genome, we investigated whether repetitive homologous sequences inserted into E1-deleted adenoviral vectors would affect replication of viral DNA. In these studies we found that inverted repeats (IRs) inserted into the E1 region could mediate predictable genomic rearrangements, resulting in vector genomes devoid of all viral genes. These genomes (termed DeltaAd.IR) contained only the transgene cassette flanked on both sides by precisely duplicated IRs, Ad packaging signals, and Ad inverted terminal repeat sequences. Generation of DeltaAd.IR genomes could also be achieved by coinfecting two viruses, each providing one inverse homology element. The formation of DeltaAd.IR genomes required Ad DNA replication and appeared to involve recombination between the homologous inverted sequences. The formation of DeltaAd. IR genomes did not depend on the sequence within or adjacent to the inverted repeat elements. The small DeltaAd.IR vector genomes were efficiently packaged into functional Ad particles. All functions for DeltaAd.IR replication and packaging were provided by the full-length genome amplified in the same cell. DeltaAd.IR vectors were produced at a yield of approximately 10(4) particles per cell, which could be separated from virions with full-length genomes based on their lighter buoyant density. DeltaAd.IR vectors infected cultured cells with the same efficiency as first-generation vectors; however, transgene expression was only transient due to the instability of deleted genomes within transduced cells. The finding that IRs present within Ad vector genomes can mediate precise genetic rearrangements has important implications for the development of new vectors for gene therapy approaches.

Herpes simplex virus processivity factor UL42 imparts increased DNA-binding specificity to the viral DNA polymerase and decreased dissociation from primer-template without reducing the elongation rate

Herpes simplex virus DNA polymerase consists of a catalytic subunit, Pol, and a processivity subunit, UL42, that, unlike other established processivity factors, binds DNA directly. We used gel retardation and filter-binding assays to investigate how UL42 affects the polymerase-DNA interaction. The Pol/UL42 heterodimer bound more tightly to DNA in a primer-template configuration than to single-stranded DNA (ssDNA), while Pol alone bound more tightly to ssDNA than to DNA in a primer-template configuration. The affinity of Pol/UL42 for ssDNA was reduced severalfold relative to that of Pol, while the affinity of Pol/UL42 for primer-template DNA was increased approximately 15-fold relative to that of Pol. The affinity of Pol/UL42 for circular double-stranded DNA (dsDNA) was reduced drastically relative to that of UL42, but the affinity of Pol/UL42 for short primer-templates was increased modestly relative to that of UL42. Pol/UL42 associated with primer-template DNA approximately 2-fold faster than did Pol and dissociated approximately 10-fold more slowly, resulting in a half-life of 2 h and a subnanomolar Kd. Despite such stable binding, rapid-quench analysis revealed that the rates of elongation of Pol/UL42 and Pol were essentially the same, approximately 15 [corrected] nucleotides/s. Taken together, these studies indicate that (i) Pol/UL42 is more likely than its subunits to associate with DNA in a primer-template configuration rather than nonspecifically to either ssDNA or dsDNA, and (ii) UL42 reduces the rate of dissociation from primer-template DNA but not the rate of elongation. Two models of polymerase-DNA interactions during replication that may explain these findings are presented.

Is gene deletion in eukaryotes sequence-dependent? A study of nine deletion junctions and nineteen other deletion breakpoints in intron 7 of the human dystrophin gene

Although large deletions comprise 65% of the mutations that underlie most cases of Duchenne and Becker muscular dystrophies, the DNA sequence characteristics of the deletions and the molecular processes leading to their formation are largely unknown. Intron 7 of the human dystrophin gene is unusually large (110 kb) and a substantial number of deletions have been identified with endpoints within this intron. The distribution of 28 deletion endpoints was mapped to local sequence elements by PCR. The break points were distributed among unique sequence, LINE-1, Alu, MIR, MER and microsatellite sequences with frequencies expected from the frequency of those sequences in the intron. Thus, deletions in this intron are not associated primarily with any one of those sequences in the intron. Nine deletion junctions were amplified and sequenced. Eight were deletions between DNA sequences with minimal homology (0-4 bp) and are therefore unlikely to be products of homologous recombination. In the ninth case, a complex rearrangement was found to be consistent with unequal recombinational exchange between two Alu sequences coupled with a duplication. We have hypothesized that a paucity of matrix attachment regions in this very large intron expanded by the insertion of many mobile elements might provoke a chromatin structure that stimulates deletions (McNaughton et al., 1997, Genomics 40, 294-304). The data presented here are consistent with that idea and demonstrate that the deletion sequences are not usually produced by homologous DNA misalignments.

DNA secondary structure effects on DNA synthesis catalyzed by HIV-1 reverse transcriptase

The effect of DNA secondary structure on polymerization catalyzed by human immunodeficiency virus (HIV-1) reverse transcriptase (RT) was studied using a synthetic 66-nucleotide DNA template containing a stable hairpin structure. Four RT pause sites were identified within the first half of the hairpin stem. Additionally, five weak pause sites within the second half of the stem and the loop of the hairpin were identified at low temperatures. These weak pause sites were relocated to the site of the first few stem base pairs of two new hairpins formed due to a change in DNA secondary structure. Each pause site was correlated with a high free energy barrier of melting the stem base pair. Pre-steady state kinetic analysis of single nucleotide incorporation showed that polymerization at each pause site occurred by both a fast phase (10-20 s-1) and a slow phase (0. 02-0.07 s-1) during a single binding event. The reaction amplitudes of the fast phase were small (4-10% of enzyme sites), whereas the amplitudes of the slow phase were large (14-40%) at the pause sites. In contrast, only a single phase with a large reaction amplitude (32-50%) and a fast nucleotide incorporation rate (33-87 s-1) was observed at the non-pause sites. DNA substrates at all sites had similar dissociation rates (0.14-0.29 s-1) and overall binding affinity (16-86 nM). These results suggest that the DNA substrates at pause sites were bound in both productive and non-productive states at the polymerase site of RT. The non-productively bound DNA was slowly converted into a productive state upon melting of the next stem base pair without dissociation of the DNA from RT.

Localised sequence regions possessing high melting temperatures prevent the amplification of a DNA mimic in competitive PCR

The polymerase chain reaction is an immensely powerful technique for identification and detection purposes. Increasingly, competitive PCR is being used as the basis for quantification. However, sequence length, melting temperature and primary sequence have all been shown to influence the efficiency of amplification in PCR systems and may therefore compromise the required equivalent co-amplification of target and mimic in competitive PCR. The work discussed here not only illustrates the need to balance length and melting temperature when designing a competitive PCR assay, but also emphasises the importance of careful examination of sequences for GC-rich domains and other sequences giving rise to stable secondary structures which could reduce the efficiency of amplification by serving as pause or termination sites. We present data confirming that under particular circumstances such localised sequence, high melting temperature regions can act as permanent termination sites, and offer an explanation for the severity of this effect which results in prevention of amplification of a DNA mimic in competitive PCR. It is also demonstrated that when Taq DNA polymerase is used in the presence of betaine or a proof reading enzyme, the effect may be reduced or eliminated.

The SbcCD nuclease of Escherichia coli is a structural maintenance of chromosomes (SMC) family protein that cleaves hairpin DNA

Hairpin structures can inhibit DNA replication and are intermediates in certain recombination reactions. We have shown that the purified SbcCD protein of Escherichia coli cleaves a DNA hairpin. This cleavage does not require the presence of a free (3' or 5') DNA end and generates products with 3'-hydroxyl and 5'-phosphate termini. Electron microscopy of SbcCD has revealed the "head-rod-tail" structure predicted for the SMC (structural maintenance of chromosomes) family of proteins, of which SbcC is a member. This work provides evidence consistent with the proposal that SbcCD cleaves hairpin structures that halt the progress of the replication fork, allowing homologous recombination to restore DNA replication.

Palindrome resolution and recombination in the mammalian germ line

Genetic instability is promoted by unusual sequence arrangements and DNA structures. Hairpin DNA structures can form from palindromes and from triplet repeats, and they are also intermediates in V(D)J recombination. We have measured the genetic stability of a large palindrome which has the potential to form a one-stranded hairpin or a two-stranded cruciform structure and have analyzed recombinants at the molecular level. A palindrome of 15.3 kb introduced as a transgene was found to be transmitted at a normal Mendelian ratio in mice, in striking contrast to the profound instability of large palindromes in prokaryotic systems. In a significant number of progeny mice, however, the palindromic transgene is rearranged; between 15 and 56% of progeny contain rearrangements. Rearrangements within the palindromic repeat occur both by illegitimate and homologous, reciprocal recombination. Gene conversion within the transgene locus, as quantitated by a novel sperm fluorescence assay, is also elevated. Illegitimate events often take the form of an asymmetric deletion that eliminates the central symmetry of the palindrome. Such asymmetric transgene deletions, including those that maintain one complete half of the palindromic repeat, are stabilized so that they cannot undergo further illegitimate rearrangements, and they also exhibit reduced levels of gene conversion. By contrast, transgene rearrangements that maintain the central symmetry continue to be unstable. Based on the observed events, we propose that one mechanism promoting the instability of the palindrome may involve breaks generated at the hairpin structure by a hairpin-nicking activity, as previously detected in somatic cells. Because mammalian cells are capable of efficiently repairing chromosome breaks through nonhomologous processes, the resealing of such breaks introduces a stabilizing asymmetry at the center of the palindrome. We propose that the ability of mammalian cells to eliminate the perfect symmetry in a palindromic sequence may be an important DNA repair pathway, with implications regarding the metabolism of palindromic repeats, the mutability of quasipalindromic triplet repeats, and the early steps in gene amplification events.

Overexpression, purification, and characterization of the SbcCD protein from Escherichia coli

The sbcC and sbcD genes mediate palindrome inviability in Escherichia coli. The sbcCD operon has been cloned into the plasmid pTrc99A under the control of the strong trc promoter and introduced into a strain carrying a chromosomal deletion of sbcCD. The SbcC and SbcD polypeptides were overexpressed to 6% of total cell protein, and both polypeptides copurified in a four-step purification procedure. Purified SbcCD is a processive double-strand exonuclease that has an absolute requirement for Mn2+ and uses ATP as a preferred energy source. Gel filtration chromatography and sedimentation equilibrium analyses were used to show that the SbcC and SbcD polypeptides dissociate at some stage after purification and that this dissociation is reversed by the addition of Mn2+. We demonstrate that SbcD has the potential to form a secondary structural motif found in a number of protein phosphatases and suggest that it is a metalloprotein that contains the catalytic center of the SbcCD exonuclease.

Hairpin formation during DNA synthesis primer realignment in vitro in triplet repeat sequences from human hereditary disease genes

Genetic expansion of DNA triplet repeat sequences (TRS) found in neurogenetic disorders may be due to abnormal DNA replication. We have previously observed strong DNA synthesis pausings at specific loci within the long tracts (> approximately 70 repeats) of CTG.CAG and CGG.CCG as well as GTC.GAC by primer extensions in vitro using DNA polymerases (the Klenow fragment of Escherichia coli DNA polymerase I, the modified T7 DNA polymerase (Sequenase), and human DNA polymerase beta). Herein, we have isolated and analyzed the products of stalled synthesis found at approximately 30-40 triplets from the beginning of the TRS. DNA sequence analyses revealed that the stalled products contained short tracts of homogeneous TRS (6-12 repeats) in the middle of the sequence corresponding to the flanking region of the primer-template sequence. The sequence at the 3'-side terminated at the end of the primer, indicating that the primer molecule had served as a template. In addition, chemical probe and polyacrylamide gel electrophoretic analyses revealed that the stalled products existed in hairpin structures. We postulate that these products of the DNA polymerases are caused by the existence of an unusual DNA conformation(s) within the TRS, during the in vitro DNA synthesis, enhancing the DNA slippages and the hairpin formations in the TRS due to primer realignment. The consequence of these steps is DNA synthesis to the end of the primer and termination. Primer realignment including hairpin formation may play an important intermediate role in the replication of TRS in vivo to elicit genetic expansions.

Leading strand specific spontaneous mutation corrects a quasipalindrome by an intermolecular strand switch mechanism

Imperfect inverted repeats or quasipalindromes can undergo spontaneous, often complex mutational events that correct them to perfect palindromes. Two models that depend on the quasipalindrome providing a template for a specific mutational event have been described to explain this mutation: an intramolecular and an intermolecular strand switch model. A 17bp quasipalindrome containing a -1 deletion within the chloramphenicol acetyl transferase (CAT) gene in plasmid pJT7 undergoes a spontaneous +1 frameshift mutation that creates a perfect inverted repeat and a Cm(r) phenotype. By analyzing this mutation frequency in two plasmids that contain the CAT gene in either orientation with respect to the origin of replication, we show that the specific frameshift occurs preferentially in the leading strand during DNA replication. Due to the availability and proximity of the lagging strand template as a single strand during replication of the quasipalindrome in the leading but not lagging strand, we suggest that the specificity for the leading strand correction is due to a leading strand specific intermolecular strand switch rather than an intramolecular strand switch. To test this hypothesis, we have designed a genetic selection to detect a leading strand intermolecular strand switch. This selection utilizes asymmetric quasipalindromes, one of which contains two central stop codons. When cloned into the CAT gene in pJT7, reversion to Cm(r) requires inversion of the stop codons and addition of a +1 frameshift to correct the reading frame. The inversion of the central stop codons, which is predicted by an intermolecular but not an intramolecular strand switch, occurs concomitant with the specific correction of the original 17 bp quasipalindrome. Inversion of an asymmetric center can also be demonstrated when not under selective pressure using a quasipalindrome lacking central stop codons. These results are consistent with the correction of a quasipalindrome occurring predominantly by an intermolecular strand switch during replication of the leading strand.

Single-stranded DNA-binding protein enhances the stability of CTG triplet repeats in Escherichia coli

The stability of CTG triplet repeats was analyzed in Escherichia coli to identify processes responsible for their genetic instability. Using a biochemical assay for stability, we show that the absence of single-stranded-DNA-binding protein leads to an increase in the frequency of large deletions within the triplet repeats.

Analysis and suppression of DNA polymerase pauses associated with a trinucleotide consensus

We have studied a novel class of DNA sequences that cause DNA polymerases to pause. These sequences have the central consensus Py-G-C and are not necessarily adjacent to hairpins in the DNA template. Since most consensus sequences do not cause pauses under standard conditions, additional template features must exist that make it difficult to incorporate nucleotides at these positions. We believe that these pauses result from constraints that make the conformation change involved in nucleotide selection more difficult. These pauses can obscure parts of DNA sequencing ladders and prevent DNA amplification by the polymerase chain reaction. The addition of betaine, and some related compounds, relieves these pauses.

Similar conformations of hairpins with TTT and TTTT sequences: NMR and molecular modeling evidence for T.T base pairs in the TTTT hairpin

The conformations of the d[G(1)C(2)G(3)C(4)-T(a)T(b)T(c)T(d)-G(5)C(6)G(7)C(8)] (T4) and d[G(1)C(2)G(3)C(4)-T(a)T(b)T(c)-G(5)C(6)G(7)C(8)] (T3) DNA hairpins have been studied. The 1H and 31P signals of the two hairpins have been nearly completely assigned by means of two-dimensional NMR spectroscopy in D2O (NOESY (two-dimensional nuclear Overhauser effect and exchange spectroscopy) at mixing times of 5, 50, 100, 300 and 500 ms, double-quantum-filtered correlation spectroscopy (DQF-COSY) and 1H-31P reverse chemical shift correlation (RCSC), and one-dimensional NOE spectra in 90% H2O. Conformational analysis using distance geometry (DG), molecular mechanics (MM) and molecular dynamics (MD) gave model conformations, which were evaluated by comparison of experimental and simulated 2D NOESY spectra. For the T4 sequence in T4, both NMR data and modeling indicated a T(a).T(d) wobble base pair. Although two types of T(a).T(d) base pairs are possible, the one with T(a)NH-T(d)O4 and T(a)O2-T(d)NH H-bonds was calculated to be more stable. Because the T(a).T(d) base pair of T4 extends the stem, there are only two residues (T(b) and T(c) in the loop. Although there are three residues in the T3 loop, the T(c) base projects into the solvent. The resulting conformational models have very similar loop folding patterns (FP): the bases of the two adjacent residues that begin the loop [T(b)T(c) of T4 and T(a)T(b) or T3] have a minor groove/major groove orientation with the first residue each having a trans alpha torsion angle; and the phosphodiester group that links the residues at the 3' end of the loop and the 5' top of the stem [T(c)pT(d) of T4 and T(c)pG(5) of T3] has a gauche+, gauche+ zeta,alpha conformation with a trans gamma angle for the second residue in both. These or similar features appear to be present in most of the few other hairpins studied previously by conformational methods. Thus, we believe that the conformations of the loops in T3 and T4 hairpins have greater similarities than previously recognized.

The chicken beta-globin gene promoter forms a novel "cinched" tetrahelical structure

We have previously shown that the G-rich sequence G16CG(GGT)2GG in the promoter region of the chicken beta-globin gene poses a formidable barrier to DNA synthesis in vitro (Woodford et al., 1994, J. Biol. Chem. 269, 27029-27035). The K+ requirement, template-strand specificity, template concentration independence, and involvement of Hoogsteen bonding suggested that the underlying basis of this new type of DNA synthesis arrest site might be an intrastrand tetrahelical structure. However, the arrest site lacks the four G-rich repeats that are a hallmark of previously described intramolecular tetraplexes and contains a number of noncanonical bases that would be expected to greatly destabilize such a structure. Here we report evidence for an unusual K+-dependent intrastrand "cinched" tetraplex. This structure has several unique features including the incorporation of bases other than guanine into the stem of the tetraplex, interaction between loop bases and bases in the flanking region, and base pairing between bases 3 and 5 of the tetrahelix-forming region to form a molecular "cinch." This finding extends the range of sequences capable of tetraplex formation as well as our appreciation of the conformational complexity of the chicken beta-globin promoter.

Sequences with high propensity to form G-quartet structures in kinetoplast DNA from Phytomonas serpens

Naturally occurring sequences containing repetitive guanine motifs have the potential to form tetraplex DNA. Phytomonas serpens minicircle DNA shows some regions where one strand is composed mainly of G and T (GT regions). These regions contain several stretches of contiguous guanines. An oligonucleotide was constructed with the sequence corresponding to one of these regions (Phyto-GT). It was demonstrated by native gel electrophoresis and methylation protection that Phyto-GT forms tetramolecular (G4), bimolecular (G'2) and unimolecular (G4') structures stabilized through G-quartets. Tetraplex DNA formation by this sequence could have biological relevance as it can be formed in physiological conditions and GT regions comprise approximately one-third of P. serpens and Crithidia oncopelti minicircles.

Flanking sequences affect replication arrest at the Escherichia coli terminator TerB in vivo

We have analyzed the effect of flanking sequences on Tus-induced replication arrest. pBR322 plasmid derivatives which carry the Escherichia coli replication terminator TerB at different locations were used. Efficiency of the replication arrest was estimated from the plasmid copy number and transformation frequency of tus+ cells. We found that flanking sequences do affect replication arrest efficiency, a weak arrest being correlated with the presence of an AT-rich region which is replicated just before TerB. Some sequences located after the replication terminator can also affect replication termination. We propose that the AT-rich regions might impair binding of the Tus protein to the TerB sequence or facilitate helicase-induced unwinding of DNA and Tus displacement from the TerB site.

Hairpin formation in d-AAGCTTAAGCTT under high salt conditions shows unusual properties

The hairpin-duplex equilibria of the dodecamer d-AAGCTTAAGCTT and interaction of the duplex form with a pentapeptide, KGWGK, has been studied. UV thermal transitions are monophasic at low salt but biphasic at higher salt concentrations. At 10(-5) M or less oligomer concentration biphasic melting curves persist till 900 mM NaCl. The d(Tm)/d log(Na+) for the duplex form is 12 degrees C and for the hairpin is 18 degrees C. The delta H and delta S values for duplex formation are low (-25 K cal/mole and -59 Cal/mole respectively). KGWGK binds to the duplex form with a binding constant K = 3.4 x 10(5)M-1 measured from fluorescence quenching of tryptophan. These unusual results are markedly different from that reported for d-AGATCTAGATCT (Biochemistry 31, 6241-6245) and are discussed in terms of sequence dependence of loop folding and cruciform extrusion pathway of hairpin formation.

Multiple pathways of deletion formation in Escherichia coli

We are investigating the mechanisms for deletion formation through the use of mutants which alter deletion frequency together with well characterized systems for deletion detection. We report here on three mutations which were isolated for their ability to stimulate deletions in plasmid pMC874 (dli mutations). The mutation rec-2251 (formerly known as dli1) is a new allele of recBCD, a group of genes coding for the polypeptide components of the major recombination enzyme complex in E. coli; the second one, dli2 may be a new allele of uvrD, which codes for DNA helicase II; and the third one, dli3, has the phenotype of a mismatch repair mutation. Here we compare the effects of mutations in SOS-repair genes to those of the dli mutations on three different deletion events: (a) the deletion of short (60-100-bp) palindromic and non-palindromic inserts in derivatives of plasmid pBR325; (b) larger (600-800-bp) deletions in plasmid pMC874; and (c) the excision of the Tn10 transposon from chromosomal sites. Our results indicate that some form of SOS processing stimulates the loss of palindromes but not non-palindromes in plasmid pBR325 derivatives, and that RecA is necessary for UV-induced excision of Tn10 but this event is inhibited by UmuCD or its homolog MucAB. Each of the dli mutations showed unique effects on different classes of deletions. Mutation rec-2251 stimulated specifically deletions in pMC874 but had no effect on the deletion of non-palindromes in pBR325, and reduced the incidence of the other deletion events tested including loss of palindromic inserts in pBR325 as well as Tn10 excision. Mutation dli2, on the other hand, stimulated all deletions tested to varying extents, while dli3 did not affect markedly deletion formation in pBR325 plasmids but had a large stimulatory effect on both deletions in plasmid pMC874 and Tn10 excision. These results reveal that (a) some SOS-repair functions participate in deletion formation, (b) mutations selected for altering the incidence of one class of deletions may have totally different effects on other deletion events, and (c) the differences in mutant behavior may result in part from the ability of some pathways to discriminate among different deletion intermediates such as hairpins or cruciforms formed by palindromic sequences vs. transient secondary structures stabilized by direct repeats flanking non-palindromic sequences.

Characterization of kinetoplast DNA from Phytomonas serpens

The restriction enzyme digestion of kinetoplast DNA from four Phytomonas serpens isolates shows an overall similar band pattern. One minicircle from isolate 30T was cloned and sequenced, showing low levels of homology but the same general features and organization as described for minicircles of other trypanosomatids. Extensive regions of the minicircle are composed by G and T on the H strand. These regions are very repetitive and similar to regions in a minicircle of Crithidia oncopelti and to telomeric sequences of Saccharomyces cerevisiae. Conserved Sequence Block 3, present in all trypanosomatids, is one nucleotide different from the consensus in P. serpens and provides a basis to differentiate P. serpens from other trypanosomatids. Electron microscopy of kinetoplast DNA evidenced a network with organization similar to other trypanosomatids and the measurement of minicircles confirmed the size of about 1.45 kb of the sequenced minicircle.

Participation of the SOS system in producing deletions in E. coli plasmids

The participation of the SOS response in the deletion of palindromic and non-palindromic inserts of about 66 and 100 bp cloned within the EcoR1 site of the chloramphenicol acetyl transferase (cat) gene of plasmid pBR325 was tested after introducing the derived plasmids into strains containing different combinations of lexA, recA and umuC alleles and the auxotrophic mutation trpE65. This allowed for a comparison of deletion frequency in the plasmids, measured as the reversion of chloramphenicol sensitivity to resistance (Cms-->Cmr), to point-mutation frequency measured from the reversion of trpE65 to tryptophan independence (Trp(-)-->Trp+). We found that the spontaneous deletion frequency of palindromic inserts was increased by the overproduction of activated RecA* and UmuC+ in lexA (Def) backgrounds but the deletion of the non-palindromic inserts was unaltered. Overproduction of RecA+ had no significant effect on deletion incidence but it did increase Trp(-)-->Trp+ reversions. The SOS stimulation of palindrome deletions paralleled the SOS mutator effect of certain recA and umuC alleles on Trp(-)-->Trp+ reversions, suggesting that some form of SOS processing was responsible for the observed increases. The results further suggest that the SOS effect on deletions depends on the distinction between palindromy vs. non-palindromy, rather than on the sizes or sequences of the inserts or those of the terminal homologies bracketing them.

DNA structure, mutations, and human genetic disease

The etiology of fragile X syndrome, myotonic dystrophy and Kennedy's disease has been attributed to the massive expansion of triplet repeat DNA sequences. This review details the relationships between the structural diversity of DNA, its secondary structure or DNA-directed mutagenesis, and the expansion of triplet repeats.