Detection of treatment-resistant infectious HIV after genome-directed antiviral endonuclease therapy.

Incurable chronic viral infections are a major cause of morbidity and mortality worldwide. One potential approach to cure persistent viral infections is via the use of targeted endonucleases. Nevertheless, a potential concern for endonuclease-based antiviral therapies is the emergence of treatment resistance. Here we detect for the first time an endonuclease-resistant infectious virus that is found with high frequency after antiviral endonuclease therapy. While testing the activity of HIV pol-specific zinc finger nucleases (ZFNs) alone or in combination with three prime repair exonuclease 2 (Trex2), we identified a treatment-resistant and infectious mutant virus that was derived from a ZFN-mediated disruption of reverse transcriptase (RT). Although gene disruption of HIV protease, RT and integrase could inhibit viral replication, a chance single amino acid insertion within the thumb domain of RT produced a virus that could actively replicate. The endonuclease-resistant virus could replicate in primary CD4(+) T cells, but remained susceptible to treatment with antiretroviral RT inhibitors. When secondary ZFN-derived mutations were introduced into the mutant virus's RT or integrase domains, replication could be abolished. Our observations suggest that caution should be exercised during endonuclease-based antiviral therapies; however, combination endonuclease therapies may prevent the emergence of resistance.

Secreted single-stranded DNA is involved in the initial phase of biofilm formation by Neisseria gonorrhoeae.

Neisseria gonorrhoeae is an obligate human pathogen that colonizes the genital tract and causes gonorrhoea. Neisseria gonorrhoeae can form biofilms during natural cervical infections, on glass and in continuous flow-chamber systems. These biofilms contain large amounts of extracellular DNA, which plays an important role in biofilm formation. Many clinical isolates contain a gonococcal genetic island that encodes a type IV secretion system (T4SS). The T4SS of N. gonorrhoeae strain MS11 secretes ssDNA directly into the medium. Biofilm formation, studied in continuous flow-chamber systems by confocal laser scanning microscopy (CLSM), was strongly reduced, especially in the initial phases of biofilm formation, in the presence of Exonuclease I, which specifically degrades ssDNA or in a ΔtraB strain that does not secrete ssDNA. To specifically detect ssDNA in biofilms using CLSM, a novel method was developed in which thermostable fluorescently labelled ssDNA- and ss/dsDNA-binding proteins were used to visualize ssDNA and total DNA in biofilms and planktonic cultures. Remarkably, mainly dsDNA was detected in biofilms of the ssDNA secreting strain. We conclude that the secreted ssDNA facilitates initial biofilm formation, but that the secreted ssDNA is not retained in mature biofilms.

RECQ1 is required for cellular resistance to replication stress and catalyzes strand exchange on stalled replication fork structures.

RECQ1 is the most abundant of the five human RecQ helicases, but little is known about its biological significance. Recent studies indicate that RECQ1 is associated with origins of replication, suggesting a possible role in DNA replication. However, the functional role of RECQ1 at damaged or stalled replication forks is still unknown. Here, for the first time, we show that RECQ1 promotes strand exchange on synthetic stalled replication fork-mimicking structures and comparatively analyze RECQ1 with the other human RecQ helicases. RECQ1 actively unwinds the leading strand of the fork, similar to WRN, while RECQ4 and RECQ5ß can only unwind the lagging strand of the replication fork. Human replication protein A modulates the strand exchange activity of RECQ1 and shifts the equilibrium more to the unwinding mode, an effect also observed for WRN. Stable depletion of RECQ1 affects cell proliferation and renders human cells sensitive to various DNA damaging agents that directly or indirectly block DNA replication fork progression. Consequently, loss of RECQ1 activates DNA damage response signaling, leads to hyper-phosphorylation of RPA32 and activation of CHK1, indicating replication stress. Furthermore, depletion of RECQ1 leads to chromosomal condensation defects and accumulation of under-condensed chromosomes. Collectively, our observations provide a new insight into the role of RECQ1 in replication fork stabilization and its role in the DNA damage response to maintain genomic stability.

Werner syndrome protein, WRN, protects cells from DNA damage induced by the benzene metabolite hydroquinone.

Werner syndrome (WS) is a rare autosomal progeroid disorder caused by a mutation in the gene encoding the WRN (Werner syndrome protein), a member of the RecQ family of helicases with a role in maintaining genomic stability. Genetic association studies have previously suggested a link between WRN and susceptibility to benzene-induced hematotoxicity. To further explore the role of WRN in benzene-induced hematotoxicity, we used short hairpin RNA to silence endogenous levels of WRN in the human HL60 acute promyelocytic cell line and subsequently exposed the cells to hydroquinone (HQ). Suppression of WRN led to an accelerated cell growth rate, increased susceptibility to hydroquinone-induced cytotoxicity and genotoxicity as measured by the single-cell gel electrophoresis assay, and an enhanced DNA damage response. More specifically, loss of WRN resulted in higher levels of early apoptosis, marked by increases in relative levels of cleaved caspase-7 and cleaved poly (ADP-ribose) polymerase 1, in cells treated with HQ compared with control cells. Our data suggests that WRN plays an important role in the surveillance of and protection against DNA damage induced by HQ. This provides mechanistic support for the link between WRN and benzene-induced hematotoxicity.

The transcriptional response to distinct growth factors is impaired in Werner syndrome cells.

The Werner syndrome protein (WRN) is mutated in Werner syndrome (WS) and plays a role in telomere maintenance, DNA repair and transcription. WS represents a premature aging syndrome with severe growth retardation. Here we show that WRN is critically required to mediate the stimulatory effect of vascular endothelial growth factor (VEGF), basic fibroblast growth factor (FGF-b) and epidermal growth factor (EGF) on the activity of RNA polymerase I (Pol I). Recombinant WRN specifically reconstitutes RNA polymerase I transcription in extracts from Werner syndrome fibroblasts in vitro. In addition, we identified a critical role for WRN during promoter clearance of Pol I transcription, but not in elongation. Notably, WRN was isolated in a complex with Pol I and was crosslinked to the unmethylated, active proportion of rDNA genes in quiescent cells suggesting a so far unknown role for WRN in epigenetic regulation. This together with alterations in Pol I transcription provide a novel mechanism possibly underlying at least in part the severe growth retardation and premature aging in Werner syndrome patients.

The exonuclease TREX1 is in the SET complex and acts in concert with NM23-H1 to degrade DNA during granzyme A-mediated cell death.

Granzyme A (GzmA) activates a caspase-independent cell death pathway with morphological features of apoptosis. Single-stranded DNA damage is initiated when the endonuclease NM23-H1 becomes activated to nick DNA after granzyme A cleaves its inhibitor, SET. SET and NM23-H1 reside in an endoplasmic reticulum-associated complex (the SET complex) that translocates to the nucleus in response to superoxide generation by granzyme A. We now find the 3'-to-5' exonuclease TREX1, but not its close homolog TREX2, in the SET complex. TREX1 binds to SET and colocalizes and translocates with the SET complex. NM23-H1 and TREX1 work in concert to degrade DNA. Silencing NM23-H1 or TREX1 inhibits DNA damage and death of cells treated with perforin (PFN) and granzyme A, but not of cells treated with perforin and granzyme B (GzmB). After granzyme A activates NM23-H1 to make single-stranded nicks, TREX1 removes nucleotides from the nicked 3' end to reduce the possibility of repair by rejoining the nicked ends.

A mechanism for the exclusion of low-fidelity human Y-family DNA polymerases from base excision repair.

The human Y-family DNA polymerases, Poliota, Poleta, and Polkappa, function in promoting replication through DNA lesions. However, because of their low fidelity, any involvement of these polymerases in DNA synthesis during base excision repair (BER) would be highly mutagenic. Mechanisms, therefore, must exist to exclude their participation in BER. Here, we show that although Poliota, Poleta, and Polkappa are all able to form a covalent Schiff base intermediate with the 5'-deoxyribose phosphate (5'-dRP) residue that results from the incision of DNA at an abasic site by an AP endonuclease, they all lack the ability for the subsequent catalytic removal of the 5'-dRP group. Instead, the covalent trapping of these polymerases by the 5'-dRP residue inhibits their DNA synthetic activity during BER. The unprecedented ability of these polymerases for robust Schiff base formation without the release of the 5'-dRP product provides a means of preventing their participation in the DNA synthetic step of BER, thereby avoiding the high incidence of mutagenesis and carcinogenesis that would otherwise occur.

Autonomous 3'-->5' exonucleases can proofread for DNA polymerase beta from rat liver.

Autonomous 3'-->5'exonucleases are not bound covalently to DNA polymerases but are often involved in replicative complexes. Such exonucleases from rat liver, calf thymus and Escherichia coli (molecular masses of 28+/-2 kDa) are shown to increase more than 10-fold the accuracy of DNA polymerase beta (the most inaccurate mammalian polymerase) from rat liver in the course of reduplication of the primed DNA of bacteriophage phiX174 amber 3 in vitro. The extent of correction increases together with the rise in 3'-->5' exonuclease concentration. Extrapolation of the in vitro DNA replication fidelity to the cellular levels of rat exonuclease and beta-polymerase suggests that exonucleolytic proofreading could augment the accuracy of DNA synthesis by two orders of magnitude. These results are not explained by exonucleolytic degradation of the primers ("no synthesis-no errors"), since similar data are obtained with the use of the primers 15 or 150 nucleotides long in the course of a fidelity assay of DNA polymerases, both alpha and beta, in the presence of various concentrations of 3'-->5' exonuclease.

FEN1 stimulation of DNA polymerase beta mediates an excision step in mammalian long patch base excision repair.

In mammalian cells, single-base lesions, such as uracil and abasic sites, appear to be repaired by at least two base excision repair (BER) subpathways: "single-nucleotide BER" requiring DNA synthesis of just one nucleotide and "long patch BER" requiring multi-nucleotide DNA synthesis. In single-nucleotide BER, DNA polymerase beta (beta-pol) accounts for both gap filling DNA synthesis and removal of the 5'-deoxyribose phosphate (dRP) of the abasic site, whereas the involvement of various DNA polymerases in long patch BER is less well understood. Recently, we found that beta-pol plays a role in mammalian cell extract-mediated long patch BER, in that formation of a key excision product, 5'-dRP-trinucleotide (5'-dRP-N(3)), is dependent upon beta-pol (Dianov, G. L., Prasad, R., Wilson, S. H., and Bohr, V.A. (1999) J. Biol. Chem. 274, 13741-13743). The structure-specific endonuclease flap endonuclease 1 (FEN1) has also been suggested to be involved in long patch BER excision. Here, we demonstrate by immunodepletion experiments that 5'-dRP-N(3) excision in long patch BER of uracil-DNA in a human lymphoid cell extract is, indeed, dependent upon FEN1. Next, we reconstituted the excision step of long patch BER using purified human proteins and an oligonucleotide substrate with 5'-dRP at the margin of a one-nucleotide gap. Formation of the excision product 5'-dRP-N(3) was dependent upon both strand displacement DNA synthesis by beta-pol and FEN1 excision. FEN1 stimulated strand displacement DNA synthesis of beta-pol. FEN1 acting either alone, or without DNA synthesis by beta-pol, produced a two-nucleotide excision product, 5'-dRP-N(1), but not 5'-dRP-N(3). These results demonstrate that human FEN1 and beta-pol can cooperate in long patch BER excision and specify the predominant excision product seen with a cell extract.

Identification of two linear plasmids in the actinomycete Planobispora rosea.

Two linear plasmids (pPR1, 27.5 kb, and pPR2, 16 kb) were identified in Planobispora rosea, an actinomycete that produces the antibiotic GE2270, an inhibitor of the elongation factor Tu. Strains lacking both plasmids still produce and are resistant to GE2270. The two plasmids share an internal region of high similarity, but no cross-hybridization was detected between their telomeric regions or between plasmid and chromosomal DNA. The 5' ends of the plasmids appear to be linked to terminal proteins. The telomeric regions of pPR2 were cloned after 3'-end homopolymer tailing and PCR amplification. The approximately 650 nt telomeric DNA sequences of pPR2 are repeated in inverted orientation and are rich in direct and inverted repeats; the 350 bp terminal region is less G + C-rich than the rest of the plasmid. The structural organization of these plasmids appears to be similar to Streptomyces linear replicons.

Myoglobin as a polymerase chain reaction (PCR) inhibitor: a limitation for PCR from skeletal muscle tissue avoided by the use of Thermus thermophilus polymerase.

Skeletal muscle tissue contains polymerase chain reaction (PCR) inhibitors that are coextracted by conventional nucleic acid extraction procedures. Myoglobin, a heme-containing molecule, was shown to act as a potent Thermus aquaticus DNA polymerase inhibitor and is likely to be involved in muscle tissue-associated PCR inhibition. The use of Thermus thermophilus DNA polymerase avoids muscle tissue-associated PCR inhibition, and should be used in case of small amounts or instability of the targeted nucleic acid.

Immunogold electron microscopy in situ end-labeling (EM-ISEL): assay for biomaterial DNA damage detection.

We have evaluated a genotoxicity assay that combines in situ end-labeling, colloidal gold tagging and electron microscopy in order to adapt it to the measurement of in vitro biomaterial-induced genotoxicity. Human lymphocytes were cultured in semi-physiological medium which had been previously exposed to biomaterial extracts of commercially pure titanium following ISO standards. In order to visualize the location of induced DNA strand breaks, cells were then exposed to exonuclease III which partially digests and amplifies lesions by releasing nucleotides at free 3' hydroxyl ends from nicked double-stranded DNA. The resulting single-stranded DNA was allowed to hybridize with short oligonucleotides of random sequences including biotinylated dUTP. After random priming using Escherichia coli DNA polymerase I, incorporation of biotin-dUTP was detected by immunogold binding to the chromatin. Cells exposed to a mutagenic concentration of methyl methanesulfonate, as a positive control, showed a significantly higher and stronger gold staining than both titanium-exposed and unexposed specimens. This assay allows a precise localization and quantification of both in vitro DNA breakage and DNA repair. It could provide a powerful tool for rapid assessment of the genotoxic potential of new biomaterials.

Accelerated binding of secretory leukoprotease inhibitor to human leukocyte elastase mediated by single-stranded sites in DNA from tracheobronchial mucus.

We have found that preparations of DNA isolated from purulent sputum possess a novel activity which accelerates and stabilizes the binding of human leukocyte elastase to secretory leukoprotease inhibitor, a major endogenous antielastase in the respiratory tract. DNA in sputum is derived from the nuclear debris of disintegrated inflammatory leukocytes, and can attain concentrations ranging from 10(2) to 10(4) micrograms/ml, depending on the severity of pulmonary infection and inflammation. In the presence of 23 micrograms/ml DNA, a concentration lower than those found in most purulent sputa, the rate constant for association of secretory leukoprotease inhibitor with elastase is increased to 1.1 x 10(8) M-1s-1, 44-fold greater than that in the absence of DNA. The equilibrium dissociation constant for the enzyme-inhibitor complex drops to 0.7 pM, two orders of magnitude lower than that in the absence of DNA. The accelerating effect of DNA is further increased by thermal denaturation or by modification with exonuclease III, while it is significantly reduced by digestion with S1 nuclease or by binding of Escherichia coli single-stranded DNA binding protein. The results from these experiments indicate that the structural elements in sputum DNA that are responsible for the accelerating effect have the characteristics of single-stranded sites. Similar kinetic effects on elastase inhibition were also observed with human placental DNA and genomic DNAs from a variety of other species. These findings suggest that DNA in pulmonary secretions may participate in antielastase defense by promoting the binding of secretory leukoprotease inhibitor to leukocyte elastase. The results may have important implications for use of nuclease preparations in mucolytic therapy for cystic fibrosis.

PM2 DNA damage induced by 3-chloro-4-(dichloromethyl)-5-hydroxy-2 (5H)-furanone (MX).

3-Chloro-4-(dichloromethyl)-5-hydroxy-2(5H)-furanone (MX) is a potent direct-acting mutagen found in chlorinated drinking water. In the present study, the induction of DNA strand breaks and apurinic/apyrimidinic (AP) sites by MX in supercoiled PM2 DNA was examined using exonuclease III, which specifically cleaves the DNA at AP sites. The results showed that MX induced AP sites in great excess of direct strand breaks. In view of the known mutagenicity of AP sites, these results provide insight into the mechanism of MX-induced mutagenesis.

Identification of the minimum regulatory region of a Myxococcus xanthus A-signal-dependent developmental gene.

Developmental expression of the Myxococcus xanthus gene 4521 requires extracellular A-signal. This signal is generated in response to nutrient limitation and functions in cell density sensing. To identify the upstream limit of the minimum region required in vivo for A-signal-dependent 4521 expression, a 5' deletion analysis of the 4521 regulatory region was performed. A new vector, pHBK280, was designed to facilitate this analysis. This vector creates tandem copies of the 4521 gene in the M. xanthus chromosome, such that the regulatory region to be tested is upstream of a single copy of the lacZ reporter gene. The 5' deletion analysis revealed that at most, 146 bp of DNA upstream of the transcription start site (TSS) was required for full developmental expression of 4521. Basal expression levels were observed with constructions containing 90 bp of DNA upstream of the TSS. In vitro gel retardation assays revealed that DNA fragments with 5' ends of 146 and 125 bp upstream of the TSS and a common 3' end of +24 bp were retarded in their mobility after incubation with all of the M. xanthus developmental crude cell extracts tested. In contrast, a fragment starting at 90 bp upstream of the TSS and ending at +24 bp was not retarded in its mobility after incubation with the same cell extracts. These in vivo and in vitro data suggest that cis-acting elements located between 146 and 90 bp upstream of the TSS serve as binding sites for one or more trans-acting regulatory factors required for 4521 developmental expression.

The formation of both apurinic/apyrimidinic sites and single-strand breaks by chromate and glutathione arises from attack by the same single reactive species and is dependent on molecular oxygen.

The induction of apurinic/apyrimidinic sites (AP sites) and DNA single-strand breaks (SSB) by chromate and glutathione in isolated DNA was investigated using agents that cleave the DNA at AP sites (putrescine and exonuclease III). It was found that chromate/glutathione-induced AP sites contain free aldehyde groups, as cleavage by putrescine could be prevented by treatment with sodium borohydride. The formation of AP sites and SSB followed a very similar temporal pattern, suggesting that both lesions arise from attack by the same single reactive species deriving from chromate and glutathione. Furthermore, the induction of both lesions was found to be dependent on the presence of molecular oxygen.

Inhibition of transcription in vitro by binding of DNA (cytosine-5)-methylases to DNA templates containing cytosine analogs.

DNA(cytosine-5)-methylases form tight complexes at their methylation sites when the target cytosine residue is substituted by analogs such as 5-azacytosine or 5-fluorocytosine. To test whether such complexes can block RNA transcription in vitro, template DNA-containing methylation sites were prepared, in which cytosine residues in either the (+)- or (-)-strand were substituted by the analogs. Such templates, irrespective of the strand in which substitution was made, could effectively block the elongation of RNA at specific sites when complexed with EcoRII methylase. The protein-DNA complex probably prevents the unwinding of the template strands or might directly present itself as a steric block to the advancing RNA polymerase. RNA synthesis was also inhibited at specific sites due to complex formation between azacytosine-containing DNA and two other methylases, HhaI and HpaII. The 3' ends of the interrupted transcripts were mapped and were found to lie within 13-14, 13, and 23 nucleotides of the binding sites on the (-)-strand for HhaI, HpaII, and EcoRII methylases, respectively. Exonuclease III footprinting revealed that the boundaries of the complexed methylases, HhaI, HpaII, and EcoRII, on the (-)-strand were within 2-3, 1-2, and 9-10 nucleotides, respectively, of the last nucleotide copied by the RNA polymerase.

Psoralen--lexitropsin hybrids: DNA sequence selectivity of photoinduced cross-linking from MPE footprinting and exonuclease III stop assay, and mode of binding from electric linear dichroism.

The properties of certain hybrids 3 and 5 bearing a photoactivatable psoralen group attached to DNA sequence recognizing lexitropsin carriers have been examined. The hybrids bind to poly(dA-dT) with Kapp of 2.8 and 0.9 x 10(7) M-1, i.e. greater than or equal to that of netropsin (Kapp = 1.0 x 10(7) M-1), indicating that the psoralen moiety may contribute to binding in the case of 5. Photoinduced cross-linking of DNA by 3 and 5, while efficient, is less so than that of individual psoralens and reaches a maximum at a ligand to DNA base pair ratio (r) of 0.2. Complementary strand methidium-propyl-EDTA (MPE).Fe(II) footprinting demonstrated that, in the dark, the sequence preferential recognition of hybrids 3 and 5 is dominated by the lexitropsin moiety. Examination of 360 nm photoinduced DNA cross-linking by the hybrids 3 and 5 was carried out using an exonuclease III stop assay. This revealed that > 95% of the DNA remained double stranded, indicating that 3 and 5 generate primarily biadducts at AT-rich sequences. This assay also located individual monoadduct sites, some of which are remote from the dominant cross-linked sites. When the samples were exposed to 254 nm UV light before loading onto the gel to reverse the photoproducts, the pattern of the exonuclease III stop bands was not altered significantly compared with the experiment without 254 nm irradiation. It is concluded that these termination sites include both mono- and biadducts. Electric linear dichroism examination of the DNA complexes of hybrids 3 and 5 (without light activation) provides evidence that the lexitropsin portion binds in the minor groove, while the psoralen portion intercalates in a suitably located site for subsequent photoinduced cross-linking.

Linear mitochondrial DNAs of yeasts: closed-loop structure of the termini and possible linear-circular conversion mechanisms.

The terminal structure of the linear mitochondrial DNA (mtDNA) from three yeast species has been examined. By enzymatic digestion, alkali denaturation, and sequencing of cloned termini, it was shown that in Pichia pijperi and P. jadinii, both termini of the linear mtDNA were made of a single-stranded loop covalently joining the two strands, as in the case of vaccinia virus DNA. The left and right loop sequences were in either of two orientations, suggesting the existence of a flip-flop inversion mechanism. Contiguous to the terminal loops, inverted terminal repeats were present. The mtDNA from Williopsis mrakii seems to have an analogous structure, although terminal loops could not be directly demonstrated. Electron microscopy revealed the presence, among linear molecules, of a small number of circular DNAs, mostly of monomer length. Linear and circular models of replication are considered, and possible conversion mechanisms between linear and circular forms are discussed. A flip-flop inversion mechanism between the inverted repeat sequences within a circular intermediate may be involved in the generation of the linear form of mtDNA.