Activation of R-mediated innate immunity and disease susceptibility is affected by mutations in a cytosolic O-acetylserine (thiol) lyase in Arabidopsis

O-acetylserine (thiol) lyases (OASTLs) are evolutionarily conserved proteins among many prokaryotes and eukaryotes that perform sulfur acquisition and synthesis of cysteine. A mutation in the cytosolic OASTL-A1 protein ONSET OF LEAF DEATH3 (OLD3) was previously shown to reduce the OASTL activity of the old3-1 protein in vitro and cause auto-necrosis in specific Arabidopsis accessions. Here we investigated why a mutation in this protein causes auto-necrosis in some but not other accessions. The auto-necrosis was found to depend on Recognition of Peronospora Parasitica 1 (RPP1)-like disease resistance R gene(s) from an evolutionarily divergent R gene cluster that is present in Ler-0 but not the reference accession Col-0. RPP1-like gene(s) show a negative epistatic interaction with the old3-1 mutation that is not linked to reduced cysteine biosynthesis. Metabolic profiling and transcriptional analysis further indicate that an effector triggered-like immune response and metabolic disorder are associated with auto-necrosis in old3-1 mutants, probably activated by an RPP1-like gene. However, the old3-1 protein in itself results in largely neutral changes in primary plant metabolism, stress defence and immune responses. Finally, we showed that lack of a functional OASTL-A1 results in enhanced disease susceptibility against infection with virulent and non-virulent Pseudomonas syringae pv. tomato DC3000 strains. These results reveal an interaction between the cytosolic OASTL and components of plant immunity.

Regulatory role of cystathionine-gamma-synthase and de novo synthesis of methionine in ethylene production during tomato fruit ripening

The essential amino acid methionine is a substrate for the synthesis of S-adenosyl-methionine (SAM), that donates its methyl group to numerous methylation reactions, and from which polyamines and ethylene are generated. To study the regulatory role of methionine synthesis in tomato fruit ripening, which requires a sharp increase in ethylene production, we cloned a cDNA encoding cystathionine gamma-synthase (CGS) from tomato and analysed its mRNA and protein levels during tomato fruit ripening. CGS mRNA and protein levels peaked at the "turning" stage and declined as the fruit ripened. Notably, the tomato CGS mRNA level in both leaves and fruit was negatively affected by methionine feeding, a regulation that Arabidopsis, but not potato CGS mRNA is subject to. A positive correlation was found between elevated ethylene production and increased CGS mRNA levels during the ethylene burst of the climacteric ripening of tomato fruit. In addition, wounding of pericarp from tomato fruit at the mature green stage stimulated both ethylene production and CGS mRNA level. Application of exogenous methionine to pericarp of mature green fruit increased ethylene evolution, suggesting that soluble methionine may be a rate limiting metabolite for ethylene synthesis. Moreover, treatment of mature green tomato fruit with the ethylene-releasing reagent Ethephon caused an induction of CGS mRNA level, indicating that CGS gene expression is regulated by ethylene. Taken together, these results imply that in addition to recycling of the methionine moieties via the Yang pathway, operating during synthesis of ethylene, de novo synthesis of methionine may be required when high rates of ethylene production are induced.

Single-gene knockout of a novel regulatory element confers ethionine resistance and elevates methionine production in Corynebacterium glutamicum

Despite the availability of genome data and recent advances in methionine regulation in Corynebacterium glutamicum, sulfur metabolism and its underlying molecular mechanisms are still poorly characterized in this organism. Here, we describe the identification of an ORF coding for a putative regulatory protein that controls the expression of genes involved in sulfur reduction dependent on extracellular methionine levels. C. glutamicum was randomly mutagenized by transposon mutagenesis and 7,000 mutants were screened for rapid growth on agar plates containing the methionine antimetabolite D,L-ethionine. In all obtained mutants, the site of insertion was located in the ORF NCgl2640 of unknown function that has several homologues in other bacteria. All mutants exhibited similar ethionine resistance and this phenotype could be transferred to another strain by the defined deletion of the NCgl2640 gene. Moreover, inactivation of NCgl2640 resulted in significantly increased methionine production. Using promoter lacZ-fusions of genes involved in sulfur metabolism, we demonstrated the relief of L-methionine repression in the NCgl2640 mutant for cysteine synthase, o-acetylhomoserine sulfhydrolase (metY) and sulfite reductase. Complementation of the mutant strain with plasmid-borne NCgl2640 restored the wild-type phenotype for metY and sulfite reductase.

Stat3 protects against Fas-induced liver injury by redox-dependent and -independent mechanisms

Signal transducer and activator of transcription-3 (Stat3) is one of the most important molecules involved in the initiation of liver development and regeneration. In order to investigate the hepatoprotective effects of Stat3, we examined whether Stat3 protects against Fas-mediated liver injury in the mouse. A constitutively activated form of Stat3 (Stat3-C) was adenovirally overexpressed in mouse liver by intravenous injection, and then a nonlethal dose of Fas agonist (Jo2) was injected intraperitoneally into the mouse (0.3 microg/g body wt). Stat3-C dramatically suppressed both apoptosis and necrosis induced by Jo2. In contrast, liver-specific Stat3-knockout mice failed to survive following Jo2 injection. Stat3-C upregulated expression of FLICE inhibitor protein (FLIP), Bcl-xL, and Bcl-2, and accordingly downregulated activities of FLICE and caspase-3 that were redox-independent. Interestingly, Stat3-C also upregulated the redox-associated protein redox factor-1 (Ref-1) and reduced apoptosis in liver following Jo2 injection by suppressing oxidative stress and redox-sensitive caspase-3 activity. These findings indicate that Stat3 activation protects against Fas-mediated liver injury by inhibiting caspase activities in redox-dependent and -independent mechanisms.

Role of the AP-1 element and redox factor-1 (Ref-1) in mediating transcriptional induction of DT-diaphorase gene expression by oltipraz: a target for chemoprevention

The dithiolethione oltipraz is a potent chemopreventive agent in preclinical models, and induces the expression of protective enzymes in the colon mucosa and peripheral mononuclear cells of treated human subjects. We investigated the effects of oltipraz on DT-diaphorase expression in HT29 colon adenocarcinoma cells. Following a 24-hr exposure to 100 microM oltipraz, elevated steady-state levels of mRNA for Jun and Fos family members were observed. A nuclear run-on assay showed induction of c-fos and c-jun transcripts at the end of the exposure, peaking at 12 hr after resuspension of cells in drug-free medium. Gel mobility shift analysis revealed a similar time-course of induced nuclear factor binding to an AP-1 probe. Supershift analysis verified the participation of Jun and Fos in the complexes. The redox coactivator Ref-1, a function of which is to enhance AP-1 binding, was induced 5-fold by oltipraz. Immunodepletion of Ref-1 partially inhibited factor binding to the AP-1 probe. Deletion analysis of the DT-diaphorase promoter in a CAT reporter construct revealed that loss of the AP-1 site accounted for approximately 65% of the induction by oltipraz. Mutation of the AP-1 element in a full-length promoter construct yielded similar results. These data suggest the importance of transcriptional activation mediated by AP-1 in the chemopreventive activity of oltipraz, and indicate that novel chemoprevention structures may be selected based upon agonist activity at this locus.

Suppressive activities of OGG1 and MYH proteins against G:C to T:A mutations caused by 8-hydroxyguanine but not by benzo[a]pyrene diol epoxide in human cells in vivo

8-Hydroxyguanine (8OHG), an oxidatively damaged base, and benzo[a]pyrene-diol-epoxide (BPDE), a metabolite of benzo[a]pyrene found in cigarette smoke, are thought to be major causes for G:C to T:A transversions in DNA of human cells. In this study, we assessed the abilities of OGG1, MYH and APE1 proteins, which are components of a base excision repair pathway, to suppress G:C to T:A transversions caused by 8OHG or BPDE by a bacterial suppressor tRNA (supF) forward mutation assay using a shuttle plasmid, pMY189. The introduction of a single 8OHG residue at position 159 of the supF gene and treatment with BPDE led to a 65- and 34-fold increase in mutation frequencies of the pMY189 plasmid, respectively, after replication in the NCI-H1299 human lung cancer cell line. G:C to T:A transversions were predominantly induced in these plasmids. Both the mutation frequency of the 8OHG-containing plasmid in NCI-H1299 cells and the occurrence of G:C to T:A transversions at position 159 in the supF gene were significantly reduced by overexpression of OGG1 and MYH proteins, but not by that of APE1 protein. In contrast, neither mutation frequency nor the occurrence of G:C to T:A transversion of the BPDE-treated plasmid was reduced by overexpression of OGG1, MYH and APE1 proteins. These results indicate that OGG1 and MYH function as suppressors for G:C to T:A transversions by 8OHG but not by BPDE in human cells.

The exonuclease activity of human apurinic/apyrimidinic endonuclease (APE1). Biochemical properties and inhibition by the natural dinucleotide Gp4G

Human DNA apurinic/apyrimidinic endonuclease (APE1) plays a key role in the DNA base excision repair process. In this study, we further characterized the exonuclease activity of APE1. The magnesium requirement and pH dependence of the exonuclease and endonuclease activities of APE1 are significantly different. APE1 showed a similar K(m) value for matched, 3' mispaired, or nucleoside analog beta-l-dioxolane-cytidine terminated nicked DNA as well as for DNA containing a tetrahydrofuran, an abasic site analog. The k(cat) for exonuclease activity on matched, 3' mispaired, and beta-l-dioxolane-cytidine nicked DNA are 2.3, 61.2, and 98.8 min(-1), respectively, and 787.5 min(-1) for APE1 endonuclease. Site-directed APE1 mutant proteins (E96A, E96Q, D210E, D210N, and H309N), which target amino acid residues in the endonuclease active site, also showed significant decrease in exonuclease activity. Gp(4)G was the only potent inhibitor to compete against the substrates of endonuclease and exonuclease activities among all tested naturally occurring ribo-, deoxyribo-nucleoside/nucleotides, NAD(+), NADP(+), and Ap(4)A. The K(i) values of Gp(4)G for the endonuclease and exonuclease activities of APE1 are 10 +/- 0.6 and 1 +/- 0.2 microm, respectively. Given the relative concentrations of Gp(4)G, 3' mispaired, and abasic DNA, Gp(4)G may play an important role in regulating APE1 activity in cells. The data presented here suggest that the APE1 exonuclease and AP endonuclease are two distinct activities. APE1 may exist in two different conformations, and each conformation has a preference for a substrate. The different conformations can be affected by MgCl(2) or salt concentrations.

Base excision repair activities required for yeast to attain a full chronological life span

The chronological life span of yeast, the survival of stationary (G0) cells over time, provides a model for investigating certain of the factors that may influence the aging of non-dividing cells and tissues in higher organisms. This study measured the effects of defined defects in the base excision repair (BER) system for DNA repair on this life span. Stationary yeast survives longer when it is pre-grown on respiratory, as compared to fermentative (glucose), media. It is also less susceptible to viability loss as the result of defects in DNA glycosylase/AP lyases (Ogg1p, Ntg1p, Ntg2p), apurinic/apyrimidinic (AP) endonucleases (Apn1p, Apn2p) and monofunctional DNA glycosylase (Mag1p). Whereas single BER glycosylase/AP lyase defects exerted little influence over such optimized G0 survival, this survival was severely shortened with the loss of two or more such enzymes. Equally, the apn1delta and apn2delta single gene deletes survived as well as the wild type, whereas a apn1delta apn2delta double mutant totally lacking in any AP endonuclease activity survived poorly. Both this shortened G0 survival and the enhanced mutagenicity of apn1delta apn2delta cells were however rescued by the over-expression of either Apn1p or Apn2p. The results highlight the vital importance of BER in the prevention of mutation accumulation and the attainment of the full yeast chronological life span. They also reveal an appreciable overlap in the G0 maintenance functions of the different BER DNA glycosylases and AP endonucleases.

Implication of Ref-1 in the repression of renin gene transcription by intracellular calcium

OBJECTIVE

The production of renin, which catalyzes the rate-limiting step of the renin-angiotensin system, is tightly regulated by intracellular second messengers. Among them, an increase of intracellular calcium represses renin gene expression. This inhibition of gene expression by intracellular calcium is exceptional, and the molecular mechanism supporting this phenomenon has not yet been identified. As the renin gene is negatively regulated by calcium in the same way as the parathormone (PTH) gene, we hypothesized that a similar molecular transcriptional mechanism could be involved.

RESULTS

Analysis of the human renin proximal promoter led to the identification of a negative calcium response element (nCaRE), which is identical to the region of the PTH promoter and is involved in its repression by calcium. Transfection experiments in renin-expressing chorio-decidual cells demonstrated the transcriptional functionality of the human renin promoter nCaRE. In addition, mutation of nCaRE suppressed the sensitivity of the renin promoter to the increase in intracellular calcium. Gel shift assays demonstrated that Redox factor 1, a multifunctional protein involved in the repair of damaged DNA and the redox activation of AP-1 transcriptional factors, binds specifically to nCaRE. Immunostaining showed that this factor is translocated from the cytoplasm to the nucleus in response to an increase in the intracellular calcium concentration.

CONCLUSION

Thus, the repression of renin expression by intracellular calcium may be mediated by the calcium-induced translocation of Ref-1 to the nucleus, where it binds to the renin promoter nCaRE, to repress the transcription of the renin gene.

AP endonuclease 1 coordinates flap endonuclease 1 and DNA ligase I activity in long patch base excision repair

Base loss is common in cellular DNA, resulting from spontaneous degradation and enzymatic removal of damaged bases. Apurinic/apyrimidinic (AP) endonucleases recognize and cleave abasic (AP) sites during base excision repair (BER). APE1 (REF1, HAP1) is the predominant AP endonuclease in mammalian cells. Here we analyzed the influences of APE1 on the human BER pathway. Specifically, APE1 enhanced the enzymatic activity of both flap endonuclease1 (FEN1) and DNA ligase I. FEN1 was stimulated on all tested substrates, regardless of flap length. Interestingly, we have found that APE1 can also inhibit the activities of both enzymes on substrates with a tetrahydrofuran (THF) residue on the 5'-downstream primer of a nick, simulating a reduced abasic site. However once the THF residue was displaced at least a single nucleotide, stimulation of FEN1 activity by APE1 resumes. Stimulation of DNA ligase I required the traditional nicked substrate. Furthermore, APE1 was able to enhance overall product formation in reconstitution of BER steps involving FEN1 cleavage followed by ligation. Overall, APE1 both stimulated downstream components of BER and prevented a futile cleavage and ligation cycle, indicating a far-reaching role in BER.

Stimulation of 3'-->5' exonuclease and 3'-phosphodiesterase activities of yeast apn2 by proliferating cell nuclear antigen

The Apn2 protein of Saccharomyces cerevisiae contains 3'-->5' exonuclease and 3'-phosphodiesterase activities, and these activities function in the repair of DNA strand breaks that have 3'-damaged termini and which are formed in DNA by the action of oxygen-free radicals. Apn2 also has an AP endonuclease activity and functions in the removal of abasic sites from DNA. Here, we provide evidence for the physical and functional interaction of Apn2 with proliferating cell nuclear antigen (PCNA). As indicated by gel filtration and two-hybrid studies, Apn2 interacts with PCNA both in vitro and in vivo and mutations in the consensus PCNA-binding motif of Apn2 abolish this interaction. Importantly, PCNA stimulates the 3'-->5' exonuclease and 3'-phosphodiesterase activities of Apn2. We have examined the involvement of the interdomain connector loop (IDCL) and of the carboxy-terminal domain of PCNA in Apn2 binding and found that Apn2 binds PCNA via distinct domains dependent upon whether the binding is in the absence or presence of DNA. In the absence of DNA, Apn2 binds PCNA through its IDCL domain, whereas in the presence of DNA, when PCNA has been loaded onto the template-primer junction by replication factor C, the C-terminal domain of PCNA mediates the binding.

The apurinic/apyrimidinic endonuclease activity of Ape1/Ref-1 contributes to human glioma cell resistance to alkylating agents and is elevated by oxidative stress

Alkylating agents are standard components of adjuvant chemotherapy for gliomas. We provide evidence here that Ape1/Ref-1, the major mammalian apurinic/apyrimidinic endonuclease (Ap endo), contributes to alkylating agent resistance in human glioma cells by incising DNA at abasic sites. We show that antisense oligonucleotides directed against Ape1/Ref-1 in SNB19, a human glioma cell line lacking O(6)-methylguanine-DNA-methyltransferase, mediate both reduction in Ape1/Ref-1 protein and Ap endo activity and concurrent reduction in resistance to methyl methanesulfonate and the clinical alkylators temozolomide and 1,3-(2-chloroethyl)-1-nitrosourea. An accompanying increase in the level of abasic sites indicates that the DNA repair activity of Ape1/Ref-1 contributes to resistance. Conversely, we also show that exposure of SNB19 cells to HOCl, a generator of reactive oxygen species (ROS), results in elevated Ape1/Ref-1 protein and Ap endo activity, enhanced alkylator resistance, and reduced levels of abasic sites. Given current evidence that heightened oxidative stress prevails within brain tumors, the finding that ROS increase resistance to clinical alkylators in glioma cells may have significance for the response of gliomas to alkylating agent-based chemotherapy. Our results may also be relevant to the design of therapeutic regimens using concurrent ionizing radiation (a generator of ROS) and alkylating agent-based chemotherapy.

Targeted deletion of mNth1 reveals a novel DNA repair enzyme activity

DNA N-glycosylase/AP (apurinic/apyrimidinic) lyase enzymes of the endonuclease III family (nth in Escherichia coli and Nth1 in mammalian organisms) initiate DNA base excision repair of oxidized ring saturated pyrimidine residues. We generated a null mouse (mNth1(-/-)) by gene targeting. After almost 2 years, such mice exhibited no overt abnormalities. Tissues of mNth1(-/-) mice contained an enzymatic activity which cleaved DNA at sites of oxidized thymine residues (thymine glycol [Tg]). The activity was greater when Tg was paired with G than with A. This is in contrast to Nth1, which is more active against Tg:A pairs than Tg:G pairs. We suggest that there is a back-up mammalian repair activity which attacks Tg:G pairs with much greater efficiency than Tg:A pairs. The significance of this activity may relate to repair of oxidized 5-methyl cytosine residues (5meCyt). It was shown previously (S. Zuo, R. J. Boorstein, and G. W. Teebor, Nucleic Acids Res. 23:3239-3243, 1995) that both ionizing radiation and chemical oxidation yielded Tg from 5meCyt residues in DNA. Thus, this previously undescribed, and hence novel, back-up enzyme activity may function to repair oxidized 5meCyt residues in DNA while also being sufficient to compensate for the loss of Nth1 in the mutant mice, thereby explaining the noninformative phenotype.

Evidence for multiple imino intermediates and identification of reactive nucleophiles in peptide-catalyzed beta-elimination at abasic sites

Prior investigations have demonstrated that peptides containing a single aromatic residue flanked by basic ones, such as Lys-Trp-Lys, can incise the phosphodiester backbone of duplex DNA at an AP site via beta-elimination. An amine serves as the reactive nucleophile to attack C1' on the ring-open deoxyribose sugar to form a transient peptide-DNA imino (Schiff base) intermediate, which may be isolated as a stable covalent species under reducing conditions. In the current study, we use this methodology to demonstrate that peptide-catalyzed beta-elimination proceeds via the formation of two Schiff base intermediates, one of which was covalently trapped prior to strand incision and the other following strand incision. N-Terminal acetylation of reactive peptides significantly inhibited formation of a trapped Schiff base complex; thus, we demonstrate for the first time that the preferred reactive nucleophile for peptides catalyzing strand incision is the N-terminal alpha-amino group, not an epsilon-amino group located on a lysine residue as previously postulated. Trapping reactions in which the central tryptophan residue was changed to alanine did not have a significant impact on the efficiency of Schiff base formation, indicating that the presence of an aromatic residue is dispensable for the step prior to peptide-catalyzed beta-elimination. Interestingly, the methodology presented here affords a convenient means for covalently attaching an array of peptides onto AP site-containing DNA in a site-specific fashion. We suggest that the generation of such DNA-peptide cross-links may provide utility in studying the repair of biologically significant DNA-protein cross-link damage as DNA-peptide complexes may mimic intermediate structures along a repair pathway for DNA-protein cross-links.

Redox factor-1/APE suppresses oxidative stress by inhibiting the rac1 GTPase

Oxidative stress triggered by many environmental and clinical insults results in cellular injury and death. The small GTPase rac1 promotes oxidative stress via the production of reactive oxygen species (ROS). In turn, the homeostatic response to such stress includes up-regulation of the dual function reducing protein/DNA repair enzyme APE/redox factor-1(ref-1). In this report we explore the function and relationship between ref-1 and rac1 in the setting of oxidative stress triggered by re-oxygenation/reperfusion. In a model of mouse hepatic ischemia/reperfusion (I/R), recombinant adenoviral overexpression of ref-1 resulted in suppression of reperfusion-stimulated oxidative stress, NF-kB induction, apoptosis, and acute injury, whereas down-regulation of endogenous ref-1 by adenoviral expression of antisense ref-1 led to an increase in these reperfusion-induced parameters. Ref-1 also mitigated ROS production induced by adenoviral expression of an active form of rac1. Finally, overexpression of ref-1 in primary hepatocytes suppressed reoxygenation-stimulated rac1 activity. This work demonstrates a novel function of ref-1 in inhibition of rac1 activity, and rac1-mediated oxidative stress and injury.

Redox effector factor-1 regulates the activity of thyroid transcription factor 1 by controlling the redox state of the N transcriptional activation domain

Thyroid transcription factor 1 (TTF-1) is a homeodomain-containing transcriptional regulator responsible for the activation of thyroid- and lung-specific genes. It has been demonstrated that its DNA binding activity is redox-regulated in vitro through the formation of dimers and oligomeric species. In this paper, we demonstrate that the redox regulation mainly involves a Cys residue (Cys(87)), which resides out of the DNA binding domain, belonging to the N-transactivation domain. In fact, the oxidized form of a truncated TTF-1 (containing the N-transactivation domain and the DNA-binding domain, here called TTF-1N-HD) looses specific DNA binding activity. Since most of the oxidized TTF-1N-HD is in a monomeric form, these data indicate that the redox state of Cys(87) may control the DNA-binding function of the homeodomain, suggesting that Cys(87) could play an important role in determining the correct folding of the homeodomain. By using gel retardation and transient transfection assays, we demonstrate that the redox effector factor-1 (Ref-1) mediates the redox effects on TTF-1N-HD binding and that it is able to modulate the TTF-1 transcriptional activity. Glutathione S-transferase pull-down experiments demonstrate the occurrence of interaction between Ref-1 and TTF-1N-HD. Having previously demonstrated that Ref-1 is able to modulate the transcriptional activity of another thyroid-specific transcription factor (Pax-8), our data suggest that Ref-1 plays a central role in the regulation of thyroid cells.

Structure and function of threonine synthase from yeast

Threonine synthase catalyzes the final step of threonine biosynthesis, the pyridoxal 5'-phosphate (PLP)-dependent conversion of O-phosphohomoserine into threonine and inorganic phosphate. Threonine is an essential nutrient for mammals, and its biosynthetic machinery is restricted to bacteria, plants, and fungi; therefore, threonine synthase represents an interesting pharmaceutical target. The crystal structure of threonine synthase from Saccharomyces cerevisiae has been solved at 2.7 A resolution using multiwavelength anomalous diffraction. The structure reveals a monomer as active unit, which is subdivided into three distinct domains: a small N-terminal domain, a PLP-binding domain that covalently anchors the cofactor and a so-called large domain, which contains the main of the protein body. All three domains show the typical open alpha/beta architecture. The cofactor is bound at the interface of all three domains, buried deeply within a wide canyon that penetrates the whole molecule. Based on structural alignments with related enzymes, an enzyme-substrate complex was modeled into the active site of yeast threonine synthase, which revealed essentials for substrate binding and catalysis. Furthermore, the comparison with related enzymes of the beta-family of PLP-dependent enzymes indicated structural determinants of the oligomeric state and thus rationalized for the first time how a PLP enzyme acts in monomeric form.

BER, MGMT, and MMR in defense against alkylation-induced genotoxicity and apoptosis

Methylating carcinogens and cytostatic drugs induce different methylation products in DNA. In cells not expressing the repair protein MGMT or expressing it at a low level, O6-methylguanine is the major genotoxic, recombinogenic, and apoptotic lesion. Genotoxicity and apoptosis triggered by O6-methylguanine require mismatch repair (MMR). In cells expressing O6-methylguanine-DNA methyl transferase (MGMT) at a high level or for agents producing low amounts of O6-methylguanine, N-alkylations become the major genotoxic lesions. N-Alkylations are repaired by base excision repair (BER). In mammalian cells, naturally occurring mutants of BER have not been detected, which points to the importance of BER for viability. In order to ascertain the role of BER in cellular defense, BER was modulated either by transfection or mutational inactivation. It has been shown that overexpression of N-methylpurine-DNA glycosylase (MPG) does not protect, but rather sensitizes cells to SN2 agents. This has been interpreted in terms of an imbalance in BER. Regarding abasic site endonuclease (APE), transient but not stable overexpression of the enzyme was achieved upon transfection in CHO cells, which indicates that unphysiologic APE levels are not tolerated by the cell. Besides the repair function, APE (alias Ref-1) exerts redox capability by which the activity of various transcription factors is modulated. Therefore, it is possible that stable overexpression of mammalian APE impairs transcriptional regulation of genes, whereas transient overexpression may exert some protective effect. DNA polymerase beta (Pol beta) transfection was ineffective in conferring resistance to methylmethane sulfonate (MMS). On the other hand, Pol beta-deficient cells proved to be highly sensitive to methylation-induced chromosomal aberrations and reproductive cell death. The dramatic hypersensitivity in the killing response is largely due to induction of apoptosis. Obviously, nonrepaired BER intermediates are clastogenic and act as a strong trigger of the apoptotic pathway. The elements of this pathway are currently under investigation.

Molecular mechanism of PCNA-dependent base excision repair

In higher eukaryotes, base excision repair can proceed by two alternative pathways: a DNA polymerase beta-dependent pathway and a proliferating cell nuclear antigen (PCNA)-dependent pathway. Recently, we have reconstituted the PCNA-dependent AP site repair reaction with six purified human proteins: AP endonuclease, replication factor C (RFC), PCNA, flap endonuclease 1 (FEN1), DNA polymerase delta (pol delta), and DNA ligase I. In this reconstituted system, the number of nucleotides replaced during the repair reaction (patch size) was predominantly two nucleotides. PCNA can directly interact with RFC, pol delta, FEN1 and DNA ligase I. These interactions are partly through a consensus motif, QXX(I/L/M)XX(F/H)(F/Y), found in each of the four proteins. PCNA functions as a molecular adaptor for recruiting these factors to the site of DNA repair. Two DNA-N-glycosylases among those so far cloned from human, UNG2 and MYH, are found to have the same PCNA-binding motif. Major substrates of these enzymes, a uracil opposite an adenine for UNG2 and an adenine opposite an 8-oxoguanine for MYH, are formed during DNA replication. Therefore, UNG2 and MYH may serve for replication-coupled base excision repair through the direct interaction with PCNA in the replication machinery.

Unraveling DNA repair in human: molecular mechanisms and consequences of repair defect

Cellular genomes are vulnerable to an array of DNA-damaging agents, of both endogenous and environmental origin. Such damage occurs at a frequency too high to be compatible with life. As a result cell death and tissue degeneration, aging and cancer are caused. To avoid this and in order for the genome to be reproduced, these damages must be corrected efficiently by DNA repair mechanisms. Eukaryotic cells have multiple mechanisms for the repair of damaged DNA. These repair systems in humans protect the genome by repairing modified bases, DNA adducts, crosslinks and double-strand breaks. The lesions in DNA are eliminated by mechanisms such as direct reversal, base excision and nucleotide excision. The base excision repair eliminates single damaged-base residues by the action of specialized DNA glycosylases and AP endonucleases. Nucleotide excision repair excises damage within oligomers that are 25 to 32 nucleotides long. This repair utilizes many proteins to remove the major UV-induced photoproducts from DNA, as well as other types of modified nucleotides. Different DNA polymerases and ligases are utilized to complete the separate pathways. The double-strand breaks in DNA are repaired by mechanisms that involve DNA protein kinase and recombination proteins. The defect in one of the repair protein results in three rare recessive syndromes: xeroderma pigmentosum, Cockayne syndrome, and trichothiodystrophy. This review describes the biochemistry of various repair processes and summarizes the clinical features and molecular mechanisms underlying these disorders.

Mammalian DNA beta-polymerase in base excision repair of alkylation damage

DNA beta-polymerase (beta-pol) carries out two critical enzymatic reactions in mammalian single-nucleotide base excision repair (BER): DNA synthesis to fill the repair patch and lyase removal of the 5'-deoxyribose phosphate (dRP) group following cleavage of the abasic site by apurinic/apyrimidinic (AP) endonuclease (1). The requirement for beta-pol in single-nucleotide BER is exemplified in mouse fibroblasts with a null mutation in the beta-pol gene. These cells are hypersensitive to monofunctional DNA methylating agents such as methyl methane-sulfonate (MMS) (2). This hypersensitivity is associated with an abundance of chromosomal damage and induction of apoptosis and necrotic cell death (3). We have found that beta-pol null cells are defective in repair of MMS-induced DNA lesions, consistent with a cellular BER deficiency as a causative agent in the observed hypersensitivity. Further, the N-terminal 8-kDa domain of beta-pol, which contains the dRP lyase activity in the wild-type enzyme, is sufficient to reverse the methylating agent hypersensitivity in beta-pol null cells. These results indicate that lyase removal of the dRP group is a pivotal step in BER in vivo. Finally, we examined MMS-induced genomic DNA mutagenesis in two isogenic mouse cell lines designed for study of the role of BER. MMS exposure strongly increases mutant frequency in beta-pol null cells, but not in wild-type cells. With MMS treatment, beta-pol null cells have a higher frequency of all six base-pair substitutions, suggesting that BER plays a role in protecting the cell against methylation-induced mutations.

Keynote: past, present, and future aspects of base excision repair

Covalent alterations of DNA bases, which may have promutagenic or cytotoxic effects, are major consequences of endogenous DNA damage caused by hydrolysis, reactive oxygen species, and several metabolites and coenzymes. A common strategy for initiation of DNA base excision repair (BER) involves a DNA glycosylase that binds the altered deoxynucleoside in an extrahelical position and catalyzes cleavage of the base-sugar bond. Subsequently, an AP endonuclease or AP lyase activity incises the abasic site, followed by short-patch gap-filling, excision of the base-free sugar-phosphate residue, and ligation. The initial work that resulted in the discovery of DNA glycosylases and AP endonucleases is briefly reviewed. In recent years, it has been shown that the latter steps of the BER pathway differ greatly between mammalian cells and microorganisms such as yeast and bacteria. Three distinct subpathways of BER occur in mammalian cells, and these have been individually reconstituted with purified enzymes. Gene knockout mice are now revealing specific roles and backup mechanisms for repair functions in murine cells, and the results in general are also applicable to human cells. Future developments in the field of base excision repair include definition by proteomics of all factors involved in handling many different types of DNA lesions, clarification of mechanisms of repair of chromatin at a high level of accuracy, manifestation of repair proteins as drug targets for cellular sensitization to ionizing radiation and anticancer medicines, and elucidation of cross-talk between the base excision repair factors and other cellular proteins involved in a variety of stress responses.

Potential double-flipping mechanism by E. coli MutY

To understand the structural basis of the recognition and removal of specific mismatched bases in double-stranded DNAs by the DNA repair glycosylase MutY, a series of structural and functional analyses have been conducted. MutY is a 39-kDa enzyme from Escherichia coli, which to date has been refractory to structural determination in its native, intact conformation. However, following limited proteolytic digestion, it was revealed that the MutY protein is composed of two modules, a 26-kDa domain that retains essential catalytic function (designated p26MutY) and a 13-kDa domain that is implicated in substrate specificity and catalytic efficiency. Several structures of the 26-kDa domain have been solved by X-ray crystallographic methods to a resolution of up to 1.2 A. The structure of a catalytically incompetent mutant of p26MutY complexed with an adenine in the substrate-binding pocket allowed us to propose a catalytic mechanism for MutY. Since reporting the structure of p26MutY, significant progress has been made in solving the solution structure of the noncatalytic C-terminal 13-kDa domain of MutY by NMR spectroscopy. The topology and secondary structure of this domain are very similar to that of MutT, a pyrophosphohydrolase. Molecular modeling techniques employed to integrate the two domains of MutY with DNA suggest that MutY can wrap around the DNA and initiate catalysis by potentially flipping adenine and 8-oxoguanine out of the DNA helix.

Multiple DNA glycosylases for repair of 8-oxoguanine and their potential in vivo functions

8-Oxoguanine (8-oxoG) is a critical mutagenic lesion because of its propensity to mispair with A during DNA replication. All organisms, from bacteria to mammals, express at least two types of 8-oxoguanine-DNA glycosylase (OGG) for repair of 8-oxoG. The major enzyme class (OGG1), first identified in Escherichia coli as MutM (Fpg), and later in yeast and humans, excises 8-oxoG when paired with C, T, and G but rarely with A. In contrast, a distinct and less abundant OGG, OGG2, prefers 8-oxoG when paired with G and A as a substrate, and has been characterized in yeast and human cells. Recently, OGG2 activity was detected in E. coli which was subsequently identified to be Nei (Endo VIII). In view of the ubiquity of OGG2, we have proposed a model named "bipartite antimutagenic processing of 8-oxoguanine" and is an extension of the original "GO model." The GO model explains the presence of OGG1 (MutM) that excises 8-oxoG from nonreplicated DNA. If 8-oxoG mispairs with A during replication, MutY excises A and provides an opportunity for insertion of C opposite 8-oxoG during subsequent repair replication. Our model postulates that whereas OGG1 (MutM) is responsible for global repair of 8-oxoG in the nonreplicating genome, OGG2 (Nei) repairs 8-oxoG in nascent or transcriptionally active DNA. Interestingly, we observed that MutY and MutM reciprocally inhibited each other's catalytic activity but observed no mutual interference between Nei and MutY. This suggests that the recognition sites on the same substrate for Nei and MutY are nonoverlapping. Human OGG1 is distinct from other oxidized base-specific DNA glycosylases because of its extremely low turnover, weak AP lyase activity, and nonproductive affinity for the abasic (AP) site, its first reaction product. OGG1 is activated nearly 5-fold in the presence of AP-endonuclease (APE) as a result of its displacement by the latter. These results support the "handoff" mechanism of BER in which the enzymatic steps are coordinated as a result of displacement of the DNA glycosylase by APE, the next enzyme in the pathway. The physiological significance of multiple OGGs and their in vivo reaction mechanisms remain to be elucidated by further studies.

The mechanism of switching among multiple BER pathways

To preserve genomic beta DNA from common endogenous and exogenous base and sugar damage, cells are provided with multiple base excision repair (BER) pathways: the DNA polymerase (Pol) beta-dependent single nucleotide BER and the long-patch (2-10 nt) BER that requires PCNA. It is a challenge to identify the factors that govern the mechanism of switching among these pathways. One of these factors is the type of DNA damage induced in DNA. By using different model lesions we have shown that base damages (like hypoxanthine and 1, N6-ethenoadenine) excised by monofunctional DNA glycosylases are repaired via both single-nucleotide and long-patch BER, while lesions repaired by a bifunctional DNA glycosylase (like 7,8-dihydro-8-oxoguanine) are repaired mainly by single-nucleotide BER. The presence of a genuine 5' nucleotide, as in the case of cleavage by a bifunctional DNA glycosylase-beta lyase, would then minimize the strand displacement events. Another key factor in the selection of the BER branch is the relative level of cellular polymerases. While wild-type embryonic mouse fibroblast cell lines repair abasic sites predominantly via single-nucleotide replacement reactions (80% of the repair events), cells homozygous for a deletion in the Pol beta gene repair these lesions exclusively via long-patch BER. Following treatment with methylmethane sulfonate, these mutant cells accumulate DNA single-strand breaks in their genome in keeping with the fact that repair induced by monofunctional alkylating agents goes predominantly via single-nucleotide BER. Since the long-patch BER is strongly stimulated by PCNA, the cellular content of this cell-cycle regulated factor is also extremely effective in driving the repair reaction to either BER branch. These findings raise the interesting possibility that different BER pathways might be acting as a function of the cell cycle stage.

DNA damage recognition and repair pathway coordination revealed by the structural biochemistry of DNA repair enzymes

Cells have evolved distinct mechanisms for both preventing and removing mutagenic and lethal DNA damage. Structural and biochemical characterization of key enzymes that function in DNA repair pathways are illuminating the biological and chemical mechanisms that govern initial lesion detection, recognition, and excision repair of damaged DNA. These results are beginning to reveal a higher level of DNA repair coordination that ensures the faithful repair of damaged DNA. Enzyme-induced DNA distortions allow for the specific recognition of distinct extrahelical lesions, as well as tight binding to cleaved products, which has implications for the ordered transfer of unstable DNA repair intermediates between enzymes during base excision repair.

Yeast base excision repair: interconnections and networks

The removal of oxidative base damage from the genome of Saccharomyces cerevisiae is thought to occur primarily via the base excision repair (BER) pathway in a process initiated by several DNA N-glycosylase/AP lyases. We have found that yeast strains containing simultaneous multiple disruptions of BER genes are not hypersensitive to killing by oxidizing agents, but exhibit a spontaneous hyperrecombinogenic (hyper-rec) and mutator phenotype. The hyper-rec and mutator phenotypes are further enhanced by elimination of the nucleotide excision repair (NER) pathway. Furthermore, elimination of either the lesion bypass (REV3-dependent) or recombination (RAD52-dependent) pathway results in a further, specific enhancement of the hyper-rec or mutator phenotypes, respectively. Sensitivity (cell killing) to oxidizing agents is not observed unless multiple pathways are eliminated simultaneously. These data suggest that the BER, NER, recombination, and lesion bypass pathways have overlapping specificities in the removal of, or tolerance to, exogenous or spontaneous oxidative DNA damage in S. cerevisiae. Our results also suggest a physiological role for the AP lyase activity of certain BER N-glycosylases in vivo.

Zinc binding and redox control of p53 structure and function

The p53 protein is a tumor suppressor often inactivated in cancer, which controls cell proliferation and survival through several coordinated pathways. The p53 protein is induced in response to many forms of cellular stress, genotoxic or not. p53 is a zinc-binding protein containing several reactive cysteines, and its key biochemical property, sequence-specific DNA binding, is dependent upon metal and redox regulation in vitro. In this review, we describe the main features of p53 as a metalloprotein and we discuss how metal binding and oxidation-reduction may affect p53 activity in vivo. In particular, we stress the possible involvement of thioredoxin, Ref-1 (redox factor 1), and metallothionein in the control of p53 protein conformation and activity. Furthermore, we also review the available evidence on the role of p53 as a transactivator or transrepressor of genes involved in the production and control of reactive oxygen intermediates. Overall, these data indicate that p53 lies at the center of a network of complex redox interactions. In this network, p53 can control the timely production of reactive oxygen intermediates (e.g., to initiate apoptosis), but this activity is itself under the control of changes in metal levels and in cellular redox status. This redox sensitivity may be one of the biochemical mechanisms by which p53 acts as a "sensor" of multiple forms of stress.

Redox regulation of the DNA repair function of the human AP endonuclease Ape1/ref-1

The second enzyme in the DNA base excision repair (BER) pathway, apurinic/apyrimidinic (AP) endonuclease or Ape1, hydrolyzes the phosphodiester backbone immediately 5' to an AP site generating a normal 3'-hydroxyl group and an abasic deoxyribose-5-phosphate, which is processed by subsequent enzymes of the BER pathway. AP sites are the most common form of DNA damage, and the persistence of AP sites in DNA results in a block to DNA replication, cytotoxic mutations, and genetic instability. Interestingly, Ape1/ref-1 is a multifunctional protein that not only is a DNA repair enzyme, but also functions as a redox factor maintaining transcription factors, such as Fos, Jun, nuclear factor-kappaB, PAX (paired box-containing family of genes), hypoxia inducible factor-lalpha (HIF-1alpha), HIF-1-like factor, and p53, in an active reduced state. Apel/ref-1 has also been implicated in a number of other activities, one of which is the activation of bioreductive drugs requiring reduction for activity. In this report, we present data supporting our findings that another level of posttranslational modification of Apel/ref-1 that clearly affects the AP endonuclease activity is the reduction or oxidation of this protein. Furthermore, we show data demonstrating that at least one of the sites involved in this redox regulation is the cysteine amino acid found at position 310, immediately adjacent to the crucial histidine residue at position 309 in the DNA repair active site. These findings suggest that the Apel/ref-1 protein may be much more intimately regulated at the posttranslational level than initially imagined.

Histology-specific expression of a DNA repair protein in pediatric rhabdomyosarcomas

PURPOSE

DNA repair enzymes have a critical role in cellular maintenance and survival. The enzyme apurinic/apyrimidinic endonuclease/redox factor 1 (APE/ref1), a key protein in the base excision repair pathway, displays both repair and redox control. We examined the role of APE/ref1 in pediatric embryonal and alveolar rhabdomyosarcomas (ARMS).

MATERIALS AND METHODS

Using an immunohistochemical method, fixed tissue from 31 newly diagnosed pediatric rhabdomyosarcomas were evaluated for expression of APE/ref1. Tissue was obtained from Indiana University and the Cooperative Human Tissue Network.

RESULTS

We demonstrated high levels of expression within the localized and metastatic embryonal rhabdomyosarcomas. This contrasted with both localized and metastatic ARMS, which had low levels of APE/ref1 expression. This histology-specific difference proved to be significant (P = 0.003). Furthermore, the expression within all tumors examined was localized to the nucleus and did not differ between localized and metastatic tumors.

CONCLUSIONS

We propose several hypotheses to explain this histology-specific expression of APE/ref1 in pediatric rhabdomyosarcomas. Because the majority of ARMS expressed either the PAX3/FKHR or PAX7/FKHR fusion transcript, the low level of expression may be related to the redox activity of APE/ref1. The low levels may also be related to the bioreductive activity of APE/ref 1.

3'-phosphodiesterase and 3'-->5' exonuclease activities of yeast Apn2 protein and requirement of these activities for repair of oxidative DNA damage

In Saccharomyces cerevisiae, the AP endonucleases encoded by the APN1 and APN2 genes provide alternate pathways for the removal of abasic sites. Oxidative DNA-damaging agents, such as H(2)O(2), produce DNA strand breaks which contain 3'-phosphate or 3'-phosphoglycolate termini. Such 3' termini are inhibitory to synthesis by DNA polymerases. Here, we show that purified yeast Apn2 protein contains 3'-phosphodiesterase and 3'-->5' exonuclease activities, and mutation of the active-site residue Glu59 to Ala in Apn2 inactivates both these activities. Consistent with these biochemical observations, genetic studies indicate the involvement of APN2 in the repair of H(2)O(2)-induced DNA damage in a pathway alternate to APN1, and the Ala59 mutation inactivates this function of Apn2. From these results, we conclude that the ability of Apn2 to remove 3'-end groups from DNA is paramount for the repair of strand breaks arising from the reaction of DNA with reactive oxygen species.

Going APE over ref-1

The DNA base excision repair (BER) pathway is responsible for the repair of cellular alkylation and oxidative DNA damage. A crucial and the second step in the BER pathway involves the cleavage of baseless sites in DNA by an AP endonuclease. The major AP endonuclease in mammalian cells is Ape1/ref-1. Ape1/ref-1 is a multifunctional protein that is not only responsible for repair of AP sites, but also functions as a reduction-oxidation (redox) factor maintaining transcription factors in an active reduced state. Ape1/ref-1 has been shown to stimulate the DNA binding activity of numerous transcription factors that are involved in cancer promotion and progression such as Fos, Jun, NF(B, PAX, HIF-1(, HLF and p53. Ape1/ref-1 has also been implicated in the activation of bioreductive drugs which require reduction in order to be active and has been shown to interact with a subunit of the Ku antigen to act as a negative regulator of the parathyroid hormone promoter, as well as part of the HREBP transcription factor complex. Ape1/ref-1 levels have been found to be elevated in a number of cancers such as ovarian, cervical, prostate, rhabdomyosarcomas and germ cell tumors and correlated with the radiosensitivity of cervical cancers. In this review, we have attempted to try and assimilated as much data concerning Ape1/ref-1 and incorporate the rapidly growing information on Ape1/ref-1 in a wide variety of functions and systems.

A novel action of human apurinic/apyrimidinic endonuclease: excision of L-configuration deoxyribonucleoside analogs from the 3' termini of DNA

beta-l-Dioxolane-cytidine (l-OddC, BCH-4556, Troxacitabine) is a novel unnatural stereochemical nucleoside analog that is under phase II clinical study for cancer treatment. This nucleoside analog could be phosphorylated and subsequently incorporated into the 3' terminus of DNA. The cytotoxicity of l-OddC was correlated with the amount of l-OddCMP in DNA, which depends on the incorporation by DNA polymerases and the removal by exonucleases. Here we reported the purification and identification of the major enzyme that could preferentially remove l-OddCMP compared with dCMP from the 3' termini of DNA in human cells. Surprisingly, this enzyme was found to be apurinic/apyrimidinic endonuclease (APE1) (), a well characterized DNA base excision repair protein. APE1 preferred to remove l- over d-configuration nucleosides from 3' termini of DNA. The efficiency of removal of these deoxycytidine analogs were as follows: l-OddC > beta-l-2',3'-dideoxy-2', 3'-didehydro-5-fluorocytidine > beta-l-2',3'-dideoxycytidine > beta-l-2',3'-dideoxy-3'-thiocytidine > beta-d-2',3'-dideoxycytidine > beta-d-2',2'-difluorodeoxycytidine > beta-d-2'-deoxycytidine >/= beta-d-arabinofuranosylcytosine. This report is the first demonstration that an exonuclease can preferentially excise l-configuration nucleoside analogs. This discovery suggests that APE1 could be critical for the activity of l-OddC or other l-nucleoside analogs and may play additional important roles in cells that were not previously known.

Human APE/Ref-1 protein

Human apurinic (apyrimidinic) endonuclease/redox-factor 1 (APE/Ref-1) is an ubiquitously expressed multifunctional protein of 36.5 kDa which is encoded by a approximately 3 kb gene localized on chromosome 14. APE/Ref-1 is involved in the repair of DNA damage as well as in the transcriptional regulation of genes. The repair function of the protein is located on its C-terminal region. Activation of transcription factors, which occurs via a redox-based mechanism, pertains to a approximately 6 kDa N-terminal fragment with Cys-65 being of essential importance. APE/Ref-1 is part of the cellular response to oxidative stress and protects cells from the genotoxic and cytotoxic effect of oxidizing agents. Thus, specific downmodulation of APE/Ref-1 activity in tumors might be considered as a novel therapeutic approach in tumor therapy.

Lessons learned from structural results on uracil-DNA glycosylase

Uracil-DNA glycosylase (UDG) functions as a sentry guarding against uracil in DNA. UDG initiates DNA base excision repair (BER) by hydrolyzing the uracil base from the deoxyribose. As one of the best studied DNA glycosylases, a coherent and complete functional mechanism is emerging that combines structural and biochemical results. This functional mechanism addresses the detection of uracil bases within a vast excess of normal DNA, the features of the enzyme that drive catalysis, and coordination of UDG with later steps of BER while preventing the release of toxic intermediates. Many of the solutions that UDG has evolved to overcome the challenges of policing the genome are shared by other DNA glycosylases and DNA repair enzymes, and thus appear to be general.

Abasic site recognition by two apurinic/apyrimidinic endonuclease families in DNA base excision repair: the 3' ends justify the means

DNA damage occurs unceasingly in all cells. Spontaneous DNA base loss, as well as the removal of damaged DNA bases by specific enzymes targeted to distinct base lesions, creates non-coding and lethal apurinic/apyrimidinic (AP) sites. AP sites are the central intermediate in DNA base excision repair (BER) and must be processed by 5' AP endonucleases. These pivotal enzymes detect, recognize, and cleave the DNA phosphodiester backbone 5' of, AP sites to create a free 3'-OH end for DNA polymerase repair synthesis. In humans, AP sites are processed by APE1, whereas in yeast the primary AP endonuclease is termed APN1, and these enzymes are the major constitutively expressed AP endonucleases in these organisms and are homologous to the Escherichia coli enzymes Exonuclease III (Exo III) and Endonuclease IV (Endo IV), respectively. These enzymes represent both of the conserved 5' AP endonuclease enzyme families that exist in biology. Crystal structures of APE1 and Endo IV, both bound to AP site-containing DNA reveal how abasic sites are recognized and the DNA phosphodiester backbone cleaved by these two structurally unrelated enzymes with distinct chemical mechanisms. Both enzymes orient the AP-DNA via positively charged complementary surfaces and insert loops into the DNA base stack, bending and kinking the DNA to promote flipping of the AP site into a sequestered enzyme pocket that excludes undamaged nucleotides. Each enzyme-DNA complex exhibits distinctly different DNA conformations, which may impact upon the biological functions of each enzyme within BER signal-transduction pathways.

An 'environment to nucleus' signaling system operates in B lymphocytes: redox status modulates BSAP/Pax-5 activation through Ref-1 nuclear translocation

The Ref-1 (also called APE or HAP1) protein is a bifunctional enzyme impacting on a wide variety of important cellular functions. It acts as a major member of the DNA base excision repair pathway. Moreover, Ref-1 stimulates the DNA-binding activity of several transcription factors (TFs) through the reduction of highly reactive cysteine residues. Therefore, it represents a mechanism that regulates eukaryotic gene expression in a fast way. However, it has been demonstrated that external stimuli directly act on Ref-1 by increasing its expression levels, a time-consuming mechanism representing a paradox in terms of rapidity of TF regulation. In this paper we demonstrate that this is only an apparent paradox. Exposure of B lymphocytes to H(2)O(2)induced a rapid and sustained increase in Ref-1 protein levels in the nucleus as evaluated by both western blot analysis and by pulse-chase experiments. A time course, two color in situ immunocytochemistry indicated that the up-regulation of Ref-1 in the nucleus at <30 min was primarily the consequence of translocation of its cytoplasmic form. This early nuclear accumulation is effective in modulating the DNA-binding activity of the B cell-specific activator protein BSAP/Pax-5. In fact, EMSA experiments demonstrate that a transient interaction with Ref-1 up-regulates the DNA-binding activity of BSAP/Pax-5. Moreover, in a co-transfection experiment, Ref-1 increased the BSAP/Pax-5 activating effect on an oligomerized BSAP/Pax-5 binding site of the CD19 promoter by 5- to 8-fold. Thus, Ref-1 mediates its effect by up-regulating the DNA-binding activity of BSAP/Pax-5, accounting for a new and fast outside/inside pathway of signaling in B cells.

Fusions with histone H3 result in highly specific alteration of gene expression

Hap1 is a yeast transcriptional activator which controls expression of genes such as CYC1 and CYC7. Our results show that Hap1 activity is dependent on a functional chromatin remodeling complex SWI/SNF. Using a modified two-hybrid screen with Hap1 as bait, we recovered expression vectors encoding the Gal4 activation domain fused to histone H3 [Gal4(AD)-H3]. Hap1 activity at CYC1 or CYC7 was increased by Gal4(AD)-H3 and the effect was dependent on the presence of the activation domain of Hap1 and a functional SWI complex. Importantly, overexpression of H3 alone had no effect on Hap1 activity. Analysis of Gal4(AD)-H3 revealed that the fusion is not incorporated into the nucleosome while a functional Gal4 activation domain is dispensable. Activity of many other transcriptional activators was unchanged or slightly affected in the presence of Gal4(AD)-H3. Thus, our results identify a new class of histone H3 variants that cause highly specific alteration of gene expression. Hap1 may interact directly with H3 favoring chromatin remodeling by the SWI/SNF complex.

Copper-zinc superoxide dismutase prevents the early decrease of apurinic/apyrimidinic endonuclease and subsequent DNA fragmentation after transient focal cerebral ischemia in mice

BACKGROUND AND PURPOSE

DNA damage and its repair mechanism are thought to be involved in ischemia/reperfusion injury in the brain. We have previously shown that apurinic/apyrimidinic endonuclease (APE/Ref-1), a multifunctional protein in the DNA base excision repair pathway, rapidly decreased after transient focal cerebral ischemia (FCI) before the peak of DNA fragmentation. To further investigate the role of reactive oxygen species in APE/Ref-1 expression in vivo, we examined the expression of APE/Ref-1 and DNA damage after FCI in wild-type and transgenic mice overexpressing copper-zinc superoxide dismutase.

METHODS

Transgenic mice overexpressing copper-zinc superoxide dismutase and wild-type littermates were subjected to 60 minutes of transient FCI by intraluminal blockade of the middle cerebral artery. APE/Ref-1 protein expression was analyzed by immunohistochemistry and Western blot analysis. DNA damage was evaluated by gel electrophoresis and terminal deoxynucleotidyl transferase-mediated uridine 5'-triphosphate-biotin nick end-labeling (TUNEL).

RESULTS

A similar level of APE/Ref-1 was detected in the control brains from both groups. APE/Ref-1 was significantly reduced 1 hour after transient FCI in both groups, whereas the transgenic mice had less reduction than that seen in wild-type mice 1 and 4 hours after FCI. DNA laddering was detected 24 hours after FCI and was decreased in transgenic mice. Double staining with APE/Ref-1 and TUNEL showed that the neurons that lost APE/Ref-1 immunoreactivity became TUNEL positive.

CONCLUSIONS

These results suggest that reactive oxygen species contribute to the early decrease of APE/Ref-1 and thereby exacerbate DNA fragmentation after transient FCI in mice.

Endonuclease III and endonuclease IV protect Escherichia coli from the lethal and mutagenic effects of near-UV irradiation

In contrast to the DNA damage caused by far-UV (lambda < 290 nm), near-UV (290 < lambda < 400 nm) induced DNA damage is partially oxygen dependent, suggesting the involvement of reactive oxygen species. To test the hypothesis that enzymes that protect cells from oxidative DNA damage are also involved in preventing near-UV mediated DNA damage, isogenic strains deficient in one or more of exonuclease III (xthA), endonuclease IV (nfo), and endonuclease III (nth) were exposed to increasing levels of far-UV and near-UV. All strains, with the exception of the nth single mutant, were found to be hypersensitive to the lethal effects of near-UV relative to a wild-type strain. A triple mutant strain (nth nfo xthA) exhibited the greatest sensitivity to near-UV-mediated lethality. The triple mutant was more sensitive than the nfo xthA double mutant to the lethal effects of near-UV, but not far-UV. A forward mutation assay also revealed a significantly increased sensitivity for the triple mutant compared to the nfo xthA deficient strain in the presence of near-UV. However, the triple mutant was no more sensitive to the mutagenic effects of far-UV than a nfo xthA double mutant. These data suggest that exonuclease III, endonuclease IV, and endonuclease III are important in protection against near-UV-induced DNA damage.

A new class of repression modules is critical for heme regulation of the yeast transcriptional activator Hap1

Heme plays key regulatory roles in numerous molecular and cellular processes for systems that sense or use oxygen. In the yeast Saccharomyces cerevisiae, oxygen sensing and heme signaling are mediated by heme activator protein 1 (Hap1). Hap1 contains seven heme-responsive motifs (HRMs): six are clustered in the heme domain, and a seventh is near the activation domain. To determine the functional role of HRMs and to define which parts of Hap1 mediate heme regulation, we carried out a systematic analysis of Hap1 mutants with various regions deleted or mutated. Strikingly, the data show that HRM1 to -6, located in the previously designated Hap1 heme domain, have little impact on heme regulation. All seven HRMs are dispensable for Hap1 repression in the absence of heme, but HRM7 is required for Hap1 activation by heme. More importantly, we show that a novel class of repression modules-RPM1, encompassing residues 245 to 278; RPM2, encompassing residues 1061 to 1185; and RPM3, encompassing residues 203 to 244-is critical for Hap1 repression in the absence of heme. Biochemical analysis indicates that RPMs mediate Hap1 repression, at least partly, by the formation of a previously identified higher-order complex termed the high-molecular-weight complex (HMC), while HRMs mediate heme activation by permitting heme binding and the disassembly of the HMC. These findings provide significant new insights into the molecular interactions critical for Hap1 repression in the absence of heme and Hap1 activation by heme.

[The function of Huntington disease gene product (huntingtin) and the pathomechanism of Huntington disease]

The recent knowledges about the functions of huntingtin and the pathomechanism of Huntington disease are reviewed. Several binding proteins such as HAP1, ubiquitin-conjugating enzyme, HIP1, glyceraldehyde-3-phosphate-dehydrogenase(GAPDH), and cystathionine beta-synthase are identified. One of the functions of huntingtin suggested by those binding proteins is organella transport. In addition huntington binds with WW domain proteins and SH3 domain. The most exciting discovery of Huntington disease pathomechanism is identification of nuclear inclusions in transgenic mouse model of Huntington disease. The discussion about the significance of nuclear inclusion for the cell death was reviewed.

Phosphorylation of the DNA repair protein APE/REF-1 by CKII affects redox regulation of AP-1

The DNA repair protein apurinic endonuclease (APE/Ref-1) exerts several physiological functions such as cleavage of apurinic/apyrimidinic sites and redox regulation of the transcription factor AP-1, whose activation is part of the cellular response to DNA damaging treatments. Here we demonstrate that APE/Ref-1 is phosphorylated by casein kinase II (CKII). This was shown for both the recombinant APE/Ref-1 protein (Km=0.55 mM) and for APE/Ref-1 expressed in COS cells. Phosphorylation of APE/Ref-1 did not alter the repair activity of the enzyme, whereas it stimulated its redox capability towards AP-1, thus promoting DNA binding activity of AP-1. Inhibition of CKII mediated phosphorylation of APE/Ref-1 blocked mutagen-stimulated increase in AP-1 binding. It also abrogated the induction of c-Jun protein and rendered cells more sensitive to induced DNA damage. Thus, phosphorylation of APE/Ref-1 appears to be involved in regulating the different physiological activities of the enzyme. CKII mediated phosphorylation of APE/Ref-1 and concomitant increase in AP-1 binding activity appears to be a novel mechanism of cellular stress response, forcing transcription of AP-1 target gene(s) the product(s) of which may exert protective function.

Mutation in P0, a dual function ribosomal protein/apurinic/apyrimidinic endonuclease, modifies gene expression and position effect variegation in Drosophila

In a search for modifiers of gene expression with the white eye color gene as a target, a third chromosomal P-element insertion mutant l(3)01544 has been identified that exhibits a strong pigment increase in a white-apricot background. Molecular analysis shows that the P-element insertion is found in the first intron of the gene surrounding the insertion site. Sequencing both the cDNA and genomic fragments revealed that the identified gene is identical to one encoding ribosomal protein P0/apurinic/apyrimidinic endonuclease. The P-element-induced mutation, l(3)01544, affects the steady-state level of white transcripts and transcripts of some other genes. In addition, l(3)01544 suppresses the variegated phenotypes of In(1)wm4h and In(1)y3P, suggesting a potential involvement of the P0 protein in modifying position effect variegation. The revertant generated by the precise excision of the P element has lost all mutant phenotypes. Recent work revealed that Drosophila ribosomal protein P0 contains an apurinic/apyrimidinic endonuclease activity. Our results suggest that this multifunctional protein is also involved in regulation of gene expression in Drosophila.

A murine AP-endonuclease gene-targeted deficiency with post-implantation embryonic progression and ionizing radiation sensitivity

Apurinic/apyrimidinic endonuclease (here designated APE/REF) carries out repair incision at abasic or single-strand break damages in mammals. This multifunctional protein also has putative role(s) as a cysteine 'reducing factor' (REF) in cell-stress transcriptional responses. To assess the significance of APE/REF for embryonic teratogenesis we constructed a more precisely targeted Ape/Ref-deficient genotype in mice. Ape/Ref gene replacement in ES cells eliminated the potential of APE/REF protein synthesis while retaining the Ape/Ref bi-directional promoter that avoided potential inactivation of an upstream gene. Chimeric animals crossed into Tac:N:NIHS-BC produced germline transmission. Homozygous null Ape/Ref-embryos exhibited successful implantation and nearly normal developmental progression until embryonic day 7.5 followed by morphogenetic failure and adsorption of embryos by day 9.5. We characterized the cellular events proceeding to embryonic lethality and examined ionizing radiation sensitivity of pre-implantation Ape/Ref-null embryos. After intermating of heterozygotes, Mendelian numbers of putative Ape/Ref-null progeny embryos at day 6.5 displayed a several-fold elevation of pycnotic, fragmenting cell nuclei within the embryo proper-the epiblast. Increased cell-nucleus degeneration occurred within epiblast cells while mitosis continued and before obvious morphogenetic disruption. Mitogenic response to epiblast cell death, if any, was ineffective for replacement of lost cells. Extra-embryonic yolk sac, a trophectoderm derived lineage retained normal appearance to day 9. Explanted homozygous Ape/Ref-null blastocysts displayed increased sensitivity to gamma-irradiation, most likely a manifestation of APE/REF incision defect. Our study establishes that this new Ape/Ref deficiency genotype is definitely capable of post-implantation developmental progression to the onset of gastrulation. Function(s) of APE/REF in base damage incision and also conceivably in mitogenic responses towards epiblast cell death are critical for transit through the gastrulation stage of embryonic growth and development.