New substrates for old enzymes. 5-Hydroxy-2'-deoxycytidine and 5-hydroxy-2'-deoxyuridine are substrates for Escherichia coli endonuclease III and formamidopyrimidine DNA N-glycosylase, while 5-hydroxy-2'-deoxyuridine is a substrate for uracil DNA N-glycosylase

5-Hydroxy-2'-deoxycytidine (5-OHdC) and 5-hydroxy-2'-deoxyuridine (5-OHdU) are major products of oxidative DNA damage with mutagenic potential. Until now, no enzymatic activity responsible for their removal has been identified. We report here that both 5-OHdC and 5-OHdU are substrates for Escherichia coli endonuclease III and formamidopyrimidine DNA N-glycosylase (FPG). 5-OHdU is also a substrate for uracil DNA N-glycosylase. Consistent with their mechanisms of action on previously described substrates, endonuclease III removes 5-OHdC and 5-OHdU via a N-glycosylase/beta-elimination reaction, FPG follows a N-glycosylase/beta,delta-elimination reaction, and uracil N-glycosylase removes 5-OHdU by N-glycosylase action leaving behind an abasic site. Endonuclease III removes both lesions more efficiently than FPG, and both endonuclease III and FPG remove 5-OHdC slightly more efficiently than 5-OHdU. Uracil DNA N-glycosylase removes 5-OHdU more efficiently than the other two enzymes and has no activity on 5-OHdC even when present in great excess. Analysis of crude extracts obtained from wild type and endonuclease III deletion mutants of E. coli correlated well with data obtained with the purified enzymes.

Alpha-deoxyadenosine, a major anoxic radiolysis product of adenine in DNA, is a substrate for Escherichia coli endonuclease IV

Oligonucleotides containing a unique alpha-deoxyadenosine or tetrahydrofuran (a model abasic site) were synthesized using phosphoramidite chemistry. Repair enzymes from Escherichia coli, including endonucleases III, IV, and VIII, exonuclease III, formamidopyrimidine N-glycosylase, and deoxyinosine 3'-endonuclease, as well as UV dimer N-glycosylases from T4 (den V) and Micrococcus luteus, were examined for their ability to recognize alpha-deoxyadenosine and tetrahydrofuran. In agreement with prior studies, a tetrahydrofuran-containing oligonucleotide was a substrate for endonuclease IV and exonuclease III, but not for the other repair enzymes. However, an oligonucleotide containing alpha-deoxyadenine was a substrate only for endonuclease IV. Competitive inhibition studies with both substrates confirmed that the activity recognizing alpha-deoxyadenine was endonuclease IV and not a possible contaminant in the endonuclease IV preparation. Using E. coli extracts, the activity that recognized alpha-deoxyadenine was dependent on nfo, the structural gene of endonuclease IV, further substantiating that endonuclease IV is the enzyme that recognized alpha-deoxyadenine. Kinetic measurements indicated that alpha-deoxyadenosine was as good a substrate for endonuclease IV as tetrahydrofuran; the Km and Vmax values for both substrates were similar. Using substrates that were labeled at either the 3'- or 5'-terminus, endonuclease IV was shown to hydrolyze the phosphodiester bond 5' to either alpha-deoxyadenosine or tetrahydrofuran, leaving the lesion, alpha-deoxyadenosine or tetrahydrofuran, on the 5'-terminus of the nicked site. The ability of endonuclease IV to recognize alpha-deoxyadenosine suggests that endonuclease IV is able to recognize a new class of DNA base lesions that is not recognized by other DNA N-glycosylases and AP endonucleases.

Purification and characterization of a novel deoxyinosine-specific enzyme, deoxyinosine 3' endonuclease, from Escherichia coli

We have purified a novel endonuclease from Escherichia coli that recognizes deoxyinosine, a deamination product of deoxyadenosine in DNA. This activity, which we named deoxyinosine 3' endonuclease, is different from the known hypoxanthine DNA N-glycosylases which have been partially characterized in E. coli and other organisms. The enzyme was purified 24,800-fold to apparent homogeneity. SDS- and activity PAGE analyses indicate that the enzyme has an apparent molecular mass of 25 kDa. Deoxyinosine 3' endonuclease recognized deoxyinosine in both single- and double-stranded DNA but exhibited a 4-fold preference for double stranded over single-stranded DNA. In addition to deoxyinosine, the enzyme recognized urea residues and AP sites. Deoxyinosine 3' endonuclease has an obligatory requirement for Mg2+, but other cations such as Co2+ and Mn2+ could partially replace Mg2+. The optimal pH for deoxyinosine 3' endonuclease was around 7.5. In contrast to most of the known repair enzymes, deoxyinosine 3' endonuclease makes an incision at the second phosphodiester bond 3' to a deoxyinosine or AP site, leaving behind the intact lesion on the nicked DNA. Therefore, deoxyinosine 3' endonuclease recognizes, but does not remove, the lesion from the DNA molecule. The biological significance of this novel activity is discussed with reference to other repair activities in E. coli.

Isolation and characterization of endonuclease VIII from Escherichia coli

Endonuclease VIII, a novel presumptive DNA repair enzyme, was isolated from Escherichia coli by FPLC1 purification. The enzyme was found in strains that contained or lacked endonuclease III and was purified by radial flow S-Sepharose, Mono S, phenyl-Superose, and Superose 12 FPLC. Examination of the properties of endonuclease VIII showed it to have many similarities to endonuclease III. DNA containing thymine glycol, dihydrothymine, beta-ureidoisobutyric acid, urea residues, or AP sites was incised by the enzyme; however, DNA containing reduced AP sites was not. HPLC analysis of the products formed by exhaustive enzymatic digestion of damage-containing DNA showed that endonuclease VIII released thymine glycol and dihydrothymine as free bases. Taken together, these data suggest that endonuclease VIII contains both N-glycosylase and AP lyase activities. Consistent with this idea, DNA containing AP sites or thymine glycols, that was enzymatically nicked by endonuclease VIII was not a good substrate for E. coli DNA polymerase I, suggesting that endonuclease VIII nicks damage-containing DNA on the 3' side of the lesion. Also, since monophosphates were not released after treating thymine glycol-containing DNA with endonuclease VIII, the enzyme does not appear to have exonuclease activity. The enzyme activity was maximal in 75 mM NaCl or 5 mM MgCl2. Analysis of endonuclease VIII by both Superose FPLC and Sephadex yielded native molecular masses of 28,000 and 30,000 Da, respectively. SDS-PAGE, in conjunction with activity gel analysis, gave a molecular mass of about 29,000 Da. Furthermore, renaturation of the putative active band from SDS-PAGE gave rise to an active enzyme.

Major oxidative products of cytosine, 5-hydroxycytosine and 5-hydroxyuracil, exhibit sequence context-dependent mispairing in vitro

Two major stable oxidation products of 2'-deoxycytidine are 2'-deoxy-5-hydroxycytidine (5-OHdC) and 2'-deoxy-5-hydroxyuridine (5-OHdU). In order to study the in vitro incorporation of 5-OHdC and 5-OHdU into DNA by DNA polymerase, and to check the base pairing specificity of these modified bases, 5-OHdCTP and 5-OHdUTP were synthesized. Incorporation studies showed that 5-OHdCTP can replace dCTP, and to a much lesser extent dTTP, as a substrate for Escherichia coli DNA polymerase I Klenow fragment (exonuclease free). However, 5-OHdUTP can only be incorporated into DNA in place of dTTP. To study the specificity of nucleotide incorporation opposite 5-hydroxypyrimidines in template DNA, 18- and 45-member oligodeoxyribonucleotides, containing an internal 5-OHdC or 5-OHdU in two different sequence contexts, were used. Translesion synthesis past 5-OHdC and 5-OHdU in both oligonucleotides occurred, but pauses both opposite, and one nucleotide prior to, the modified base in the template were observed. The specificity of nucleotide incorporation opposite 5-OHdC and 5-OHdU in the template was sequence context dependent. In one sequence context, dG was the predominant nucleotide incorporated opposite 5-OHdC with dA incorporation also observed; in this sequence context, dA was the principal nucleotide incorporated opposite 5-OHdU. However in a second sequence context, dC was the predominant base incorporated opposite 5-OHdC. In that same sequence context, dC was also the predominant nucleotide incorporated opposite 5-OHdU. These data suggest that the 5-hydroxypyrimidines have the potential to be premutagenic lesions leading to C-->T transitions and C-->G transversions.

Chemically altered apurinic sites in phi X174 DNA give increased mutagenesis in SOS-induced E. coli

Single-strand DNA from bacteriophage phi X174 am3 is treated with mild acid and heat to produce increasing numbers of apurinic sites per molecule. Samples are assayed, either directly or after additional chemical reactions, by electroporation into the recipient E. coli strain HF4714(su-1+). Modified apurinic sites are produced by reactions with O-methyl- or O-benzyl-hydroxylamine, and reduced apurinic sites by reactions with sodium borohydride. Reversion mutation frequencies are significant only if the recipient strain is SOS-induced (by growth after UV irradiation). A simple apurinic site at the target gives rise to mutation (a transversion) with a probability of 0.07, while the modified or reduced apurinic site has a mutagenic efficiency of 0.22-0.27 or 0.29, respectively. The open ring form of deoxyribose may account for the 3-4-fold increased mutagenicity with altered apurinic lesions. Also considered are effects by temperature and cyclobutane pyrimidine dimers on mutagenicity and the relatively invariant survival curves that obtain regardless of chemical alterations at the apurinic sites and/or SOS induction.

Absence of a role for DNA polymerase II in SOS-induced translesion bypass of phi X174

In order to examine the possible role of Escherichia coli DNA polymerase II in SOS-induced translesion bypass, Weigle reactivation and mutation induction were measured with single-stranded phi X174 transfecting DNA containing individual lesions. No decrease in bypass of thymine glycol or cyclobutane pyrimidine dimers in the absence of DNA polymerase II was observed. Furthermore, DNA polymerase II did not affect bypass of abasic sites when either survival or mutagenesis was the endpoint. Lastly, repair of gapped DNA molecules, intermediates in methyl-directed mismatch repair, was also unaffected by the presence or absence of DNA polymerase II.

Properties of a monoclonal antibody for the detection of abasic sites, a common DNA lesion

The abasic site is one of the most frequent changes occurring in DNA and has been shown to be lethal and mutagenic. An abasic site in DNA can be tagged by reaction with O-4-nitrobenzylhydroxylamine (NBHA), resulting in the formation of an oxime linkage between the abasic site and the NBHA moiety. In order to measure NBHA-tagged abasic sites, a monoclonal antibody was elicited against a 5'-phosphodeoxyribosyl O-4-nitrobenzyl hydroxylamine-BSA conjugate. The antibody was specific for the NBHA residue as demonstrated by hapten inhibition, with IC50 values for 5'-phosphodeoxyribosyl-NBHA, deoxyribosyl-NBHA, ribosyl-NBHA and NBHA of 0.3 microM, 5 microM, 5 microM and 7 microM, respectively. Other haptens examined, including benzylhydroxylamine, 5'-phosphodeoxyribosyl-, deoxyribosyl-, and ribosyl-benzylhydroxylamine, showed no inhibition even at 1 mM. The antibody showed high specificity for NBHA-modified AP sites in DNA and exhibited no cross reactivity with normal DNA bases, otherwise-modified DNA bases or unmodified AP sites. Using a direct ELISA assay, the antibody detected 1 AP site (after NBHA-modification) per 10,000 base-pairs or approximately 10 femtomoles of AP sites in DNA. DNA lesions were detectable in 60Co gamma-irradiated DNA at a dose as low as 10 rad (0.1 Gy) and the production of antibody detectable sites was proportional to the gamma-ray dose. Since NBHA reacts with lesions containing an aldehyde group, the simplicity and sensitivity of the antibody assay should provide a useful method for the quantitation of AP sites or other DNA lesions containing an aldehyde group.

A novel, sensitive, and specific assay for abasic sites, the most commonly produced DNA lesion

Free radicals produce a wide spectrum of damages; among these are DNA base damages and abasic (AP) sites. Although several methods have been used to detect and quantify AP sites, they either are relatively laborious or require the use of radioactivity. A novel reagent for detecting abasic sites in DNA was prepared by reacting O-(carboxymethyl)hydroxylamine with biotin hydrazide in the presence of carbodiimide. This reagent, called Aldehyde Reactive Probe (ARP), specifically tagged AP sites in DNA with biotin residues. The number of biotin-tagged AP sites was then determined colorimetrically by an ELISA-like assay using avidin/biotin complex conjugated to horseradish peroxidase as the indicator enzyme. With heat/acid-depurinated calf thymus or bacteriophage f1 DNA, ARP detected femtomoles of AP sites in DNA. Using this assay, DNA damages generated in calf thymus, phi X174 RF, and f1 single-stranded DNA, X-irradiated in phosphate buffer, were easily detectable at 10 rad (0.1 Gy). Furthermore, ARP sites were detectable in DNA isolated from heat-inactivated X-irradiated (10 Gy) and methyl methanesulfonate (MMS)-treated (5 microM) Escherichia coli cells. The rate of production of ARP sites was proportional to the X-ray dose as well as to the concentration of MMS. Thus, the sensitivity and simplicity of the ARP assay should provide a potentially powerful method for the quantitation of AP sites or other DNA lesions containing an aldehyde group.

Processing of model single-strand breaks in phi X-174 RF transfecting DNA by Escherichia coli

The inactivation efficiency and repair of single-strand breaks was investigated using model strand breaks created by endonucleolytic incision of damaged DNA. Phi X-174 duplex transfecting DNA containing either thymine glycols, urea residues, or abasic (AP) sites was incubated with AP endonucleases that produce breaks on the 3' side, the 5' side, or both sides of the lesion. For each lesion, incubation with Escherichia coli endonuclease III results in a single-strand break containing a 3' alpha, beta-unsaturated aldehyde (4-hydroxy-2-pentenal), while treatment of AP- or urea-containing DNA with E. coli endonuclease IV results in a single-strand break containing a 5' deoxyribose or a 5' deoxyribosylurea moiety, respectively. Incubation of lesion-containing DNA with both enzymes results in a base gap. Ligatable nicks containing 3' hydroxyl and 5' phosphate moieties were produced by subjecting undamaged DNA to DNase I. When the biological activity of these DNAs was assessed in wild-type cells, ligatable nicks were not lethal, but each of the other strand breaks tested was lethal, having inactivation efficiencies between 0.12 and 0.14. These inactivation efficiencies are similar to those of the base lesions from which the strand breaks were derived. In keeping with the current model of base excision repair, when phi X duplex DNA containing strand breaks with a blocked 3' terminus was transfected into an E. coli double mutant lacking the major 5' cellular AP endonucleases, a greater than twofold decrease in survival was observed. Moreover, when this DNA was treated with a 5' AP endonuclease prior to transfection, the survival returned to that of wild type. As expected, when DNA containing strand breaks with a 5' blocked terminus or DNA containing base gaps was transfected into the double mutant lacking 5' AP endonucleases, the survival was the same as in wild-type cells. The decreased survival of transfecting DNA containing thymine glycols, urea, or AP sites observed in appropriate base excision repair-defective mutants was also obviated if the DNA was incubated with the homologous enzyme prior to transfection. Thus, in every case, with both base lesions and single-strand breaks, the lesion was repaired in the cell by the enzyme that recognizes it in vitro. Furthermore, the repair step in the cell could be eliminated if the appropriate enzyme was added in vitro prior to transfection.(ABSTRACT TRUNCATED AT 400 WORDS)

Damage repertoire of the Escherichia coli UvrABC nuclease complex includes abasic sites, base-damage analogues, and lesions containing adjacent 5' or 3' nicks

Using oligonucleotide synthesis, we demonstrate a rapid and efficient method for the construction of DNA duplexes containing defined DNA lesions at specific positions. These DNA lesions include apyrimidinic sites, reduced apyrimidinic sites, and base-damage analogues consisting of O-methyl- or O-benzylhydroxylamine-modified apyrimidinic sites. A 49 base pair DNA duplex containing these lesions was specifically incised by the UvrABC nuclease complex. The incision sites occurred predominantly at the eighth phosphodiester bond 5' and the fifth phosphodiester bond 3' to the lesion. Multiple incisions were observed 3' to the lesion. The extent of DNA incisions was base-damage analogues greater than reduced apyrimidinic sites greater than apyrimidinic sites. Introduction of 3' or 5' nicks at the site of a base-damage analogue by treatment of these substrates with either endonuclease III or endonuclease IV reduced, but did not abolish, subsequent incision by the UvrABC complex, whereas introduction of a 3' nick at an abasic site increased the incision efficiency of the UvrABC complex. These data demonstrate a convergence of base and nucleotide excision repair pathways in the removal of specific base damages.

Mechanism of action of Escherichia coli exonuclease III

Exonuclease III is the major apurinic/apyrimidinic (AP) endonuclease of Escherichia coli, accounting for more than 80% of the total cellular AP endonuclease activity. We have shown earlier that the endonucleolytic activity of exonuclease III is able to hydrolyze the phosphodiester bond 5' to the urea N-glycoside in a duplex DNA [Kow, Y. W., & Wallace, S. S. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 8354-8358]. Therefore, we were interested in studying the mechanism of action of the endonucleolytic activity of exonuclease III by preparing DNA containing different base lesions as well as chemically modified AP sites. When AP sites were converted to O-alkylhydroxylamine residues, exonuclease III was able to hydrolyze the phosphodiester bond 5' to O-alkylhydroxylamine residues. The apparent Km for different O-alkylhydroxylamine residues was not affected by the particular O-alkylhydroxylamine residue substituted; however, the apparent Vmax decreased as the size of the residue increased. On the basis of a study of the substrate specificity of exonuclease III, a modification of the Weiss model for the mechanism of action of exonuclease III is presented. Furthermore, a temperature study of exonucleolytic activity of exonuclease III in the presence of Mg2+ showed discontinuity in the Arrhenius plot. However, no discontinuity was observed when the reaction was performed in the presence of Ca2+. Similarly, no discontinuity was observed for the endonucleolytic activity of exonuclease III, in the presence of either Ca2+ or Mg2+. These data suggest that, in the presence of Mg2+, exonuclease III, in the presence of either Ca2+ or Mg2+.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanism of action of Escherichia coli endonuclease III

Endonuclease III isolated from Escherichia coli has been shown to have both N-glycosylase and apurinic/apyrimidinic (AP) endonuclease activities. A nicking assay was used to show that the enzyme exhibited a preference for form I DNA when DNA containing thymine glycol was used as a substrate. This preference was reduced or eliminated either when the DNA was relaxed or when the type of damage was altered to urea residues or AP sites. The combined N-glycosylase/AP endonuclease activity was at least 10-fold higher than the AP endonuclease activity alone when urea-containing DNA was used as a substrate as compared to AP DNA. When DNA containing thymine glycol was used as a substrate, the combined N-glycosylase/AP endonuclease activity was about 2-fold higher than the AP endonuclease activity. Yet, when DNA containing thymine glycol or urea was used as substrate, no apurinic sites remained. Furthermore, magnesium selectively inhibited endonuclease III activity when AP DNA was used as a substrate but had no effect when DNA containing either urea or thymine glycol was used as substrate. These data suggest that both the N-glycosylase and AP endonuclease activities of endonuclease III reside on the same molecule or are in very tight association and that these activities act in concert, with the N-glycosylase reaction preceding the AP endonuclease reaction.

Mechanism of action of Micrococcus luteus gamma-endonuclease

Micrococcus luteus extracts contain gamma-endonuclease, a Mg2+-independent endonuclease that cleaves gamma-irradiated DNA. This enzyme has been purified approximately 1000-fold, and the purified enzyme was used to study its substrate specificity and mechanism of action. gamma-Endonuclease cleaves DNA containing either thymine glycols, urea residues, or apurinic sites but not undamaged DNA or DNA containing reduced apurinic sites. The enzyme has both N-glycosylase activity that releases thymine glycol residues from OsO4-treated DNA and an associated apurinic endonuclease activity. The location and nature of the cleavage site produced has been determined with DNA sequencing techniques. gamma-Endonuclease cleaves DNA containing thymine glycols or apurinic sites immediately 3' to the damaged or missing base. Cleavage results in a 5'-phosphate terminus and a 3' baseless sugar residue. Cleavage sites can be converted to primers for DNA polymerase I by subsequent treatment with Escherichia coli exonuclease III. The mechanism of action of gamma-endonuclease and its substrate specificity are very similar to those identified for E. coli endonuclease III.

Apurinic endonucleases from Saccharomyces cerevisiae also recognize urea residues in oxidized DNA

Saccharomyces cerevisiae apurinic endonucleases E cochromatographed with activity against a DNA substrate containing urea residues. The urea-recognizing activity of endonuclease E was competitively inhibited by apurinic DNA, and the heat labilities of both activities were the same. The apparent VmaxS of endonuclease E for both substrates were about the same, while the apparent Km for urea-containing DNA was about threefold greater than that for apurinic DNA. These results were similar to those obtained previously with Escherichia coli exonuclease III (Y. Kow and S. Wallace, Proc. Natl. Acad. Sci. USA 82:8354-8358, 1985) and suggest that the ability to recognize urea residues may be a general property of apurinic endonucleases.

Exonuclease III recognizes urea residues in oxidized DNA

Escherichia coli exonuclease III was found to be associated with an activity that recognizes urea residues in DNA but not thymine glycol residues from which the urea residues were prepared. This activity was not due to a contaminating activity such as endonuclease III since urea-containing DNA was a competitive inhibitor of exonuclease III when apurinic DNA was used as a substrate and vice versa. The apparent kinetic constants for both the substrate and inhibitor were determined. Like its apurinic activity, exonuclease III activity against urea residues was endonucleolytic, nicking on the 5' side of the damage and having an optimal Mg2+ concentration between 2 and 10 mM. Also, the enzyme recognized alkali-stable damages produced in DNA by H2O2 in vitro. We suggest that it may be this activity of exonuclease III that accounts for its biological role in vivo.

Thymine glycols and urea residues in M13 DNA constitute replicative blocks in vitro

Thymine glycols were produced in M13 DNA in a concentration dependent manner by treating the DNA with osmium tetroxide (OsO4). For the formation of urea-containing M13 DNA, OsO4-oxidized DNA was hydrolyzed in alkali (pH 12) to convert the thymine glycols to urea residues. With both thymine glycol- and urea-containing M13 DNA, DNA synthesis catalyzed by Escherichia coli DNA polymerase I Klenow fragment was decreased in proportion to the number of damages present in the template DNA. Sequencing gel analysis of the products synthesized by E. coli DNA polymerase I and T4 DNA polymerase showed that DNA synthesis terminated opposite the putative thymine glycol site and at one nucleotide before the putative urea site. Substitution of manganese for magnesium in the reaction mix resulted in increased processivity of DNA synthesis so that a base was incorporated opposite urea. With thymine glycol-containing DNA, processivity in the presence of manganese was strongly dependent on the presence of a pyrimidine 5' to the thymine glycol in the template.

Ubiquinone in hydrogen metabolism by Azotobacter vinelandii

Extraction with n-heptane abolished over 95% of the NADH oxidase and the hydrogenase activity in membrane preparations from Azotobacter vinelandii. Incorporation of ubiquinone-8 or plastoquinone restored each reaction to about 55% of its original activity.

Purification and properties of membrane-bound hydrogenase from Azotobacter vinelandii

Uptake hydrogenase (EC 1.12) from Azotobacter vinelandii has been purified 250-fold from membrane preparations. Purification involved selective solubilization of the enzyme from the membranes, followed by successive chromatography on DEAE-cellulose, Sephadex G-100, and hydroxylapatite. Freshly isolated hydrogenase showed a specific activity of 110 mumol of H2 uptake (min X mg of protein)-1. The purified hydrogenase still contained two minor contaminants that ran near the front on sodium dodecyl sulfate-polyacrylamide gels. The enzyme appears to be a monomer of molecular weight near 60,000 +/- 3,000. The pI of the protein is 5.8 +/- 0.2. With methylene blue or ferricyanide as the electron acceptor (dyes such as methyl or benzyl viologen with negative midpoint potentials did not function), the enzyme had pH optima at pH 9.0 or 6.0, respectively, It has a temperature optimum at 65 to 70 degrees C, and the measured half-life for irreversible inactivation at 22 degrees C by 20% O2 was 20 min. The enzyme oxidizes H2 in the presence of an electron acceptor and also catalyzes the evolution of H2 from reduced methyl viologen; at the optimal pH of 3.5, 3.4 mumol of H2 was evolved (min X mg of protein)-1. The uptake hydrogenase catalyzes a slow deuterium-water exchange in the absence of an electron acceptor, and the highest rate was observed at pH 6.0. The Km values varied widely for different electron acceptors, whereas the Km for H2 remained virtually constant near 1 to 2 microM, independent of the electron acceptors.

Oxidation of NAD(P)H in a Reconstituted Spinach Chloroplast Preparation Using Ascorbate and Hydrogen Peroxide

The conversion of fructose-1,6-bisphosphate to glycerate-3-phosphate (PGA) was studied in a reconstituted spinach (Spinacia oleracea L.) chloroplast preparation to determine whether a chloroplast-localized NAB(P)H-oxidizing system (Kow, Smyth, Gibbs 1982 Plant Physiol 69: 72-76 with substrates of ascorbate, NAD(P)H, and H(2)O(2) could serve as a coupling enzyme in the recycling of NAD(P)H. The rate of PGA formation was monitored as an indicator of NAD(P) generation. With NAD as a cofactor, ascorbate enhanced PGA formation, and an additional increase resulted upon addition of glucose-glucose oxidase, a H(2)O(2)-generating enzyme. This increase in PGA formation due to H(2)O(2) was eliminated by the addition of catalase. With NADP and ferredoxin as cofactors, the recycling of NADP apparently was catalyzed both by ferredoxin-NADP reductase coupled to O(2) and by the NAD(P)H-oxidizing system.It was concluded that the oxidation of NAD(P)H by a system using ascorbate and H(2)O(2) can serve as a means of recycling NAD(P)H but that another reaction involving ascorbate and NAD(P)H may also function in the spinach chloroplast.

Chloroplast Respiration : A MEANS OF SUPPLYING OXIDIZED PYRIDINE NUCLEOTIDE FOR DARK CHLOROPLASTIC METABOLISM

A spinach (Spinacia oleracia var. America) chloroplast particle fortified with ferredoxin, fructose-1,6-bisphosphate, or ribose-5-phosphate and NADP has been shown to generate NADPH by the oxidation of glyceraldehyde-3 phosphate to glycerate-3-phosphate (PGA) and to reduce ferredoxin with the NADPH. The resulting reduced ferredoxin can reduce O(2) to H(2)O(2), nitrite to ammonia, or protons to H(2). Hydrogen production was the result of adding hydrogenase from Chlamydomonas reinhardii to the chloroplast preparation. The predicted stoichiometry of 1 PGA:1 O(2) in the absence of and 2 PGA:1 O(2) in the presence of catalase was observed indicating H(2)O(2) as the end product of O(2) reduction. The predicted stoichiometry of 3 PGA:1 nitrite:1 ammonia was also observed. A scheme is presented to account for a sustained generation of NADP and ATP necessary for the dissimilation of starch in the darkened chloroplast. The unifying term chloroplast respiration is introduced to account for those reactions in which reduced ferredoxin interacts with physiological acceptors other than NADP or nitrite, hydrogen, or O(2) respiration when nitrite, protons, or O(2) is the ultimate electron acceptor.

Characterization of a Photosynthesizing Reconstituted Spinach Chloroplast Preparation : REGULATION BY PRIMER, ADENYLATES, FERREDOXIN, AND PYRIDINE NUCLEOTIDES

A particulate preparation (MgP) capable of photosynthetic CO(2) assimilation without the addition of stromal protein was obtained by rupturing whole spinach (Spinacia oleracea var. America) chloroplasts in 15 millimolar MgCl(2) buffered with Tricine at pH 8.5. This CO(2) assimilation was dependent upon light, inorganic phosphate, ferredoxin, ADP, NAD or NADP, and primer. Excepting glycolate, the products of CO(2) fixation by MgP were similar to those found with whole chloroplasts.Glycerate-3-phosphate (PGA), fructose-1, 6-bisphosphate (FBP), and ribose-5-phosphate (R5P) but not fructose-6-P (F6P) functioned as primers. Concentrations of PGA and FBP but not of R5P higher than 2 millimolar were inhibitory to CO(2) fixation. A lag of CO(2) fixation was observed with PGA and FBP but not with R5P. This lag as well as inhibition by NADP, ADP, and ATP in the FBP-primed preparation was eliminated by an equimolar mixture of FBP plus F6P indicating FBPase as the sensitive site. NADP, ADP, and ATP also blocked CO(2) fixation by the PGA-fortified preparation but inhibition was even more sensitive than that observed when FBP was added. Inhibition by AMP in the PGA and FBP-primed preparations was not affected by the addition of F6P. When R5P was the starting primer, inhibition of CO(2) fixation was relatively insensitive to the adenylates and NADP. In contrast to the parent whole chloroplast, CO(2) fixation by MgP was insensitive to high (5 millimolar) inorganic phosphate. Depending upon the ferredoxin concentration, NAD was as effective as NADP in supporting CO(2) fixation.

Oxidation of reduced pyridine nucleotide by a system using ascorbate and hydrogen peroxide from plants and algae

A NAD(P)H oxidizing system (NAAP) was detected and partially purified from leaves of spinach and Sedum praealtum, seeds and leaves of pea and cells of green and red algae which oxidized NAD(P)H in the presence of ascorbate and H(2)O(2).The partially-purified spinach system had substrate K(m) values of 5 micromolar for NADH, 50 micromolar for H(2)O(2), and 300 micromolar for l-ascorbic acid at the pH optimum of 6.8. NADH was a better electron donor than NADPH. Among other electron donors, isoascorbic acid had considerable activity but hydroquinone and resorcinol had only weak activities. The enzyme was inhibited by cyanide, alpha,alpha'-dipyridyl, and mono-and di-thiol reagents. Inhibition by thiol-reagents was partially restored by Fe(2+) as was enzymic activity lost following dialysis against buffer.Subcellular localization studies with spinach and S. praealtum leaves indicated that a portion of the cell's NAAP was in the chloroplast fraction. Photosynthetic conditions resulted in a decrease in this activity solubilized from spinach and S. praealtum chloroplasts. The presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea or Fe(2+) in the incubation medium eliminated the light-mediated inhibition of NAAP.NAAP may function in the recycling of NAD(P)H generated in the dark within the chloroplast. Inasmuch as all preparations of NAAP contained ascorbate peroxidase activity, the data do not rule out the possibility that NAAP is the same protein as ascorbate peroxidase or, alternatively, a combination of ascorbate peroxidase and some other enzyme.

Influence of pH upon the Warburg Effect in Isolated Intact Spinach Chloroplasts: II. Interdependency of Glycolate Synthesis upon pH and Calvin Cycle Intermediate Concentration in the Absence of Carbon Dioxide Photoassimilation

The light-dependent synthesis of glycolate derived from fructose 1,6-diphosphate, ribose 5-phosphate, or glycerate 3-phosphate was studied in the intact spinach (Spinacia oleracea) chloroplasts in the absence of CO(2). Glycolate yield increased with an elevation of O(2), pH, and the concentration of the phosphorylated compound supplied. No pH optimum was observed as the pH was increased from 7.4 to 8.5. The average maximal rate of glycolate synthesis was 50 mumoles per milligram chlorophyll per hour while the highest rate observed was 92 with 2.5 mm fructose 1,6-diphosphate in 100% O(2). The highest yields of glycolate synthesized from fructose 1,6-diphosphate, ribose 5-phosphate, or glycerate 3-phosphate were 0.14, 0.24, and 0.30, respectively, on a molar basis.