Kinetic studies of Escherichia coli AlkB using a new fluorescence-based assay for DNA demethylation.

The Escherichia coli AlkB protein catalyzes the direct reversal of alkylation damage to DNA; primarily 1-methyladenine (1mA) and 3-methylcytosine (3mC) lesions created by endogenous or environmental alkylating agents. AlkB is a member of the non-heme iron (II) alpha-ketoglutarate-dependent dioxygenase superfamily, which removes the alkyl group through oxidation eliminating a methyl group as formaldehyde. We have developed a fluorescence-based assay for the dealkylation activity of this family of enzymes. It uses formaldehyde dehydrogenase to convert formaldehyde to formic acid and monitors the creation of an NADH analog using fluorescence. This assay is a great improvement over the existing assays for DNA demethylation in that it is continuous, rapid and does not require radioactively labeled material. It may also be used to study other demethylation reactions including demethylation of histones. We used it to determine the kinetic constants for AlkB and found them to be somewhat different than previously reported values. The results show that AlkB demethylates 1mA and 3mC with comparable efficiencies and has only a modest preference for a single-stranded DNA substrate over its double-stranded DNA counterpart.

Delayed DNA joining at 3' mismatches by human DNA ligases.

Repair synthesis catalysed by DNA polymerase beta at 1 nt gaps occurs in the main pathway of mammalian base excision repair. DNA polymerase beta has no exonucleolytic proof-reading ability, and exhibits high error frequency during DNA synthesis. Consequently, continuous correction of endogenous DNA damage by short-patch repair synthesis might lead to a high spontaneous mutation rate, unless subsequent steps in the repair pathway allow for selective removal of incorporation errors. We show here that both human DNA ligase I and III discriminate strongly between a correctly paired versus a mispaired residue at the 3' position of a nick in DNA, when assayed in the presence of physiological concentrations of KCl. The resulting delay in joining after misincorporation by DNA polymerase beta during gap filling could allow for removal of the mismatched terminal residue by a distinct 3' exonuclease.

Mutations induced by bacteriophage T7 RNA polymerase and their effects on the composition of the T7 genome.

We show here that transcription by the bacteriophage T7 RNA polymerase increases the deamination of cytosine bases in the non-transcribed strand to uracil, causing C to T mutations in that strand. Under optimal conditions, the mutation frequency increases about fivefold over background, and is similar to that seen with the Escherichia coli RNA polymerase. Further, we found that a mutant T7 RNA polymerase with a slower rate of elongation caused more cytosine deaminations than its wild-type parent. These results suggest that promoting cytosine deamination in the non-transcribed strand is a general property of transcription in E. coli and is dependent on the length of time the transcription bubble stays open during elongation. To see if transcription-induced mutations have influenced the evolution of bacteriophage T7, we analyzed its genome for a bias in base composition. Our analysis showed a significant excess of thymine over cytosine bases in the highly transcribed regions of the genome. Moreover, the average value of this bias correlated well with the levels of transcription of different genomic regions. Our results indicate that transcription-induced mutations have altered the composition of bacteriophage T7 genome and suggest that this may be a significant force in genome evolution.

A novel repetitive sequence lies near the gene encoding a cytosine methyltransferase in the cyanobacterium Dactylococcopsis salina.

An unusual cluster of tandemly repeated DNA sequences (TRS) was found downstream from the gene encoding DsaV methyltransferase, the DNA modification enzyme in the DsaV restriction-modification system found in a strain of Dactylococcopsis salina (Ds). The repeat unit is about 32-bp long and is present 13 times in the cluster. Each repeat unit can be divided into two distinct parts based on the level of sequence conservation and evolution. Hybridization of Ds DNA with a probe specific for this cluster revealed that there were at least two additional sites within the genome with similar TRS. The TRS units are localized in one region of the Ds genome. They do not share significant sequence similarity with other TRS found in prokaryotes.

Sequence motifs specific for cytosine methyltransferases.

Using a new alignment method, the sequences of 13 m5C methyltransferases (MTases) have been examined. Five extremely well-conserved blocks of sequence have been detected and have been used as fixed points for the alignment of the 13 sequences. Following this initial alignment, five further blocks of similarity have been identified to give a total of ten recognizable blocks of sequence homology that are all arranged in a common order. The structures of these MTases consist of a variable-length N-terminal arm followed by eight well-conserved blocks each separated by small variable-length regions. A large variable-length segment of 90 to 270 amino acids (aa) then follows. After this are two blocks, and a variable-length C-terminal segment completes the sequence. Within the final alignment, 20 aa in the protein sequences, and 86 nucleotides in the nucleotide sequences are invariant. The strongest conservation is found in proximity to a suspected functional site that contains the dipeptide proline-cysteine. Consensus patterns can be defined for the five best conserved blocks and, when used as search motifs, are able to clearly distinguish between the m5C MTases and all other identified proteins in the PIR database. This suggests they may be of use in identifying putative MTases among protein sequences of unknown function.

Cloning and characterization of the gene encoding the DsaV methyltransferase.

A gene encoding the M.DsaV methyltransferase was cloned and characterized. The enzyme methylates the internal cytosines in the 5'-CCTGG recognition sequence, as determined by a novel rapid method employing 3H label and exonuclease III.

Activation-dependent changes in microenvironment of spinach ribulose 1,5-bisphosphate carboxylase/oxygenase.

The spinach ribulose 1,5-bisphosphate carboxylase/oxygenase was labelled with o-phthalaldehyde, which forms a stable fluorescent isoindole adduct at the active site. The fluorescence behaviour of the labelled enzyme after activation to different levels by Mg2+ was compared with that of a synthetic isoindole adduct of o-phthalaldehyde, namely 1-(hydroxyethylthio)-2-beta hydroxyethylisoindole in solvents of different pH and polarity. The results suggest that the microenvironment at the catalytically incompetent active site of the unactivated Rubisco is highly acidic (pH less than 2) in nature. The activation by Mg2+ results in the conformational change such that the effective pH at the active site increases to greater than 8. The polarity of the active site of the activated enzyme was found to be similar to that of a mixture of hexane and toluene.

Principal causes of hot spots for cytosine to thymine mutations at sites of cytosine methylation in growing cells. A model, its experimental support and implications.

In Escherichia coli and human cells, many sites of cytosine methylation in DNA are hot spots for C to T mutations. It is generally believed that T.G mismatches created by the hydrolytic deamination of 5-methylcytosines (5meC) are intermediates in the mutagenic pathway. A number of hypotheses have been proposed regarding the source of the mispaired thymine and how the cells deal with the mispairs. We have constructed a genetic reversion assay that utilizes a gene on a mini-F to compare the frequency of occurrence of C to T mutations in different genetic backgrounds in exponentially growing E. coli. The results identify at least two causes for the hot spot at a 5meC: (1) the higher rate of deamination of 5meC compared to C generates more T.G than uracil.G (U.G) mismatches, and (2) inefficient repair of T.G mismatches by the very short-patch (VSP) repair system compared to the repair of U. G mismatches by the uracil-DNA glycosylase (Ung). This combination of increased DNA damage when the cytosines are methylated coupled with the relative inefficiency in the post-replicative repair of T.G mismatches can be quantitatively modeled to explain the occurrence of the hot spot at 5meC. This model has implications for mutational hot and cold spots in all organisms.

Ho: Yag laser-assisted lumbar disc decompression: a minimally invasive procedure under local anesthesia.

The morbidity associated with open procedures for lumbar intervertebral disc prolapse has led to the development of minimally invasive techniques. Ho: LADD (Laser-assisted disc decompression) is a very cost-effective minimally invasive procedure. The procedure is carried out under local anesthesia. The patient can be mobilized immediately after the surgery. The study involved 36 cases treated with Ho: LADD for contained lumbar intervertebral disc prolapse. 35 cases were available for follow-up. There was a 91.5% success rate and a minimal complication rate. All cases adhered to strict inclusion and exclusion criteria and were evaluated with the modified Macnab criteria for the assessment of postoperative results.

o-Phthalaldehyde as a probe in the active site of phosphoenolpyruvate carboxylase.

Modification of phosphoenolpyruvate carboxylase with o-phthalaldehyde (OPA) resulted in rapid and irreversible inactivation exhibiting biphasic reaction kinetics. The kinetic analysis and correlation of spectral changes with activity indicated that inactivation by OPA results from the modification of two lysine and two cysteine residues per subunit of the enzyme. PEP plus Mg2+ offered substantial protection against modification. Some of the effectors also gave appreciable protection against modification indicating that the residues may be located at or close to the active site. Thus, the results indicate formation of two isoindoles showing the proximity of the essential lysine and cysteine residues at the active site.

Essential tryptophan residues of ribulose 1,5-bisphosphate carboxylase.

Ribulose 1,5-bisphosphate carboxylase [3-phospho-D-glyceratecarboxy-lyase (dimerizing), EC 4.1.1.39] is rapidly and irreversibly inactivated by micromolar concentrations of dimethyl (2-hydroxy-5-nitrobenzyl) sulphonium bromide (DMHNB), a tryptophan selective reagent, after reversible protection of the reactive sulphydryl groups. The inactivation followed pseudo-first-order reaction kinetics. Replots of the kinetic data indicated that no reversible enzyme-inhibitor complex was formed prior to irreversible modification. Kinetic analysis and the correlation of the spectral data at 410 nm with enzyme activity indicated that inactivation by DMHNB resulted from modification of on an average one tryptophan per 67 kDa combination of large and small subunits. Several competitive inhibitors and substrate RuBP offered strong protection against inhibition. The k1/2 (protection) for RuBP was 1.3 mM, indicating that the tryptophan residues may be located at or near the substrate binding site. Free and total sulphydryl groups were not affected by the reagent. The modified enzyme exhibited significantly reduced intrinsic fluorescence, indicating that the microenvironment of the tryptophans at the active site is significantly perturbed. Tryptic peptide profiles and CD spectral analyses suggested that inactivation may not be due to the extensive conformational changes in the enzyme molecule during modification.

Limited proteolysis by trypsin influences activity of maize phosphoenolpyruvate carboxylase.

Maize phosphoenolpyruvate carboxylase (PEPC) was rapidly and completely inactivated by very low concentrations of trypsin at 37 degrees C. PEP+Mg2+ and several other effectors of PEP carboxylase offered substantial protection against trypsin inactivation. Inactivation resulted from a fairly specific cleavage of 20 kDa peptide from the enzyme subunit. Limited proteolysis under catalytic condition (in presence of PEP, Mg2+ and HCO3) although yielded a truncated subunit of 90 kDa, did not affect the catalytic function appreciably but desensitized the enzyme to the effectors like glucose-6-phosphate glycine and malate. However, under non-catalytic condition, only malate sensitivity was appreciably affected. Significant protection of the enzyme activity against trypsin during catalytic phase could be either due to a conformational change induced on substrate binding. Several lines of evidence indicate that the inactivation caused by a cleavage at a highly conserved C-terminal end of the subunit.

Limited proteolysis of maize NADP-malic enzyme.

The incubation of maize malic enzyme at 37 degrees C with trypsin at a ratio of 150:1 of malic enzyme to trypsin caused rapid and complete inactivation of enzyme activity. The inactivation was caused by fairly specific cleavage of the enzyme monomer (62 kDa) into 40 kDa and 20 kDa fragments. The intensity of 40 kDa band increased with the time of treatment of enzyme with trypsin from 2 to 30 min. Substrates, especially NADP (25 microM) provided almost total protection against trypsin inactivation of the enzyme activity. The studies carried out with various other endoproteases indicated that endoprotease Lys-C was most effective in inactivating malic enzyme activity. The kinetic properties of the truncated enzyme have been studied. The Km value for malate in case of native and modified enzyme was found to be identical. Km NADP for the modified enzyme was slightly higher indicating that after proteolysis the enzyme affinity for NADP had decreased. Limited proteolysis with trypsin did not show any appreciable change in fluorescence properties of the modified enzyme. Binding of NADPH to the enzyme was not affected after modification.

Inactivation of maize NADP-malic enzyme by Cu2+-ascorbate.

Maize malic enzyme was rapidly inactivated by micromolar concentrations of cupric nitrate in the presence of ascorbate at pH, 5.0. Ascorbate or Cu2+ alone had no effect on enzyme activity. The substrate L-malate or NADP individually provided almost total protection against Cu2+-ascorbate inactivation. The loss of enzyme activity was accompanied by cleavage of the enzyme. The cleaved peptides showed molecular mass of 55 kDa, 48 kDa, 38 kDa, and 14 kDa. Addition of EDTA, histidine and imidazole provided protection. The results of protection experiments with sodium azide, DABCO and catalase suggested that reactive oxygen species were generated resulting in loss of enzyme activity. This was further supported by experiments showing that the rate of enzyme inactivation was higher in D2O than in water. It is suggested that maize malic enzyme is modified by reactive oxygen species like singlet oxygen and H2O2 generated by Cu2+-ascorbate system and the modified amino acid residue(s) may be located at or near the substrate-binding site of the enzyme.

Modification of maize NADP-malic enzyme by Woodward's reagent 'K'.

Maize leaf NADP-malic enzyme was rapidly inactivated by micromolar concentrations of Woodward's reagent K (WRK). The inactivation followed pseudo-first order reaction kinetics. The order of reaction with respect to WRK was 1, suggesting that inactivation was a consequence of the modification of a single residue per active site. The modified enzyme showed a characteristic absorbance at 346 nm due to carboxyl group modification and also exhibited altered surface charge as seen from the elution profile on "Mono Q" anion exchange column and the mobility on native polyacrylamide gel electrophoresis. Substrate NADP and NADP + Mg2+ strongly protected the enzyme against WRK inactivation indicating that the modified residue may be located at or near the active site. Binding affinity of NADPH to the malic enzyme was studied by the fluorescence technique. The native enzyme binds NADPH strongly resulting in enhancement of the fluorescence emission and also causes a blue shift in the emission maximum of NADPH from 465 nm to 450 nm, however, the modified enzyme neither exhibited the enhancement of fluorescence emission nor the blue shift, indicating loss of NADPH binding site on modification. The essential carboxyl group may be involved in NADPH binding during catalysis by the enzyme.