Gene cloning and biochemical characterizations of thermostable ribonuclease HIII from Bacillus stearothermophilus

The gene encoding RNase HIII from the thermophilic bacterium Bacillus stearothermophilus was cloned and overexpressed in Escherichia coli, and the recombinant protein (Bst-RNase HIII) was purified and biochemically characterized. Bst-RNase HIII is a monomeric protein with 310 amino acid residues, and shows an amino acid sequence identity of 47.1% with B. subtilis RNase HIII (Bsu-RNase HIII). The enzymatic properties of Bst-RNase HIII, such as pH optimum, metal ion requirement, and cleavage mode of the substrates, were similar to those of Bsu-RNase HIII. However, Bst-RNase HIII was more stable than Bsu-RNase HIII, and the temperature (T(1/2)) at which the enzyme loses half of its activity upon incubation for 10 min was 55 degrees C for Bst-RNase HIII and 35 degrees C for Bsu-RNase HIII. The optimum temperature for Bst-RNase HIII activity was also shifted upward by roughly 20 degrees C as compared to that of Bsu-RNase HIII. The availability of such a thermostable enzyme will facilitate structural studies of RNase HIII.     

The solubilization and biological activities of Aspergillus beta-(1 --> 3)-D-glucan

We have recently demonstrated that the cell wall beta-glucan of Candida albicans could be solubilized by sodium hypochlorite, followed by dimethylsulfoxide-extraction (NaClO-DMSO method). In this study, applying this method to Aspergillus spp., we prepared mycelial cell wall beta-glucan and examined its physical properties and immunotoxicological activity. The acetone-dried mycelia of Aspergillus spp. were oxidized by the NaClO-DMSO method. An analysis of (13)C NMR spectra revealed the preparations to be composed of alpha-(1 --> 3) and beta-(1 --> 3)-D-glucan. Also, the proportion of alpha-(1 --> 3) and beta-(1 --> 3)-D-glucan varied. Furthermore, a solubilized Aspergillus beta-glucan (ASBG) was prepared from OX-Asp by urea-autoclave treatment. ASBG showed limulus activity similar to Candida solubilized beta-glucan (CSBG), and there was little difference in the activity of ASBG between various Aspergillus spp. ASBG affected the production of IL-8 by human peripheral blood mononuclear cells (PBMC). ASBG should be useful for analyzing the clinical role of beta-glucan.     

High-efficiency bypass of DNA damage by human DNA polymerase Q

Endogenous DNA damage arises frequently, particularly apurinic (AP) sites. These must be dealt with by cells in order to avoid genotoxic effects. DNA polymerase theta; is a newly identified enzyme encoded by the human POLQ gene. We find that POLQ has an exceptional ability to bypass an AP site, inserting A with 22% of the efficiency of a normal template, and continuing extension as avidly as with a normally paired base. POLQ preferentially incorporates A opposite an AP site and strongly disfavors C. On nondamaged templates, POLQ makes frequent errors, incorporating G or T opposite T about 1% of the time. This very low fidelity distinguishes POLQ from other A-family polymerases. POLQ has three sequence insertions between conserved motifs in its catalytic site. One insert of approximately 22 residues into the tip of the polymerase thumb subdomain is predicted to confer considerable flexibility and additional DNA contacts to affect enzyme fidelity. POLQ is the only known enzyme that efficiently carries out both the insertion and extension steps for bypass of AP sites, commonly formed as endogenous genomic lesions.     

Effect of irradiance on the partitioning of assimilated carbon during the early phase of grain filling in rice

Low irradiance in the early phase of grain filling in rice often results in a low grain yield, but its effects on the partitioning of previously or recently assimilated carbon within the plant or panicle have not been seriously examined. The objective of this study was to demonstrate the effect of shading during the different stages in the early phase of grain filling on the partitioning of previously or recently assimilated carbon among constituent organs and into superior and inferior spikelets of the panicle in rice (Oryza sativa L. 'Sasanishiki') plants using 13C as a tracer. Plants were grown either under low (shading) or moderate (non-shading) irradiance (120 and 800 micromol quantum m(-2) s(-1)) for 3 or 4 d before or after the 13CO2 feeding at heading, full-heading or milky stages during the early phase of grain filling. Four days after the 13CO2 feeding, the proportion of labelled (previously assimilated) carbon partitioned into the panicle was 17% higher in plants grown under low irradiance compared with plants grown under moderate irradiance at the full-heading stage (7-11 d after heading), while the proportion partitioned into the culm was 13% lower. The light treatments for 3 d were conducted before the 13CO2 feeding and partitioning of the labelled (recently-assimilated) carbon into spikelets was examined 6 h after feeding. The amount of labelled carbon partitioned into the spikelets of the secondary branch (inferior grains) in the plants grown under low irradiance was only 31% when compared with plants grown under moderate irradiance at the full-heading stage, although the partitioning of labelled carbon into the apical spikelets of the primary branch (superior grains) was not affected by the light treatments. These results clearly indicate that preferential partitioning of assimilated carbon into the panicle occurs under low irradiance at around 7-11 d after heading and that the priority of superior spikelets for assimilated carbon intensifies. This phenomenon is thought to be an important strategy for such rice cultivars as used in this study to achieve a certain proportion of ripened grains even under light limited conditions.     

An oxidized purine nucleoside triphosphatase,MTH1, suppresses cell death caused by oxidative stress

MTH1 hydrolyzes oxidized purine nucleoside triphosphates such as 8-oxo-2'-deoxyguanosine 5'-triphosphate (8-oxo-dGTP) and 2-hydroxy-2'-deoxyadenosine 5'-triphosphate (2-OH-dATP) and thus protects cells from damage caused by their misincorporation into DNA. In the present study, we established MTH1-null mouse embryo fibroblasts that were highly susceptible to cell dysfunction and death caused by exposure to H2O2, with morphological features of pyknosis and electron-dense deposits accumulated in mitochondria. The cell death observed was independent of both poly(ADP-ribose) polymerase and caspases. A high performance liquid chromatography tandem mass spectrometry analysis and immunofluorescence microscopy revealed a continuous accumulation of 8-oxo-guanine both in nuclear and mitochondrial DNA after exposure to H2O2. All of the H2O2-induced alterations observed in MTH1-null mouse embryo fibroblasts were effectively suppressed by the expression of wild type human MTH1 (hMTH1), whereas they were only partially suppressed by the expression of mutant hMTH1 defective in either 8-oxo-dGTPase or 2-OH-dATPase activity. Human MTH1 thus protects cells from H2O2-induced cell dysfunction and death by hydrolyzing oxidized purine nucleotides including 8-oxo-dGTP and 2-OH-dATP, and these alterations may be partly attributed to a mitochondrial dysfunction.     

Identification and characterization of an intermediate in the alkali degradation of (6-4) photoproduct-containing DNA

The (6-4) photoproduct formed by ultraviolet light is known as an alkali-labile DNA lesion. Strand breaks occur at (6-4) photoproducts when UV-irradiated DNA is treated with hot alkali. We have analyzed the degradation reaction of this photoproduct under alkaline conditions using synthetic oligonucleotides. A tetramer, d(GT(6-4)TC), was prepared, and its degradation in 50 mm KOH at 60 degrees C was monitored by high performance liquid chromatography. A single peak with a UV absorption spectrum similar to that of the starting material was detected after the reaction, and this compound was regarded as an intermediate before the strand break. The formation of this intermediate was compared with intermediates from the degradation of other alkali-labile lesions such as the abasic site, thymine glycol, and 5,6-dihydrothymine. The results strongly suggested that the first step of the alkali degradation of the (6-4) photoproduct was the hydrolysis between the N3 and C4 positions of the 5'-pyrimidine component. Analyses by NMR spectroscopy and mass spectrometry supported the chemical structure of this product. Assays of the complex formation with XPC.HR23B and the translesion synthesis by DNA polymerase eta revealed that the biochemical properties are indistinguishable between the intact and hydrolyzed photoproducts.     

Molecular basis of enzyme inactivation by an endogenous electrophile 4-hydroxy-2-nonenal: identification of modification sites in glyceraldehyde-3-phosphate dehydrogenase

4-Hydroxy-2-nonenal (HNE), a major lipid peroxidation-derived reactive aldehyde, is a potent inhibitor of sulfhydryl enzymes, such as the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH). It has been suggested that HNE exerts an inhibitory effect on the enzyme due to the modification of the cysteine residue (Cys-149) at the catalytic site generating the HNE-cysteine Michael addition-type adduct [Uchida, K., and Stadtman, E. R. (1993) J. Biol. Chem. 268, 6388-6393]. In the study presented here, to elucidate the mechanism for the inactivation of GAPDH by HNE, we attempted to identify the modification sites of the enzyme by monitoring the formation of the HNE Michael adducts by mass spectrometric methods. Incubation of GAPDH (1 mg/mL) with 1 mM HNE in 50 mM sodium phosphate buffer (pH 7.4) at 37 degrees C resulted in a time-dependent loss of enzyme activity, which was associated with the covalent binding of HNE to the enzyme. To identify the site of modification of GAPDH by HNE, both the HNE-pretreated and untreated GAPDH were digested with trypsin and V8 protease, and the resulting peptides were subjected to electrospray ionization liquid chromatography-mass spectrometry (ESI-LC-MS). This technique identified five peptides, which contained the HNE adducts at His-164, Cys-244, Cys-281, His-327, and Lys-331 and revealed that both His-164 and Cys-281 were very rapidly modified at 5 min, followed by Cys-244 at 15 min and His-327 and Lys-331 at 30 min. These observations and the observation that the HNE modification of the catalytic center, Cys-149, was not observed suggest that the HNE inactivation of GAPDH is not due to the modification of the catalytic center but to the selective modification of amino acids primarily located in the surface of the GAPDH molecule.     

Role of tryptophan residues in the recognition of mutagenic oxidized nucleotides by human antimutator MTH1 protein

The human MTH1 antimutator protein hydrolyzes mutagenic oxidized nucleotides, and thus prevents their incorporation into DNA and any subsequent mutation. We have examined its great selectivity for oxidized nucleotides by analyzing the structure of the protein and its interaction with nucleotides, as reflected in the fluorescence of its tryptophan residues. The binding of nucleotides decreased the intensity of MTH1 protein fluorescence and red-shifted the emission peak, indicating that at least one tryptophan residue is close to the binding site. Oxidized nucleotides (2-OH-dATP and 8-oxo-dGTP) produced a larger decrease in fluorescence intensity than did unoxidized nucleotides, and MTH1 protein had a much higher binding affinity for oxidized nucleotides. Deconvolution of protein fluorescence by comparison of its quenching by positively (Cs(+)) and negatively (I(-)) charged ions indicated that the MTH1 tryptophan residues are in two different environments. One class of tryptophan residues is exposed to solvent but in a negatively charged environment; the other class is partially buried. While the binding of unoxidized nucleotides quenches the fluorescence of only class 1 tryptophan residue(s), the binding of oxidized nucleotides quenched that of class 2 tryptophan residue(s) as well. This suggests that selectivity is due to additional contact between the protein and the oxidized nucleotide. Mutation analysis indicated that the tryptophan residue at position 117, which is in a negative environment, is in contact with nucleotides. The negatively charged residues in the binding site probably correlate with the finding that nucleotide binding requires metal ions and depends upon their nature. Positively charged metal ions probably act by neutralizing the negatively charged nucleotide phosphate groups. (c) 2002 Elsevier Science Ltd.     

Proteases involved in long-term potentiation

Much attention has been paid to proteases involved in long-term potentiation (LTP). Calpains, Ca-dependent cysteine proteases, have first been demonstrated to be the mediator of LTP by the proteolytic cleavage of fodrin, which allows glutamate receptors located deep in the postsynaptic membrane to move to the surface. It is now generally considered that calpain activation is necessary for LTP formation in the cleavage of substrates such as protein kinase Czeta, NMDA receptors, and the glutamate receptor-interacting protein. Recent studies have shown that serine proteases such as tissue-type plasminogen activator (tPA), thrombin, and neuropsin are involved in LTP. tPA contributes to LTP by both receptor-mediated activation of cAMP-dependent protein kinase and the cleavage of NMDA receptors. Thrombin induces a proteolytic activation of PAR-1, resulting in activation of protein kinase C, which reduces the voltage-dependent Mg2+ blockade of NMDA receptor-channels. On the other hand, neuropsin may act as a regulatory molecule in LTP via its proteolytic degradation of extracellular matrix protein such as fibronectin. In addition to such neuronal proteases, proteases secreted from microglia such as tPA may also contribute to LTP. The enzymatic activity of each protease is strictly regulated by endogenous inhibitors and other factors in the brain. Once activated, proteases can irreversibly cleave peptide bonds. After cleavage, some substrates are inactivated and others are activated to gain new functions. Therefore, the issue to identify substrates for each protease is very important to understand the molecular basis of LTP.