Appearance of new lipoxygenases in soybean cotyledons after germination and evidence for expression of a major new lipoxygenase gene

The appearance and subsequent disappearance of lipoxygenase activity at pH 6.8 in germinated cotyledons of soybean (Glycine max [L.]) was shown using a variant soybean cultivar (Kanto 101) that lacks the two lipoxygenase isozymes, L-2 and L-3, that are present in dry seeds of a normal soybean cultivar (Enrei). Three new lipoxygenases, designated lipoxygenase L-4, L-5, and L-6, were purified using anionic or cationic ion exchange chromatography. The major lipoxygenase in 5-day-old cotyledons of the variant soybean was lipoxygenase L-4. Lipoxygenases L-5 and L-6 preferentially produced 13(S)-hydroperoxy-9(Z), 11(E)-octadecadienoic acid (13S-HPOD) as a reaction product of linoleic acid, whereas lipoxygenase L-4 produced both 13S-HPOD and 9(S)-hydroperoxy-10(E), 12(Z)-octadecadienoic acid. All three isozymes have pH optima of 6.5, no activity at pH 9.0, and preferred linolenic acid to linoleic acid as a substrate. Partial amino acid sequencing of lipoxygenase L-4 showed that this isozyme shares amino acid sequence homology with lipoxygenases L-1, L-2, and L-3 but is not identical to any of them. This indicates that a new lipoxygenase, L-4, is expressed in cotyledons.     

cDNA sequence and expression of a phosphoenolpyruvate carboxylase gene from soybean

A full-length cDNA encoding a subunit of phosphoenolpyruvate carboxylase (PEPC) was isolated from a developing seed expression library of the C₃ plant Glycine max. The corresponding mRNA is present at similar levels in leaf, stem, root and developing seed. Two potential start codons exist, and the activity of protein initiated from the first such codon could be subject to regulation by protein kinase. Sequence comparison shows a similar upstream start codon in the case of the Ppc2 gene from Mesembryanthemum crystallinum, previously assumed to lack the sequences necessary for phosphorylation. The soybean encoded protein tends to resemble other C₃-type PEPC proteins more closely than those implicated in C₄ or crassulacean acid metabolism.     

A monoclonal antibody to the phosphorylated form of glial fibrillary acidic protein: application to a non-radioactive method for measuring protein kinase activities

Monoclonal antibody YC10 showed specificity for the phosphorylated form of human, bovine and porcine glial fibrillary acidic proteins (GFAPs) and negligible reactivity towards the dephosphorylated form of the GFAPs. Analysis of species specificity and of the epitope, determined using synthetic phosphopeptides, indicated that this antibody recognized the local phosphorylation-site sequence Thr-phosphoSer-Ala-Ala-Arg-Arg (residues 7-12 of GFAP). Making use of this antibody we developed a non-radioactive method to measure protein kinase activities. After incubation of a protein kinase with non-radioactive ATP in ninety-six wells coated with the synthetic peptide Arg-Arg-Arg-Val-Thr-Ser-Ala-Ala-Arg-Arg-Ser-Cys (residues 3-13 of GFAP), the phosphorylated product was detected by using this mouse antibody and peroxidase-labeled goat anti-mouse IgG. This method proved to be equally as sensitive as the radioactive method for the measurement of protein kinase activities and was less affected by concentrations of ATP present in the reaction mixture.     

A molecular dynamics study of the effect of G.T mispairs on the conformation of DNA in solution

The effect of G.T mispair incorporation into a double-helical environment was examined by molecular dynamics simulation. The 60-ps simulations performed on the two hexanucleotide duplexes d (G3C3)2 and d(G3TC2)2 included 10 Na+ counterions and first hydration shell waters. The resulting backbone torsional angle trajectories were analyzed to select time spans representative of conformational domains. The average backbone angles and helical parameters of the last time span for both duplexes are reported. During the simulation the hexamers retained B-type DNA structures that differed from typical A- or B-DNA forms. The overall helical structures for the two duplexes are vary similar. The presence of G.T mispairs did not alter the overall helical structure of the oligonucleotide duplex. Large propeller twist and buckle angles were obtained for both duplexes. The purine/pyrimidine crossover step showed a large decrease in propeller twist in the normal duplex but not in the mismatch duplex. Upon the formation of wobble mispairs in the mismatched duplex, the guanines moved into the minor groove and the thymines moved into the major groove. This helped prevent purine/purine clash and created a deformation in the relative orientation of the glycosidic bonds. It also exposed the free O4 of the thymines in the major groove and N2 of the guanines in the minor groove to interactions with solvent and counterions. These factors seemed to contribute to the apparently higher rigidity of the mismatched duplex during the simulation.     

Fragmentation of re-formation of mitotic Golgi apparatus detected by a centrifugal method

The fragmentation/re-formation process of the Golgi apparatus during mitosis was studied by flotation centrifugation in a stepwise sucrose density gradient. The mitotic Golgi fraction was obtained from Chinese hamster ovary cells synchronized with thymidine and nocodazole. The Golgi apparatus detected by a marker enzyme, galactosyltransferase, was separated into two peaks by the flotation centrifugation. The amount of the Golgi recovered at the lower density peak was less in the mitotic cells than in the interphase cells. The separation profile of the mitotic Golgi returned to that of the interphase Golgi by further incubation of the mitotic cells. The re-formation of the fragmented Golgi was inhibited by nocodazole and vinblastine, but not by actinomycin D and cycloheximide.     

Kinetics of hydroperoxide degradation by NADP-glutathione system in mitochondria

Hydroperoxide decomposition by the NADP-glutathione system in rat liver mitochondria was analyzed. Mitochondria were found to contain high concentrations of the reduced form of glutathione (GSH) (4.32 +/- 0.50 nmol/mg) and NADPH (4.74 +/- 0.64 nmol/mg), and high activities of glutathione peroxidase and reductase. In the initial phase of the reaction, the rate of hydroperoxide decomposition was proportional to both the GSH level and the activity of GSH peroxidase. However, in the later steady state, the step of NADP reduction was rate-limiting, and the overall reaction rate was independent of the initial concentration of GSH, and activities of glutathione peroxidase and reductase. Some GSH was released from mitochondria during incubation, but the rate of the decomposition could be simply expressed as kappa [GSH]/2, where kappa is the first-order rate constant of the peroxidase and [GSH] is the intramitochondrial level of GSH in the steady state. The rate of the reaction in the steady state was also dependent on the NADPH level, its reciprocal being linearly correlated with [NADPH]-1. The rate of decomposition of hydroperoxide was influenced by the respiratory state. During state 3 respiration, the rate was greatly depressed, but was still considered to exceed by far the rate of physiological generation of hydroperoxide.     

Isolation of anti-endothelin receptor monoclonal antibodies for use in receptor characterization

Monoclonal antibodies reactive with endothelin (ET) receptors have been prepared by immunization of mice with rat lung membranes. Of four clones isolated, three clones preferentially recognized 32,000-dalton ET receptor and the other has a higher affinity for the 45,000-dalton receptor. The binding of 125I-ET-1 to detergent-solubilized ET receptors which were adsorbed to the antibodies was displaced by increasing concentrations of unlabeled ET isopeptides. These results demonstrate that the four clones specific for the receptor have the potential to be a useful tool in the characterization of ET receptors.     

A molecular dynamics simulation of the (dG)6 . (dC)6 minihelix including counterions and water

The results of a 60 ps molecular dynamics (MD) simulation of (dG)6.(dC)6 including 10 Na+ counterions and 292 water molecules are presented. All backbone angles and helix parameters for the hexamer are reported in this paper along with trajectory plots of selected angles. Hydrogen bonding between the bases along the helical axis was observed to fluctuate with time, showing the dynamic nature of the base-pairing interaction. These fluctuations gave rise to unusual hydrogen-bonding patterns. Good intrastrand base stacking and no interstrand base stacking were also observed. The hexamer minihelix retains an essentially B-DNA conformation throughout the entire simulation even though some helix parameters and backbone angles do not have strict B-DNA values. The most striking feature obtained from the simulation was a high propeller twist, which resulted in a narrow minor groove for the minihelix. It is proposed that (dG)n.(dC)n sequences are resistant to DNAase I because of this narrow minor groove in dilute aqueous solution.     

A subunit of yeast site-specific endonuclease SceI is a mitochondrial version of the 70-kDa heat shock protein

Endo.SceI of Saccharomyces cerevisiae is a heterodimeric site-specific endonuclease, which is distinguishable from prokaryotic restriction endonucleases in the mode of recognition of its cleavage site. We have used monoclonal antibodies specific to the larger subunit (75 kDa) of Endo.SceI to isolate the gene for the subunit (ENS1) from S. cerevisiae. Unexpectedly, ENS1 was found to encode a 70-kDa heat shock protein-related polypeptide and to be identical to recently cloned SSC1. Subcellular fractionation experiments on yeast cells revealed that the primary target site of the larger subunit is mitochondria, where almost all the Endo.SceI activity is localized. Molecular genetic analysis of ENS1 demonstrated its indispensability for growth and the requirement of a high level of its expression at the sporulation and germination stages. The data suggest that ENS1 plays an important role, especially at these differentiation stages.     

D-loop cycle. A circular reaction sequence which comprises formation and dissociation of D-loops and inactivation and reactivation of superhelical closed circular DNA promoted by recA protein of Escherichia coli

Excess recA protein, a protein essential to general genetic recombination in Escherichia coli, promotes a sequence of formation and dissociation of D-loops from negative superhelical closed circular double-stranded DNA (form I DNA) and homologous single-stranded fragments in the presence of excess ATP, resulting in inactivation of the form I DNA without apparent damage to the DNA. The dissociation of D-loops is accompanied by hydrolysis of ATP to ADP that apparently depends on homologous DNA molecules (homology-dependent ATP hydrolysis). However, at a lower concentrations of ATP, we observed anomalous kinetics in the formation and dissociation of D-loops; as the concentration of ATP was decreased, there was a progressively smaller dissociation of D-loops and a faster resynthesis in the second phase, without changing the rate of the first formation of D-loops. This anomaly might suggest that, as the increase in the amount of ADP relative to that of ATP, dissociation form I DNA is stimulated before formation of D-loops is inhibited. We found that addition of ADP inhibited competitively both formation and dissociation of D-loops and that the latter process was more sensitive to the inhibition than was the former process. Addition of a sufficient amount of ADP to inhibit both formation and dissociation of D-loops, cessation of homology-dependent hydrolysis of ATP, or incubation at low temperature resulted in reactivation of form I DNA that had been inactivated by the sequence. In the presence of an ATP-regenerating system, we confirmed our previous result that limiting the amount of recA protein also causes anomalous kinetics in the formation and dissociation of D-loops. These observations indicate that the formation and dissociation of D-loops and the inactivation and reactivation of form I DNA make a circular reaction sequence.