Oxidation-reduction potentials of cytochromes in Ascaris muscle mitochondria: high-redox-potential cytochrome b558 in complex II (succinate-ubiquinone reductase)

Oxidation-reduction midpoint potentials (Ems) were determined at pH 7.0 for cytochromes in the anaerobic respiratory chain of Ascaris mitochondria by redox titration techniques. Cytochrome b558, which is associated with complex II that functions as fumarate reductase in the terminal step of the respiratory chain, was shown to have an Em of -34 mV in the isolated complex II and -54 mV in mitochondria. These values are much higher than the value of Ascaris cytochrome b558. In contrast, Ems of cytochromes C + C1 and cytochrome b559.5 were determined in situ to be 235 mV and 78 mV, respectively, which are comparable to those of their mammalian counterparts.     

Inhibition of mitogen-stimulated T lymphocyte proliferation by calcitonin gene-related peptide

The effect of calcitonin gene-related peptide (CGRP) on mouse lymphocyte proliferation stimulated by mitogens was studied. CGRP (10(-10)-10(-7) M) dose-dependently inhibited the proliferative response of mouse lymph node cells and spleen cells stimulated by T cell mitogens concanavalin A (Con A) and phytohemagglutinin (PHA), whereas a B cell mitogen lipopolysaccharide (LPS) did not inhibit this response. The maximal inhibition by this peptide was 50% to 80% at 10(-8) and 10(-7) M. The addition of 10(-8) and 10(-7) M CGRP to lymph node cell cultures 24 hr after stimulation with Con A or PHA also had a significant inhibitory effect on the proliferative response. Furthermore, in the same concentration range (10(-10)-10(-7) M) CGRP increased intracellular cyclic AMP concentration in nylon wool nonadherent cells, but not in nylon wool adherent cells. CGRP had no significant effect on intracellular cyclic GMP concentration. In addition, specific binding of CGRP was observed in mouse spleen cells. Our present study suggests that CGRP inhibits the proliferative response of T lymphocytes to the mitogens by interacting with cell receptors coupled with adenylate cyclase. CGRP may be implicated in the regulation of T cell function.     

Purification and properties of trimethylamine N-oxide reductase from aerobic photosynthetic bacterium Roseobacter denitrificans.

Trimethylamine N-oxide (TMAO) reductase was purified from an aerobic photosynthetic bacterium Roseobacter denitrificans. The enzyme was purified from cell-free extract by ammonium sulfate fractionation, DEAE ion exchange chromatography, hydrophobic chromatography, and gel filtration. The purified enzyme was composed of two identical subunits with molecular weight of 90,000, as identified by SDS-polyacrylamide gel electrophoresis, containing heme c and a molybdenum cofactor. The molecular weight of the native enzyme determined by gel filtration was 172,000. The midpoint redox potential of heme c was +200 mV at pH 7.5. Absorption maxima appeared at 418,524, and 554 nm in the reduced state and 410 nm in the oxidized state. The enzyme reduced TMAO, nicotine acid N-oxide, picoline N-oxide, hydroxylamine, and bromate, but not dimethyl sulfoxide, methionine sulfoxide, chlorate, nitrate, or thiosulfate. Cytochrome c2 served as a direct electron donor. It probably catalyzes the electron transfer from cytochrome b-c1 complex to TMAO reductase. Cytochrome c552, another soluble low-molecular-weight cytochrome of this bacterium, also donated electrons directly to TMAO reductase.     

Photosynthetic electron transfer system is inoperative in anaerobic cells of Erythrobacter species strain OCh 114

Some of the photosynthetic reactions were measured under aerobic and anaerobic conditions in intact cells of an aerobic photosynthetic bacterium Erythrobacter species strain OCh 114 (ATCC No. 33942). In intact cells, the flash-light induced oxidation of cytochrome c-551, the continuous light-induced oxidation of reaction center bacteriochlorophyll and the continuous light-induced pH change ( ) of the suspension decreased on aerobic-anaerobic transition and almost disappeared under anaerobic conditions. These photosynthetic reactions reappeared when the suspension was aerated again. These phenomena were reconciled with the fact that Erythrobacter sp. cannot grow anaerobically even in the light. The incompetence of photoanaerobic growth of this bacterium was explained by the reduction of the primary electron acceptor (Q_I) before illumination, resulting partly from the relatively high midpoint potential of Q_I of this bacterium.Abbreviations Q_I Primary electron acceptor - E_h ambient redox potential - E_m midpoint redox potential     

Enzymatic Conversion of Pheophorbide a to the Precursor of Pyropheophorbide a in Leaves of Chenopodium album

Soluble proteins extracted from leaves of Chenopodium albumcatalyzed the conversion of pheophorbide a to a precursor ofpyropheophorbide a, putatively identified as C-13²-carboxyl-pyropheophorbidea. The precursor was then decarboxylated non-enzymatically toyield pyropheophorbide a. Soluble proteins and pheophorbidea, as the substrate, were required for the formation of theprecursor, and boiled proteins were enzymatically inactive.The maximum rate of conversion of pheophorbide a to the precursoroccurred at pH 7.5. The K_m for pheophorbide a was 12.5 µMat pH 7.0. Both pheophorbide b and bacteriopheophorbide a couldserve as substrates, but protopheophorbide a could not. Formationof methanol was detected during the enzymatic reaction, an indicationthat the enzyme is an esterase. Among seven alcohol analogstested, only methanol inhibited the enzymatic activity uncompetitively,with a K₁ of 71.6 mM. Mass-spectrometric (MS) analysis of theprecursor yield a peak at m/z 579 that indicated the releaseof a methyl group from pheophorbide a. It appears thereforethat the enzyme catalyzes the demethylation of the carbomethoxygroup at C-13² of pheophorbide a by hydrolysis to yield methanoland the precursor, C-13²-carboxyl-pyropheophorbide a, whichis converted to pyropheophorbide a by spontaneous decarboxylation.We have tentatively designated the enzyme "pheophorbidase".The presence of the enzyme was dependent on plant species andit was expressed constitutively. ¹Present address: Faculty of Science, Shizuoka University, Ohya,Shizuoka, 422 Japan     

Purification and Characterization of Two Isozymes of Chlorophyllase from Mature Leaves of Chenopodium album

Chlorophyllase (Chlase) was purified from mature leaves of Chenopodiumalbum, and its enzymatic properties were investigated. Chlasewas extracted from acetone powder of C. album and purified bythe following chroma-tographic procedures: hydrophobic chromatography,Con A Sepharose, Heparin affinity chromatography, Mono Q ion-exchangechromatography, and gel-filtration. Con A Sepharose affinitychromatography and gel-filtration were the most effective stepson the purification. On Mono Q chromatography, the Chlase preparationseparated into two major and one minor fractions that exhibitedChlase activity. The two major Chlases were purified to homogeneity.Their molecular masses were estimated as 41.3 kDa and 40.2 kDaby SDS-PAGE. The optimum pH and K_m values of these two Chlaseswere similar. Their N-terminal amino acid sequences were almostidentical except for a deletion in the tenth amino acid residuein one of the Chlase; there was no homologous protein detectedby database search. ³Present address: Department of Biology and Geoscience, Facultyof Science, Shizuoka University, 836 Ohya, Shizuoka, 422 Japan.     

Distinct pathways for jasmonate- and elicitor-induced expressions of a cytochrome P450 gene in soybean suspension-cultured cells

The mechanisms of the jasmonate-induced expression of genes encoding the cytochrome P450 CYP93A1 and lipoxygenase L-4 were analyzed in a soybean photomixotrophic cultured cell line, SB-P. The induction of the cytochrome P450 gene caused by methyl jasmonate (MeJA) was specifically suppressed by trifluoperazine and DCMU, inhibitors of chloroplast electron transport. Additionally, induction of the cytochrome P450 gene required irradiation. In contrast, induction of the lipoxygenase L-4 gene by the MeJA treatment occurred in both dark and light. Based on the results, the presence of two distinct signalling pathways for jasmonate-inducible gene expression, light-dependent and light-independent, is proposed. The jasmonate-inducible cytochrome P450 was also specifically induced by a fungal elicitor from a cell wall fraction of Phytophthora megasperma , a fungal pathogen, suggesting a role for P450 in the defense response to fungus in soybean cells. However, trifluoperazine did not block the elicitor-induced expression of cytochrome P450.     

Electrophoretic and cytological evidence for genetic heterogeneity and the hybrid origin ofAthyrium oblitescens

Athyrium oblitescens, a putative hybrid species, was examined electrophoretically and cytologically to clarify its origin. Allozyme data showed thatA. oblitescens consisted of at least three allozyme types, designated Type C, Type O and Type W. Genotypic compositions of Type C and Type W suggested that they were derived from independent hybridizations betweenA. otophorum andA. clivicola and betweenA. otophorum andA. wardii, respectively. Contrary to previous reports of tetraploidy inA. oblitescens and its hypothesized parent species, cytological observation revealed that Type C and Type W were both hexaploids. Possible pathways for the origin of these hexaploids are proposed. Type O was not genetically distinct fromA. otophorum by either electrophoretic or cytological analyses, and thus there was no evidence of hybrid origin.     

Distinctive features of plant organs characterized by global analysis of gene expression in Arabidopsis.

The distinctive features of plant organs are primarily determined by organ-specific gene expression. We analyzed the expression specificity of 8809 genes in 7 organs of Arabidopsis using a cDNA macroarray system. Using relative expression (RE) values between organs, many known and unknown genes specifically expressed in each organ were identified. We also analyzed the organ specificity of various gene groups using the GRE (group relative expression) value, the average of the REs of all genes in a group. Consequently, we found that many gene groups even ribosomal protein genes, have strong organ-specific expression. Clustering of the expression profiles revealed that the 8809 genes were classified into 9 major categories. Although 3451 genes were clustered into the largest category, which showed constitutive gene expression, 266 and 1005 genes were found to be root- and silique-specific genes, respectively. By this clustering, particular gene groups which showed multi-organ-specific expression profiles, such as bud-flower-specific, stem-silique-specific or bud-flower-root-specific profiles, could be effectively identified. From these results, major features of plant organs could be characterized by their distinct profiles of global gene expression. These data of organ-specific gene expression are available at our web site: Arabidopsis thaliana Tissue-Specific Expression Database, ATTED (http://www.atted.bio.titech.ac.jp/).