Yuzo Shioi

Re-examination of Mg-dechelation reaction in the degradation of chlorophylls using chlorophyllin a as a substrate

The Mg-dechelating activity of extracts of Chenopodium album (goosefoot) was investigated using an artificial substrate, chlorophyllin a. The activity was measured spectrophotometrically by the formation of a reaction product, pheophorbin a (Mg-free chlorin), after release of the central Mg. The Mg-releasing protein was highly purified by successive DEAE, Butyl and HW-55 chromatographies. The molecular weight of the purified protein was 20 k by gel filtration. The protein showed a broad, but single, pH optimum at 7.5. The Km value for chlorophyllin a was 95.1 nM at pH 7.5. The Mg-releasing protein was not active with chlorophyllide a, a native substrate, although it was active with Zn-chlorophyllin a. Similar results were obtained from horseradish peroxidase. Only a small molecular weight, metal-chelating substance (MCS) had Mg-dechelating activity for the native substrate. An inhibitor study showed involvement of radicals in the Mg-dechelation of the Mg-releasing protein. The purified Mg-releasing protein showed neither peroxidase activity nor absorption bands in the visible region, and this indicates that the Mg-releasing protein is clearly distinct from horseradish peroxidase, which is a heme-containing protein. A likely conclusion is that the Mg-releasing protein and horseradish peroxidase are not involved in the Mg-dechelation in the degradation pathway of chlorophylls. The relevance of the participation of MCS in Mg-dechelation in the breakdown of chlorophylls (Chls) is also discussed.

Chlorophyll analysis by high-performance liquid chromatography

Abstract The separation and determination of chlorophylls by high-performance liquid chromatography (HPLC) is described. Chlorophylls and their derivatives were separated by reversed-phase HPLC based on hydrophobic interaction between solute and support, using an octadecyl silica column and elution with 100% methanol. Separated pigments were detected fluorometrically with a sensitivity in the picomole range: the fluorescence response was linear over a wide pigment concentration range. Resolution of five chlorophylls a and four protochlorophyll species esterified with different alcohols was achieved within 22 min in a single experiment. This method can be used for the determination of chlorophyll b, bacteriochlorophyll a esters and products synthesized from chlorophyll, but not for nonesterified pigments, i.e., chlorophyllide, protochlorophyllide and chlorophyll c. The chromatographic mobility of chlorophyll a esterified with different alcohols increases with increasing number of carbon atoms in the esterifying alcohols. The plots obtained from the logarithm of the capacity factor (k′) of these pigments versus the numbers of carbon atoms of the alcohol molecule gave a straight line, thus permitting the estimation of the chain length of unknown pigment esterifying alcohols. This HPLC separation technique did not cause the formation of artifacts. The deviation of the individual retention time for each pigment is less than ±0.5%, thus making this method suitable for the rapid identification and quantification of unknown pigments.

Pyropheophorbide a, a catabolite of ethylene-induced chlorophyll a degradation.

Abstract An enzyme extract prepared from ethylene-induced degreening fruits of Citrus unshiu contains chlorophyll degrading enzymes. The fate of chlorophyll carbons during an enzymatic degradation was investigated using [14C]-chlorophyll a. Accompaning the disappearance of labelled chlorophyll a, labelled chlorophyllide a, pheophorbide a, and pyropheophorbide a appeared respectively, and accumulation of pyropheophorbide a was observed. Unlike ethylene-induced Citrus fruits (in vivo), further degradation of pyropheophorbide a did not occur in the in vitro enzyme system. The significance of these pigments in regreening of Citrus fruits is discussed.

Induction of a novel cytochrome P450 (CYP93 family) by methyl jasmonate in soybean suspension-cultured cells

We isolated a cDNA encoding a novel cytochrome P450 (CYP93A1) from soybean suspension-cultured cells that had been treated with methyl jasmonate (MeJA). The amino acid sequence of the gene product had 30-40% identity with those of other plant P450s. The protein contained the heme-binding domain which is highly conserved among plant P450s. Transcription of the cytochrome P450 gene in soybean cells was induced by 30 microM MeJA even in the presence of cycloheximide, and reached maximum level 6 h after MeJA treatment. This is the first report of a plant cytochrome P450 gene whose transcription is induced by MeJA even without protein synthesis.We isolated a cDNA encoding a novel cytochrome P450 (CYP93A1) from soybean suspension‐cultured cells that had been treated with methyl jasmonate (MeJA). The amino acid sequence of the gene product had 30–40% identity with those of other plant P450s. The protein contained the heme‐binding domain which is highly conserved among plant P450s. Transcription of the cytochrome P450 gene in soybean cells was induced by 30 μM MeJA even in the presence of cycloheximide, and reached maximum level 6 h after MeJA treatment. This is the first report of a plant cytochrome P450 gene whose transcription is induced by MeJA even without protein synthesis.

A versatile assay for the accurate, time-resolved determination of cellular viability

A convenient and versatile method for the accurate, time-resolved determination of cellular viability has been developed. The conventional viability indicator fluorescein diacetate (FDA), which is converted to the fluorescent compound fluorescein in living cells, was employed as a viability probe. Fluorescence emission from cells was measured using a spectrofluorimeter equipped with a magnetic stirrer. Using this assay cell suspensions exhibiting densities in the range 0.5 x 10(5) to 2.0 x 10(5) cells displayed a linear response when FDA concentrations less than 12 micro M were employed. To calibrate the method, viability standards were elaborated using different proportions of living and dead cells, and a correlation coefficient for the viability of tobacco BY-2 suspensions was calculated as 0.998. This viability assay was also found to be applicable to Chlamydomonas reinhardtii and Arabidopsis thaliana cultured cells. Using this cell viability assay, kinetic analyses of cell death could be performed. Using the proteinaceous elicitor from Phytophthora cryptogea, cryptogein, to induce cell death in tobacco cell suspensions, values for the maximum velocity of death induction rate (V(max)) and the LD50 (half-maximal velocity or k(1/2)) were calculated as 17.2 (% death/h) and 65 nM, respectively.

Analysis of chlorophylls and their derivatives by matrix-assisted laser desorption/ionization-time-of-flight mass spectrometry

The analysis of chlorophylls and their derivatives by matrix-assisted laser desorption/ionization-time-of-flight mass spectrometry is described. Four matrices-sinapinic acid, a-cyano-4-hydroxycinnnamic acid, terthiophene, and 3-aminoquinoline-were examined to determine optimal conditions for analysis of the molecular mass and structure of chlorophyll a as a representative chlorophyll. Among them, terthiophene was the most efficient without releasing metal ions, although it caused fragmentation of the phytol-ester linkage. Terthiophene was useful for the analyses of chlorophyll derivatives as well as porphyrin products such as 8-deethyl-8-vinyl-chlorophyll a, pheophorbide a, pyropheophorbide a, bacteriochlorophyll a esterified phytol, and protoporphyrin IX. The current method is suitable for rapid and accurate determination of the molecular mass and structure of chlorophylls and porphyrins.

Spectroscopical studies on the light-harvesting pigment-protein complex II from dark-aerobic and light-anaerobic grown cells of Rhodobacter sulfidophilus

The photosynthetic bacterium Rhodobacter sulfidophilus can grow and synthesize photosynthetic pigments under dark-aerobic as well as light-anaerobic growth conditions. Under both growth conditions intracytoplasmic membrane vesicles (diameter about 35 nm) are formed. The light-harvesting (LH) pigment-protein complex II, isolated from dark-aerobic and light-anaerobic grown cells, consists of two small polypeptides (

Biochemical and molecular characterization of senescence‐related cysteine protease–cystatin complex from spinach leaf

Cysteine proteases (CPs) with N-succinyl-Leu-Tyr-4-methylcoumaryl-7-amide (Suc-LY-MCA) cleavage activity were investigated in green and senescent leaves of spinach. The enzyme activity was separated into two major and several faint minor peaks by hydrophobic chromatography. These peaks were conventionally designated as CP1, CP2 and CP3, according to their order of elution. From the analyses of molecular mass, subunit structure, amino acid sequences and cDNA cloning, CP2 was a monomer complex (SoCP-CPI) (51 kDa) composed of a 41-kDa core protein, SoCP (Spinacia oleracea cysteine protease), and 14-kDa cystatin, a cysteine protease inhibitor (CPI), while CP3 was a trimer complex (SoCP-CPI)(3) (151 kDa) of the same subunits as SoCP-CPI and showed a wider range of specificity toward natural substrates than SoCP-CPI. Trimer (SoCP-CPI)(3) was irreversibly formed from monomers through association. The results of reverse transcription-polymerase chain reaction (RT-PCR) revealed that mRNAs of CPI and SoCP are hardly expressed in green leaves, but they are coordinately expressed in senescent leaves, suggesting that these proteases involve in senescence. Purified recombinant CPI had strong inhibitory activity against trimer SoCP, (SoCP)(3) , which had a cystatin deleted with K(i) value of 1.33 × 10(-9) M. After treatment of the enzyme with a succinate buffer (pH 5) at the most active pH of the enzyme, sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and activity analyses showed that cystatin was released from both monomer SoCP-CPI and trimer (SoCP-CPI)(3) complexes with a concomitant activation. Thus, the removal of a cystatin is necessary to activate the enzyme activity.

Characterization and Cloning of the Chlorophyll-Degrading Enzyme Pheophorbidase from Cotyledons of Radish

Enzymatic removal of the methoxycarbonyl group of pheophorbide (Pheid) a in chlorophyll degradation was investigated in cotyledons of radish (Raphanus sativus). The enzyme pheophorbidase (PPD) catalyzes the conversion of Pheid a to a precursor of pyropheophorbide (PyroPheid), C-132-carboxylPyroPheid a, by demethylation, and then the precursor is decarboxylated nonenzymatically to yield PyroPheid a. PPD activity sharply increased with the progression of senescence in radish, suggesting de novo synthesis of PPD. The enzyme activity was separated into two peaks in anion-exchange and hydrophobic chromatography; the terms type 1 and type 2 were applied according to the order of elution of these enzymes in anion-exchange chromatography. PPD types 1 and 2 were purified 9,999- and 6,476-fold, with a yield of 0.703% and 2.73%, respectively. Among 12 substrates tested, both enzymes were extremely specific for Pheids of the dihydroporphyrin and tetrahydroporphyrin types, indicating that they are responsible for the formation of these PyroPheids. Both PPDs had molecular masses of 113,000 kD on gel filtration and showed three bands of 16.8, 15.9, and 11.8 kD by SDS-PAGE. The partial N-terminal amino acid sequences for these bands of PPD (type 2) were determined. Based on their N-terminal amino acid sequences, a full-length cDNA of PPD was cloned. The molecular structure of PPD, particularly the molecular mass and subunit structure, is discussed in relation to the results of SDS-PAGE.

Polyethylene-based high-performance liquid chromatography of chloroplast pigments: Resolution of mono- and divinyl chlorophyllides and other pigment mixtures☆

In addition to most chlorophylls and their derivatives, monovinyl and divinyl chlorophyll species were separated by high-performance liquid chromatography, using a polyethylene column and a simple elution with aqueous acetone. Peak retention and resolution of the pigment separation were greatly increased by increasing the polarity of the mobile phase and also by decreasing the column temperature. Polyethylene chromatography showed chlorophyll separation behavior similar to that of the octadecyl silica column, but it showed no adsorption of the pigment species containing free carboxylic acid groups, enabling the complete separation of chlorophylls and their derivatives. Polyethylene is a superior alternative stationary phase to the known reversed-phase materials for chlorophyll separation and analysis.