Involvement of the Binuclear Copper Site in the Proteolytic Activity of Polyphenol Oxidase

Plant polyphenol oxidase (PPO) is apt to degrade during andeven after purification. We developed a method to stabilizePPO by 0.3 M NaCl, 0.1% (w/v) Tween 20, and 50% (w/v) ethyleneglycol at pH 6.5. The protein slowly degraded by itself whenthe stabilizing reagents were removed. Ascorbate and/or H₂O₂accelerated the degradation. The ascorbate-induced degradationwas inhibited by catalase, suggesting that H₂O₂ is generatedthrough reduction of PPO by ascorbate. It is likely that dissolvedoxygen is converted to peroxide through two-electron reductionby the reaction center of PPO, binuclear Cu site, and a Fenton-typereaction occurred on it. This understanding was supported bythe finding that the H₂O₂-induced degradation was inhibitedby metal-chelators as well as by polyphenolic substrate of PPO.Considering the postulated mechanism of the self-degradationof PPO, we re-examined the degradation of the 23-kDa proteinof PSII by PPO [Kuwabara et al. (1997) Plant Cell Physiol. 38:179]. The obtained results suggested that the 23-kDa proteintriggers the active oxygen production by the binuclear Cu site,probably as reductant, and receives the radical species preferentiallyto the polypeptide moiety of PPO. (Received April 15, 1999; Accepted July 21, 1999)     

Subnuclear localization and antitransforming activity of N-myc:beta-galactosidase fusion proteins.

N-myc expression is under stage- and tissue-specific regulation in mammalian development, but its function is totally unknown. We sought agents to block N-myc activity in order to infer from the effect the possible function of N-myc in the apparently complex processes. As candidates for such agents, we tested fusion genes encoding N-myc:beta-galactosidase fusion proteins for their effects on the formation of transformed foci of rat embryo primary fibroblasts as the result of transfection with N-myc and activated H-ras. One of the gene constructs very efficiently antagonized N-myc activity, as assessed by its effect on focus formation, but did not appreciably affect cell viability. The product of this gene was not only targeted to the nucleus but also accumulated in subnuclear loci which may represent the sites where normal N-myc proteins reside. The occurrence of antagonistic effect at a low stoichiometric ratio suggested that the fusion protein gene competed with the N-myc gene in a fashion analogous to a dominant negative mutation.     

Separation of Cl-Containing Chlorophylls by Column Chromatography

Using Toyopearl and cyclohexane: cyclohexanol solvent, fourCl-containing Chls were separated from ³⁶Cl-labeled cells ofthe blue-green, Plectonema boryanum. In normally grown cells,all four Cl-containing chlorophylls amounted to less than 1/2,000of the total Chi and about 1/50 of P700, values much lower thanpreviously reportedcontents of Chi RC I, and varied from algato alga. The level of Cl-containing Chi was markedly enhancedwhen the cells were poisoned with methyl viologen. These resultssuggests that these Cl-containing Chls are not related to thereaction center of PS I. (Received June 23, 1987; Accepted September 17, 1987)     

Effects of Exogenous Amino Acids on Iron Uptake in Relation to their Effects on Photoperiodic Flowering in Lemna paucicostata 6746

The flowering of Lemna paucicostata 6746 grown on 14-h photoperiodwas enhanced by the addition of high concentrations of ironto the medium, which also increased the endogenous iron concentration.The addition of asparagine, aspartate, glutamate, -alanine,glycine or serine to the medium also increased the endogenousiron level, resulting in the promotion of flowering. In contrast,the addition of cysteine, cystine, glutamine, arginine, threonineor phenylalanine lowered the endogenous iron level, resultingin the inhibition of flowering. Glycine and asparagine added to the medium during an inductive96-h dark period did not promote iron uptake and had no effecton flowering, but when added during the subsequent 120-h lightperiod, they promoted both iron uptake and flowering response.The increase in the endogenous iron level seems to favor floraldevelopment rather than induction of photoperiodic floweringof Lemna paucicostata 6746. (Received September 8, 1986; Accepted March 31, 1987)     

Distribution and evolution of C4 syndrome inRhynchospora (Rhynchosporeae-Cyperaceae)

In order to elucidate the evolution of C₄ syndrome, the taxonomic relationships, leaf anatomy, and ecological and global distribution of C₃ and C₄ species in the genusRhynchospora were investigated. The anatomical observation for 181 species revealed that 26 C₄ species occurred within theCapitatae group of the subgenusHaplostyleae, a natural group showing highly advanced morphological characteristics, together with several C₃ species. In spite of there being rather few C₄ species, they possessed two kinds of Kranz anatomical structure differing from each other in the location of Kranz cells. Some C₃ species ofCapitatae showed radial arrangement in mesophyll cells surrounding vascular bundles, which is distinguished from typical non-Kranz anatomy. The C₄ species extended their ecological ranges from wet habitats to dry savanna grasslands, while the C₃ species showed the best development in wet habitats. The C₃ species were widespread from tropical to temperate regions with partial range extension into subarctic regions of both hemispheres, showing conspicuously high concentration of species in the New World, but being absent from arid climatic regions. The C₄ species were distributed mostly in tropics and subtropics, showing two separate distributional centers in South and Central America and in Tropical Asia and Australia. The range of C₄ species was nearly completely included in the C₃ range. In conclusion, it seems that inRhynchospora the C₄ syndrome evolved relatively recently, and arose in at least two separate phylogenetic trends in the tropics and the subtropics, more probably in the Neotropics.