The Synthesis of Ethylene in Melon Fruit during the Early Stage of Ripening

The levels of mRNA and polypeptide for a 1-aminocyclopropane-1-carboxylate(ACC) oxidase were studied to identify the tissues in whichthe synthesis of ethylene first occurs during the initial stageof ripening. RNA and immunoblot analysis showed that the levelsof the mRNA and polypeptide for ACC oxidase were very low inunripe fruit. They first became detectable in the placentaltissue at the pre-climacteric stage, and then their levels increasedin the mesocarp tissue during the climacteric increase in theproduction of ethylene. Two mRNAs for ACC synthase (transcribedfrom ME-ACS1 and ME-ACS2) were detected in the placental tissueand seeds at the pre-climacteric stage, but only the level ofME-ACS1 mRNA, which has been characterized as the mRNA for awound-inducible ACC synthase, increased in mesocarp, placentaltissues and seeds during ripening. The level of ME-ACS2 mRNAthat was isolated from etiolated seedlings of melon, did notchange markedly during ripening. These results suggest thatthe central region of melon fruit (placental tissue and seeds)plays a major role in the production of ethylene during theearly stage of ripening. ³These three authors made equal contribution to this study.     

Expression of ACC synthase is enhanced earlier than that of ACC oxidase during fruit ripening of mume (Prunus mume)

Mume (Japanese apricot: Prunus mume Sieb. et Zucc.) is a climacteric fruit that produces large amounts of ethylene as it ripens. Ripening is accompanied by marked increases in the activities of two ethylene-biosynthetic enzymes, namely, 1-aminocyclopropane-1-carboxylic acid (ACC) synthase and ACC oxidase. To study the molecular aspects of ripening of mume, we isolated cDNA clones for proteins that we considered likely to be involved in the biosynthesis and perception of ethylene during ripening, namely, ACC synthase, ACC oxidase and the ethylene receptor. Northern blotting analysis revealed the markedly increased expression of ACC synthase prior to that of ACC oxidase and the increase in ethylene production during ripening. Overall, the levels of the mRNAs for the genes corresponded closely to the levels of activity of the ethylene-biosynthetic enzymes. Exposure of mature green mume fruit to ethylene for 12 h induced strong expression of ACC synthase, as well as of ACC oxidase. Wounding of the pericarp of mume fruit induced the expression of ACC synthase but not of ACC oxidase. The rate of ethylene production increased only slightly after wounding. These results suggest that expression of the genes for ACC synthase and ACC oxidase must be activated sequentially for maximum production of ethylene during ripening of mume fruit and that several mechanisms regulate the expression of ethylene-biosynthetic genes during ripening.     

Ethylene regulation of fruit ripening: Molecular aspects

Progress in ethylene regulating fruit ripening concerning itsperception and signal transduction and expression of ACC synthaseand ACC oxidase genes is reviewed. ACC synthase and ACC oxidasehave been characterized and their genes cloned from various fruittissues. Both ACC synthase and ACC oxidase are encoded bymultigene families, and their activities are associated withfruit ripening. In climacteric fruit, the transition toautocatalytic ethylene production appears to be due to a seriesof events in which ACC sythase and ACC oxidase genes have beenexpressed developmentally. Differential expression of ACCsynthase and ACC oxidase gene family members is probably involvedin such a transition that ultimately controls the onset of fruitripening.In comparison to ACC synthase and ACC oxidase, less is knownabout ethylene perception and signal transduction because of thedifficulties in isolating and purifying ethylene receptors orethylene-binding proteins using biochemical methods. However, theidentification of the Nr tomato ripening mutant as anethylene receptor, the applications of new potent anti-ethylenecompounds and the generation of transgenic fruits with reducedethylene production have provided evidence that ethylenereceptors regulate a defined set of genes which are expressedduring fruit ripening. The properties and functions of ethylenereceptors, such as ETR1, are being elucidated.Application of molecular genetics, in combination withbiochemical approaches, will enable us to better understand theindividual steps leading from ethylene perception and signaltransduction and expression of ACC synthase and ACC oxidase genefamily member to the physiological responses.     

Expression of MdCAS1 and MdCAS2, encoding apple beta-cyanoalanine synthase homologs, is concomitantly induced during ripening and implicates MdCASs in the possible role of the cyanide detoxification in Fuji apple (Malus domestica Borkh.) fruits

Fruit ripening involves complex biochemical and physiological changes. Ethylene is an essential hormone for the ripening of climacteric fruits. In the process of ethylene biosynthesis, cyanide (HCN), an extremely toxic compound, is produced as a co-product. Thus, most cyanide produced during fruit ripening should be detoxified rapidly by fruit cells. In higher plants, the key enzyme involved in the detoxification of HCN is β-cyanoalanine synthase (β-CAS). As little is known about the molecular function of β-CAS genes in climacteric fruits, we identified two homologous genes, MdCAS1 and MdCAS2, encoding Fuji apple β-CAS homologs. The structural features of the predicted polypeptides as well as an in vitro enzyme activity assay with bacterially expressed recombinant proteins indicated that MdCAS1 and MdCAS2 may indeed function as β-CAS isozymes in apple fruits. RNA gel-blot studies revealed that both MdCAS1 and MdCAS2 mRNAs were coordinately induced during the ripening process of apple fruits in an expression pattern comparable with that of ACC oxidase and ethylene production. The MdCAS genes were also activated effectively by exogenous ethylene treatment and mechanical wounding. Thus, it seems like that, in ripening apple fruits, expression of MdCAS1 and MdCAS2 genes is intimately correlated with a climacteric ethylene production and ACC oxidase activity. In addition, β-CAS enzyme activity was also enhanced as the fruit ripened, although this increase was not as dramatic as the mRNA induction pattern. Overall, these results suggest that MdCAS may play a role in cyanide detoxification in ripening apple fruits.     

Biochemical properties of 1-aminocyclopropane-1-carboxylate N-malonyltransferase activity from early growing embryonic axes of chick-pea (Cicer arietinum L.) seeds

In the present work, certain biochemical characteristics ofthe enzyme 1-aminocyclopropane-1-carboxylate N-malonyltransferase(ACC N-MTase) which is responsible for the malonylation of 1-aminocyclopropane-1-carboxylate(ACC) in chickpea (Cicer arietinum) are described. Phosphatebuffer was the most appropriate buffer with regard to enzymestability and, therefore, ACC N-MTase was extracted, assayedand purified in the presence of this buffer. ACC N-MTase waspartially purified approximately 900-fold from embryonic axesof chick-pea seeds using ammonium sulphate precipitation, hydrophobicinteraction and molecular filtration chromatography. By gelfiltration chromatography on Superose-12, the molecular massof the enzyme was estimated to be 54 4 kDa. ACC N-MTase hadan optimal pH and temperature of 7.5 and 40C, respectively,as well as a K_m for ACC and malonyl-CoA of 400 M and 90 M,respectively. D-Phenylalanine was a competitive inhibitor ofACC N-MTase with respect to ACC (K_i of 720 M), whereas co-enzymeA was a competitive product inhibitor with respect to malonyl-CoA(K_i of 300 M) and a non-competitive inhibitor with respectto ACC (K_i of 600 M). Under optimal assay conditions, ACC N-MTasewas strongly inhibited by (a)divalent [Zn²⁺>Mg²⁺>>Co²⁺>Co²⁺>(NH₄)²⁺>Fe²⁺]and monovalent metal cations (Li⁺>Na⁺>K⁺), without activitybeing detected in the presence of Hg²⁺, and (b) PCMB or mersalicacid, suggesting that sulphydryl group(s) are involved at theactive site of the enzyme. Key words: ACC-N-malonyltransferase, Cicer arietinum, embryonic axes, ethylene, germination, seeds     

Development of Ethylene Biosynthesis in Pear Fruits at --1 {degrees}C

Knee, M. 1987. Development of ethylene biosynthesis in pearfruits at — 1 °C.—J. exp. Bot. 38: 1724–1733. The regulation of ethylene synthesis in pear fruits was investigated.During storage for 60 d at — 1 °C the rate of ethylenesynthesis increased 100-fold but the concentration of 1-aminocyclopropane-l-carboxylicacid (ACC) increased only 2-fold and ACC synthase activity waslow. On transfer to 15 °C after storage at — 1 °Cethylene synthesis increased 10-fold within 10 h but ACC synthaseactivity only increased rapidly after 24 h; the decline in ACClevels during the first 16 h at 15 °C was insufficient tosustain ethylene synthesis. Ethylene synthesis was further investigatedusing discs cut from the mid cortex of pear fruits. Synthesiswas inhibited by aminoethoxyvinylglycine (AVG) and amino-oxyaceticacid at all stages of ripening. The rate of synthesis and ACCsynthase activity increased rapidly after slicing of pears heldat — 1 °C but more slowly in discs cut from pearsimmediately after harvest. Cycloheximide (CHI) inhibited theseincreases and reversed increases resulting from pre-incubationof discs. A combination of CHI and AVG abolished the capacityof discs to synthesize ACC and ethylene production was curtailed.Cordycepin and actinomycin-D were less effective as inhibitorsof the development of ethylene synthesis and ACC synthase activitythan as inhibitors of incorporation of 5-[³H] uridine into totalRNA or poly A rich RNA. The ability of discs to develop ethylenesynthesis and ACC synthase activity in the presence and absenceof cordycepin increased concurrently during storage of wholefruits at — 1 °C. This suggested that mRNA for ACCsynthase was formed at — 1 °C. Key words: 1-Aminocyclopropane-l-carboxylic acid, ethylene, fruit ripening, Pyrus communis L. (fruit ripening)     

Tomato vesicles as a model system for studying in situ activity of 1-aminocyclopropane-1-carboxylic acid oxidase

A model system is described which could be used for the studyof ACC oxidase in vivo. The enzyme is localized within sedimentablevesicles isolated from the locular tissue of ripening tomatofruit. These vesicles display linear ACC oxidase activity overa period of at least 3 h and this activity is not dependenton the essential cofactors (Fe²⁺ and ascorbate) needed for theenzyme in vitro. This system has been used to demonstrate thepresence of an inhibitors) of ACC oxidase activity in the locularjuice and also to study the effects of ionophores and uncouplerson the in vivo enzyme activity. Key words: ACC oxidase, tomato, Lycopersicon esculentum     

Preliminary characterization of 1-aminocyclopropane-1-carboxylate oxidase properties from embryonic axes of chick-pea (Cicer arietinum L.) seeds

For a deeper understanding of the germination of chick–pea(Cicer arietinum) seeds, which is dependent upon ethylene synthesis,a crude extract containing authentic ACC oxidase (ACCO) activitywas isolated in soluble form from the embryonic axes of seedsgerminated for 24 h. Under our optimal assay conditions (200mM HEPES at pH 7.0, 4µM FeS0₄, 6 mM Na–ascorbate,1 mM ACC, 20% 0₂, 3% CO₂ , and 10%glycerol) this enzyme was5–fold more active than under the conditions we used initiallyin the present work. The enzyme has the following K_m: 28 µMfor ACC (approximately 4–fold less than in vivo), 1.2%for O₂ (in the presence of an optimal CO₂ concentration of 3%),and 1% for CO₂ in the presence of O₂ (20%). The enzyme is inhibitedby phenanthroline (PNT) (specific chelating agent of ferrousion), and competitively inhibited (K₁, =0.5 mM) by 2–aminoisobutyricacid (AIB), and the enzymatic activity was not detectable inthe absence of CO₂. Under optimal assay conditions, the enzymehas two optimum temperatures (28 C and 35 C) and is inhibitedby divalent metal cations (Zn²⁺> CO²⁺>Ni²⁺>Cu²⁺>Mn²⁺>Mg²⁺) and by salicylic acid, propylgallate, carbonyl cyanidem–chlorophenyl hydrazone (CCCP), dinitrophenol (DNP),and Na–benzoate. The in vitro ACCO activity which we recoveredin soluble form is equivalent to approximately 80–85%of the apparent activity evaluated in vivo. Key words: ACC oxidase, Cicer arietinum, ethylene, germination, seeds     

Ethylene Production by the Kudzu Strains of Pseudomonas syringae pv. phaseolicola Causing Halo Blight in Pueraria lobata (Willd) Ohwi

Significant amounts of ethylene was produced by Pseudomonassolanacearum (all strains), P. syringae pv. phaseolicola (Kudzustrains isolated from Pueraria lobata) and Erwinia rhapontici(2 strains out of 22) out of 24 species, 3 subspecies and 38pathovars of plant pathogenic bacteria tested in yeast extract-peptonebroth. The bean strains of P. syringae pv. phaseolicola causinghalo blight in kindney bean plants did not produce ethylene.The Kudzu strains produced ethylene at a rate of 7 to 100?10^–9nl cell^–1 h^–1, which was 500 to 1,000 times higherthan that of P. solanacearum and several times higher than thatof Penicillium digitatum, the most potent ethylene producerknown among microorganisms. The presence of living cells was essential for ethylene productionby the Kudzu strains. The bacterium effectively produced ethylenefrom amino acids such as glutamate, aspartate and their amides.Although glucose and succinate were also good substrates forethylene biosynthesis, the rate of ethylene production was significantlysmaller than that with glutamate. Methionine, which is knownas the precursor of ethylene in plants, had no effect on ethyleneproduction by the bacterium. 1-Aminocyclopropane-1-carboxylicacid (ACC) also had no effect on ethylene production, and therewas not enough ACC in the bacterial cells to account for thehigh rate of ethylene production. Ethylene production from glutamatewas inhibited by n-propylgallate and EDTA, but not by aminoethoxyvinylglycine.These results indicate that ACC is not involved as an intermediatein the process of ethylene biosynthesis by the bacterium, suggestingthe presence of a pathway different from that of plant tissues. (Received September 4, 1984; Accepted October 27, 1984)     

Pistil-Specific and Ethylene-Regulated Expression of 1-Aminocyclopropane-1-Carboxylate Oxidase Genes in Petunia Flowers

The differential expression of the petunia 1-aminocyclopropane-1-carboxylate (ACC) oxidase gene family during flower development and senescence was investigated. ACC oxidase catalyzes the conversion of ACC to ethylene. The increase in ethylene production by petunia corollas during senescence was preceded by increased ACC oxidase mRNA and enzyme activity. Treatment of flowers with ethylene led to an increase in ethylene production, ACC oxidase mRNA, and ACC oxidase activity in corollas. In contrast, leaves did not exhibit increased ethylene production or ACC oxidase expression in response to ethylene. Gene-specific probes revealed that the ACO1 gene was expressed specifically in senescing corollas and in other floral organs following exposure to ethylene. The ACO3 and ACO4 genes were specifically expressed in developing pistil tissue. In situ hybridization experiments revealed that ACC oxidase mRNAs were specifically localized to the secretory cells of the stigma and the connective tissue of the receptacle, including the nectaries. Treatment of flower buds with ethylene led to patterns of ACC oxidase gene expression spatially distinct from the patterns observed during development. The timing and tissue specificity of ACC oxidase expression during pistil development were paralleled by physiological processes associated with reproduction, including nectar secretion, accumulation of stigmatic exudate, and development of the self-incompatible response.     

授粉诱导兰花花部乙烯生物合成基因在转录水平上的表达

朵丽蝶兰（Ｄｏｒｉｔａｅｎｏｐｓｉｓｈｙｂｒｉｄａ Ｈｏｒｔ．）的花授粉后,测定乙烯的产生,并分析授粉后花部各器官乙烯生物合成的ＡＣＣ合成酶和ＡＣＣ氧化酶两个基因转录水平上的表达。授粉后在花部均可探测到ＡＣＣ合成酶和ＡＣＣ氧化酶的ｍ ＲＮＡ。在花部不同器官之间,此两种酶的ｍ ＲＮＡ的积累水平均表现出一些差异。ＡＣＣ合成酶的ｍ ＲＮＡ 积累与ＡＣＣ氧化酶相比,具有更明显的特异性。而ＡＣＣ氧化酶ｍ ＲＮＡ 的积累水平远比ＡＣＣ合成酶高