JASMONATE TREATMENT (jasmonate + treatment)

Distribution by Scientific Domains

Kinds of JASMONATE TREATMENT

  • methyl jasmonate treatment


  • Selected Abstracts


    CYSTATIN ACCUMULATION IN TOMATO LEAVES AFTER METHYL JASMONATE TREATMENT OR MECHANICAL INJURY

    JOURNAL OF FOOD BIOCHEMISTRY, Issue 1 2002
    JU WEN WU
    The elicitation of cystatin accumulation in tomato leaves was studied with mature and seedling cv. Bonnie Best. Repetitive mechanical injury (MI) or methyl jasmonate (MJ) treatment of seedlings elicited plentiful cystatin accumulation in the leaves when plants were held at 30C under continuous lighting. Cystatin accumulation in leaves of MI seedlings decreased by 50% when incubated at a reduced light period of 12 h light/day. Cystatin accumulation in MJ treated plants was not influenced by reducing the light period from 24 h to 12 h/day. Cystatin accumulation after MJ treatment was optimal at 35C and negligible at 40C. At ambient field conditions (I8,33C), MJ treated seedlings still accumulated a significant amount of cystatin; however, very little cystatin accumulated in leaves of MI seedlings under these conditions of lower temperature and light exposure. The leaves of mature plants accumulated less cystatin after MJ or MI treatment than did those of seedlings. [source]


    REDUCTION IN MICROBIAL GROWTH AND IMPROVEMENT OF STORAGE QUALITY IN FRESH-CUT PINEAPPLE AFTER METHYL JASMONATE TREATMENT

    JOURNAL OF FOOD QUALITY, Issue 1 2005
    MAGALY MARTÍNEZ-FERRER
    ABSTRACT Maintaining the quality of a fresh-cut fruit or vegetable product is a major concern and a priority in the development and in the production of fresh-cut produce products of the industry. The industry has been searching for alternative methods to protect fresh-cut produce from decay and to prolong shelf life. The objective of this research is to enhance the quality and the shelf life of fresh-cut pineapple by exposure to methyl jasmonate (MJ). The exposure of the diced pineapple to a MJ emulsion at a concentration of 10,4 M for 5 min in a sealed container decreased microbiological growth by 3 logs after 12 days of storage at 7C, compared with the control pineapple. Methyl jasmonate as vapor or as dip did not affect the firmness or the color of the fruit. Methyl jasmonate may be a practical treatment to ensure the safety and the quality of fresh-cut pineapple and other fruits and vegetables. [source]


    Cloning, characterization and localization of a novel basic peroxidase gene from Catharanthus roseus

    FEBS JOURNAL, Issue 5 2007
    Santosh Kumar
    Catharanthus roseus (L.) G. Don produces a number of biologically active terpenoid indole alkaloids via a complex terpenoid indole alkaloid biosynthetic pathway. The final dimerization step of this pathway, leading to the synthesis of a dimeric alkaloid, vinblastine, was demonstrated to be catalyzed by a basic peroxidase. However, reports of the gene encoding this enzyme are scarce for C. roseus. We report here for the first time the cloning, characterization and localization of a novel basic peroxidase, CrPrx, from C. roseus. A 394 bp partial peroxidase cDNA (CrInt1) was initially amplified from the internodal stem tissue, using degenerate oligonucleotide primers, and cloned. The full-length coding region of CrPrx cDNA was isolated by screening a leaf-specific cDNA library with CrInt1 as probe. The CrPrx nucleotide sequence encodes a deduced translation product of 330 amino acids with a 21 amino acid signal peptide, suggesting that CrPrx is secretory in nature. The molecular mass of this unprocessed and unmodified deduced protein is estimated to be 37.43 kDa, and the pI value is 8.68. CrPrx was found to belong to a ,three intron' category of gene that encodes a class III basic secretory peroxidase. CrPrx protein and mRNA were found to be present in specific organs and were regulated by different stress treatments. Using a ,-glucuronidase,green fluorescent protein fusion of CrPrx protein, we demonstrated that the fused protein is localized in leaf epidermal and guard cell walls of transiently transformed tobacco. We propose that CrPrx is involved in cell wall synthesis, and also that the gene is induced under methyl jasmonate treatment. Its potential involvement in the terpenoid indole alkaloid biosynthetic pathway is discussed. [source]


    Effects of progressive drought stress on the expression of patatin-like lipid acyl hydrolase genes in Arabidopsis leaves

    PHYSIOLOGIA PLANTARUM, Issue 1 2008
    Ana Rita Matos
    Patatin-like genes have recently been cloned from several plant species and found to be involved in stress responses and development. In previous work, we have shown that a patatin-like gene encoding a galactolipid acyl hydrolase (EC 3.1.1.26) was stimulated by drought in the leaves of the tropical legume, Vigna unguiculata L. Walp. The aim of the present work was to study the expression of patatin-like genes in Arabidopsis thaliana under water deficit. Expression of six genes was studied by reverse transcriptase polymerase chain reaction in leaves of plants submitted to progressive drought stress induced by withholding water and also in different plant organs. Three genes, designated AtPAT IIA, AtPAT IVC and AtPAT IIIA, were shown to be upregulated by water deficit but with different kinetics, while the other patatin-like genes were either constitutive or not expressed in leaves. The accumulation of transcripts of AtPAT IIA in the early stages of the drought treatment was coordinated with the upregulation of lipoxygenase and allene oxide synthase genes. AtPAT IIA expression was also induced by wounding and methyl jasmonate treatments. The in vitro lipolytic activity toward monogalactosyldiacylglycerol, digalactosyldiacylglycerol, phosphatidylcholine and phosphatidylglycerol was confirmed by producing the recombinant protein ATPAT IIA in insect cells. The analysis of free fatty acid pools in drought-stressed leaves shows an increase in the relative amounts of trans-3-hexadecenoic acid at the beginning of the treatment followed by a progressive accumulation of linoleic and linolenic acids. The possible roles of AtPAT IIA in lipid signaling and membrane degradation under water deficit are discussed. [source]