Maturation and Ripening of Fruit ofAmelanchier alnifoliaNutt. are Accompanied by Increasing Oxidative Stress

doi:10.1006/anbo.1997.0543

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Annals of Botany 81: 203-211, 1998
© 1998 Annals of Botany Company

Maturation and Ripening of Fruit ofAmelanchier alnifoliaNutt. are Accompanied by Increasing Oxidative Stress

SUZY Y. ROGIERS, G. N. MOHAN KUMAR and N. RICHARD KNOWLES⁺^,

Department of Agricultural, Food and Nutritional Science, 4–10 Agriculture/Forestry Center, University of Alberta, Edmonton, Alberta, Canada, T6G 2P5

June 5, 1997 ; August 26, 1997 . September 18, 1997 .

The extent of oxidative stress during ripening of saskatoon(AmelanchieralnifoliaNutt.) fruit was examined. Lipid peroxidation duringfruit development from the mature green to the fully ripe (purple)stage was evidenced by the accumulation of ethane and 2-thiobarbituricacid reactive substances. Fruit polar lipid and free fatty acidconcentrations also declined during ripening. Moreover, thedouble bond index of fatty acids in the polar lipid fractionfell during ripening, reflecting a progressive increase in thesaturation of membrane lipids. This increase in saturation waspartly due to a 65% decline in the concentration of linolenicacid. Activities of superoxide dismutase (SOD) and catalase(CAT) fell about 4-fold and 18-fold, respectively, during development,indicating higher potential for the accumulation of cytotoxicH₂O₂. Peroxidase activity remained relatively low and constantfrom the mature green to the dark red stage of development,then increased towards the end of ripening as fruits turnedpurple. Lipoxygenase (LOX) activity increased 2.5-fold fromthe mature green to the fully ripe stage. Tissue prints showedLOX to be present throughout fruit development and Western analysisrevealed that the increase in activity during ripening was dueto increased synthesis of the enzyme. Collectively, these resultsprovide evidence that ripening of this climacteric fruit isaccompanied by a substantial increase in free-radical-mediatedperoxidation of membrane lipids, probably as a direct consequenceof a progressive decline in the enzymatic systems responsiblefor catabolism of active oxygen species. The role of glutathione-mediatedfree-radical scavenging was also examined as a potential systemfor coping with this increased oxidative stress. Concentrationsof reduced and oxidized glutathione (GSSG) increased 2-foldand GSSG increased as a percentage of total glutathione, reflectingthe increase in oxidative status of fruits during ripening.Tissue prints of glutathione reductase (GRase) and transferase(GTase) showed these enzymes to be distributed throughout thepericarp at all stages of fruit development. GRase and GTaseactivities rose sharply during the later stages of fruit ripening,correlating well with substantial increases in the levels ofboth enzymes. Hence, the glutathione-mediated free-radical scavengingsystem was up-regulated towards the end of ripening, perhapsin response to the increasing oxidative stress resulting fromthe accumulation of lipid hydroperoxides from increased LOXactivity, in conjunction with a decline in SOD/CAT activities.Copyright1998 Annals of Botany Company

Amelanchier alnifoliaNutt.; saskatoon fruit; ripening; oxidative stress.

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