Your search keyword '"Alkalai-Tuvia S"' showing total 2 results

1. Fruit cuticle lipid composition and water loss in a diverse collection of pepper (Capsicum).

Author

Parsons EP, Popopvsky S, Lohrey GT, Alkalai-Tuvia S, Perzelan Y, Bosland P, Bebeli PJ, Paran I, Fallik E, and Jenks MA

Subjects

Alcohols analysis, Capsicum genetics, Capsicum metabolism, Coumaric Acids analysis, Fatty Acids analysis, Fruit genetics, Fruit metabolism, Genes, Plant genetics, Genotype, Lipids chemistry, Palmitic Acid analysis, Plant Epidermis chemistry, Plant Epidermis genetics, Plant Epidermis metabolism, Plant Structures chemistry, Plant Structures genetics, Plant Structures metabolism, Quantitative Trait Loci genetics, Species Specificity, Stearic Acids analysis, Sterols analysis, Terpenes analysis, Capsicum chemistry, Fruit chemistry, Membrane Lipids chemistry, Water metabolism, Waxes chemistry

Abstract

Pepper (Capsicum spp.) fruits are covered by a relatively thick coating of cuticle that limits fruit water loss, a trait previously associated with maintenance of postharvest fruit quality during commercial marketing. To shed light on the chemical-compositional diversity of cuticles in pepper, the fruit cuticles from 50 diverse pepper genotypes from a world collection were screened for both wax and cutin monomer amount and composition. These same genotypes were also screened for fruit water loss rate and this was tested for associations with cuticle composition. Our results revealed an unexpectedly large amount of variation for the fruit cuticle lipids, with a more than 14-fold range for total wax amounts and a more than 16-fold range for cutin monomer amounts between the most extreme accessions. Within the major wax constituents fatty acids varied from 1 to 46%, primary alcohols from 2 to 19%, n-alkanes from 13 to 74% and triterpenoids and sterols from 10 to 77%. Within the cutin monomers, total hexadecanoic acids ranged from 54 to 87%, total octadecanoic acids ranged from 10 to 38% and coumaric acids ranged from 0.2 to 8% of the total. We also observed considerable differences in water loss among the accessions, and unique correlations between water loss and cuticle constituents. The resources described here will be valuable for future studies of the physiological function of fruit cuticle, for the identification of genes and QTLs associated with fruit cuticle synthesis in pepper fruit, and as a starting point for breeding improved fruit quality in pepper., (© 2013 Scandinavian Plant Physiology Society.)

Published

2013

2. Fruit cuticle lipid composition and fruit post-harvest water loss in an advanced backcross generation of pepper (Capsicum sp.).

Author

Parsons EP, Popopvsky S, Lohrey GT, Lü S, Alkalai-Tuvia S, Perzelan Y, Paran I, Fallik E, and Jenks MA

Subjects

Capsicum genetics, Chimera, Genetic Variation, Inbreeding, Stress, Physiological, Capsicum chemistry, Capsicum metabolism, Fruit chemistry, Fruit metabolism, Membrane Lipids chemistry, Water metabolism, Waxes chemistry

Abstract

To understand the role of fruit cuticle lipid composition in fruit water loss, an advanced backcross population, the BC(2)F(2) , was created between the Capsicum annuum (PI1154) and the Capsicum chinense (USDA162), which have high and low post-harvest water loss rates, respectively. Besides dramatic differences in fruit water loss, preliminary studies also revealed that these parents exhibited significant differences in both the amount and composition of their fruit cuticle. Cuticle analysis of the BC(2)F(2) fruit revealed that although water loss rate was not strongly associated with the total surface wax amount, there were significant correlations between water loss rate and cuticle composition. We found a positive correlation between water loss rate and the amount of total triterpenoid plus sterol compounds, and negative correlations between water loss and the alkane to triterpenoid plus sterol ratio. We also report negative correlations between water loss rate and the proportion of both alkanes and aliphatics to total surface wax amount. For the first time, we report significant correlations between water loss and cutin monomer composition. We found positive associations of water loss rate with the total cutin, total C(16) monomers and 16-dihydroxy hexadecanoic acid. Our results support the hypothesis that simple straight-chain aliphatic cuticle constituents form more impermeable cuticular barriers than more complex isoprenoid-based compounds. These results shed new light on the biochemical basis for cuticle involvement in fruit water loss., (Copyright © Physiologia Plantarum 2012.)

Published

2012