Yanjun Guo1,2, Jia Jun Li3, Lucas Busta3, Reinhard Jetter2,3. 1. College of Agronomy and Biotechnology, Southwest University, Chongqing, China. 2. Department of Botany, University of British Columbia, University Boulevard, Vancouver, BC, Canada. 3. Department of Chemistry, University of British Columbia, Vancouver, BC, Canada.
Abstract
Background and Aims: The cuticular waxes sealing plant surfaces against excessive water loss are complex mixtures of very-long-chain aliphatics, with compositions that vary widely between plant species. To help fill the gap in our knowledge about waxes of non-flowering plant taxa, and thus about the cuticle of ancestral land plants, this study provides comprehensive analyses of waxes on temperate fern species from five different families. Methods: The wax mixtures on fronds of Pteridium aquilinum, Cryptogramma crispa, Polypodium glycyrrhiza, Polystichum munitum and Gymnocarpium dryopteris were analysed using gas chromatography-mass spectrometry for identification, and gas chromatography-flame ionization detection for quantification. Key Results: The wax mixtures from all five fern species contained large amounts of C36-C54 alkyl esters, with species-specific homologue distributions. They were accompanied by minor amounts of fatty acids, primary alcohols, aldehydes and/or alkanes, whose chain length profiles also varied widely between species. In the frond wax of G. dryopteris, C27-C33 secondary alcohols and C27-C35 ketones with functional groups exclusively on even-numbered carbons (C-10 to C-16) were identified; these are characteristic structures similar to secondary alcohols and ketones in moss, gymnosperm and basal angiosperm waxes. The ferns had total wax amounts varying from 3.9 μg cm-2 on P. glycyrrhiza to 16.9 μg cm-2 on G. dryopteris, thus spanning a range comparable with that on leaves of flowering plants. Conclusions: The characteristic compound class compositions indicate that all five fern species contain the full complement of wax biosynthesis enzymes previously described for the angiosperm arabidopsis. Based on the isomer profiles, we predict that each fern species, in contrast to arabidopsis, has multiple ester synthase enzymes, each with unique substrate specificities.
Background and Aims: The cuticular waxes sealing plant surfaces against excessive water loss are complex mixtures of very-long-chain aliphatics, with compositions that vary widely between plant species. To help fill the gap in our knowledge about waxes of non-flowering plant taxa, and thus about the cuticle of ancestral land plants, this study provides comprehensive analyses of waxes on temperate fern species from five different families. Methods: The wax mixtures on fronds of Pteridium aquilinum, Cryptogramma crispa, Polypodium glycyrrhiza, Polystichum munitum and Gymnocarpium dryopteris were analysed using gas chromatography-mass spectrometry for identification, and gas chromatography-flame ionization detection for quantification. Key Results: The wax mixtures from all five fern species contained large amounts of C36-C54 alkyl esters, with species-specific homologue distributions. They were accompanied by minor amounts of fatty acids, primary alcohols, aldehydes and/or alkanes, whose chain length profiles also varied widely between species. In the frond wax of G. dryopteris, C27-C33 secondary alcohols and C27-C35 ketones with functional groups exclusively on even-numbered carbons (C-10 to C-16) were identified; these are characteristic structures similar to secondary alcohols and ketones in moss, gymnosperm and basal angiosperm waxes. The ferns had total wax amounts varying from 3.9 μg cm-2 on P. glycyrrhiza to 16.9 μg cm-2 on G. dryopteris, thus spanning a range comparable with that on leaves of flowering plants. Conclusions: The characteristic compound class compositions indicate that all five fern species contain the full complement of wax biosynthesis enzymes previously described for the angiosperm arabidopsis. Based on the isomer profiles, we predict that each fern species, in contrast to arabidopsis, has multiple ester synthase enzymes, each with unique substrate specificities.
Authors: Harald Schneider; Eric Schuettpelz; Kathleen M Pryer; Raymond Cranfill; Susana Magallón; Richard Lupia Journal: Nature Date: 2004-04-01 Impact factor: 49.962