Genetic Variation in Needle Epicuticular Wax Characteristics in Pinus Pinceana Seedlings-Reference-Cited by-同舟云学术

Genetic Variation in Needle Epicuticular Wax Characteristics in Pinus Pinceana Seedlings

Published:2011-12-01 Issue:1-6 Volume:60 Page:210-215
ISSN:2509-8934
Container-title:Silvae Genetica
language:en
Short-container-title:

Author:

Ramirez-Herrera C.¹²,Percy K. E.²,Loo J. A.²³,Yeates L. D.³,Vargas-Hernandez J.¹

Affiliation:

1. Colegio de Postgraduados, Montecillos , Mexico , CP56230

2. Natural Resources Canada , Canadian Forest Service – Atlantic Forestry Centre , P.O. Box 4000, Fredericton , NB, E3B 5P7 , Canada .

3. Faculty of Forestry and Environmental Management , P.O. Box 44555, 28 Dineen Dr., University of New Brunswick , Fredericton , NB, E3B 6C2 , Canada .

Abstract

Abstract Seedlings from each of 12 Pinus pinceana populations from throughout the species’ range in Mexico were evaluated in a common-garden test to (1) determine the level of genetic variation and genetic structure of epicuticular needle wax quantity, (2) examine differences in wax chemical composition, and (3) seek evidence for an adaptive response in wax composition and quantity across environmental and geographic gradients. Regions and populations within regions showed high variation (38.2% and 10.5%, respectively, of the total variation) in wax quantity. Epicuticular wax recovered from primary needles of P. pinceana comprised eight classes. Secondary alcohols (71.7%) were the major homologs identified by gas chromatography. Seedlings from the northern region were separated based on wax composition from seedlings from the central and southern regions by canonical discriminant analysis. A strong differentiation among regions (QSTR =0.571) and populations within regions (QSTP(R) =0.384) was observed for wax quantity. Data on wax quantity and chemical composition indicate that physicochemical characteristics of epicuticular wax may show adaptation of P. pinceana to local environments.

Publisher

Walter de Gruyter GmbH

Subject

Genetics,Forestry

Reference29 articles.

1. Baker, E. A. (1982): Chemistry and morphology of plant epicuticular waxes, pp. 139–166. In: The plant cuticle, edited by D. F. Cutler, K. L. Alvin and C. E. Price, Academic Press, London, UK.

2. Beatley, C. J. (1974): Effects of rainfall and temperature on the distribution and behavior of Larrea tridentata (creosote bush) in the Mojave desert of Nevada. Ecology 55: 245–261.

3. Bytnerowicz, A., K. Percy, G. Tiechers, P. Padget and M. Krywalt (1998): Nitric acid vapor effects on forest trees-deposition and cuticular changes. Chemosphere 36: 697–702.

4. Cape, J. N. and K. E. Percy (1993): Environmental influences on the development of spruce needle cuticles. New Phytologist 125: 787–799.

5. Cape, J. N. and K. E. Percy (1996): The interpretation of leaf drying curves. Plant Cell Environment 19: 356–361.

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