Cold Tolerance in Two Large Maize Inbred Panels Adapted to European Climates

ABSTRACT Maize (Zea mays L.) for northern growing areas requires cold tolerance for extending the vegetative period. Our objectives were to evaluate two large panels of maize inbred lines adapted to Europe for cold tolerance and to estimate the effects of cold‐related traits on biomass production. T...

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Published inCrop science Vol. 54; no. 5; pp. 1981 - 1991
Main Authors Revilla, Pedro, Rodríguez, Víctor Manuel, Ordás, Amando, Rincent, Renaud, Charcosset, Alain, Giauffret, Catherine, Melchinger, Albrecht E., Schön, Chris‐Carolin, Bauer, Eva, Altmann, Thomas, Brunel, Dominique, Moreno‐González, Jesús, Campo, Laura, Ouzunova, Milena, Laborde, Jacques, Álvarez, Ángel, Ruíz de Galarreta, José Ignacio, Malvar, Rosa Ana
Format Journal Article
LanguageEnglish
Published Madison The Crop Science Society of America, Inc 01.09.2014
American Society of Agronomy
Crop Science Society of America
Subjects
Chlorophyll
Cold
Cold tolerance
Collections
Corn
Developmental stages
Dry matter
Genetic structure
Genomes
Germplasm
Growth chambers
Inbreeding
Life Sciences
Studies
Vegetal Biology
Vegetation
GENETIC-VARIATION
QUANTITATIVE TRAIT LOCI
FIELD
CHILLING TOLERANCE
GROWTH
CORN
INHERITANCE
LOW-TEMPERATURES
LINES
ZEA-MAYS-L
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Summary:ABSTRACT Maize (Zea mays L.) for northern growing areas requires cold tolerance for extending the vegetative period. Our objectives were to evaluate two large panels of maize inbred lines adapted to Europe for cold tolerance and to estimate the effects of cold‐related traits on biomass production. Two inbred panels were evaluated for cold tolerance per se and in testcrosses under cold and control conditions in a growth chamber and under field conditions. Comparisons of inbreds and groups of inbreds were made taking into account the single nucleotide polymorphisms (SNP)‐based genetic structure of the panels, and the factors affecting biomass production were studied. Eight flint and one dent inbred with diverse origins were the most cold tolerant. The most cold‐tolerant dent and flint groups were the Iodent Ph207 and the Northern Flint D171 groups, respectively. The relationships between inbred per se and testcross performance and between controlled and field conditions were low. Regressions with dry matter yield in the field as dependent variable identified plant height (R2 = 0.285) as the main independent variable, followed by quantum efficiency of photosystem II (R2 = 0.034) and other traits with minor contributions. Cold‐tolerance–related traits had low and negative effects on dry matter yield. Models intending the prediction of final performance from traits scored in early developmental stages are not expected to be precise enough for breeding. For improving cold tolerance, inbreds released from crosses among the No Iodent group and the Northern Flint group may show high combining ability, as well as between both groups and the Northern Flint D171 group.
Bibliography:All rights reserved. No part of this periodical may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, or any information storage and retrieval system, without permission in writing from the publisher. Permission for printing and for reprinting the material contained herein has been obtained by the publisher.
ISSN:0011-183X
1435-0653
DOI:10.2135/cropsci2013.11.0733