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CROP BREEDING & GENETICS

Combining Maize Base Germplasm for Cold Tolerance Breeding

Misión Biológica de Galicia, Consejo Superior de Investigaciones Científicas (CSIC), Apartado 28, E-36080 Pontevedra, Spain. Research was supported by the Spanish National Plan for Research and Development (AGF01-3946 and AGF2004-06776), the Autonomous Government of Galicia (PGIDIT04RAG403006PR), and the Excma. Diputación Provincial de Pontevedra. V.M. Rodríguez and G. Sandoya acknowledge their fellowships from the Ministry of Science and Technology from Spain

^* Corresponding author (previlla{at}mbg.cesga.es).

Early planting can contribute to increased grain yield of maize (Zea mays L.), but it requires cold tolerance. A limited number of cold-tolerant maize genotypes have been reported. The objectives of this study were to test a new strategy to improve cold tolerance in maize searching for broad x narrow genetic combinations that may be useful as base populations for breeding programs, to compare genotype performance under cold-controlled and field conditions, and to establish the major genetic effects involved in crosses between cold-tolerant inbred lines and populations. Nine cold-tolerant populations were crossed to five inbred lines and evaluated in a cold chamber and in the field. Most inbred line x population crosses performed better than populations per se or hybrids used as checks, both in the cold chamber and in the field, suggesting that broad x narrow genetic combination could be a suitable start point for further breeding programs for cold tolerance. The crosses between the inbred line EP80 and northwestern Spanish populations are the most promising base germplasm. In particular, EP80 x Puenteareas showed the greatest yield and good performance at the first stages of development under cold conditions. In addition, EP80 and Puenteareas showed favorable general combining ability for most traits. Early vigor rating would be the most suitable trait to select maize genotypes with superior cold tolerance during emergence and postemergence stages, because it was the only trait for which differences among genotypes were observed in both the cold chamber and the field. Although evaluation under controlled conditions is essential to test cold tolerance, field evaluations are complementary because no association was found between traits evaluated in both conditions.

Abbreviations: GCA, general combining ability • SCA, specific combining ability

This article has been cited by other articles:

				V. M. Rodriguez, R. A. Malvar, A. Butron, A. Ordas, and P. Revilla Maize Populations as Sources of Favorable Alleles to Improve Cold-Tolerant Hybrids Crop Sci., September 1, 2007; 47(5): 1779 - 1786. [Abstract] [Full Text] [PDF]