Yield stability of durum wheat (Triticum durum desf.) in the region of the plains with petrocalcic subsoil layer of La Pampa province

  • M. A. Fernández Universidad Nacional de La Pampa, Facultad de Agronomía, Cátedra de Cultivos II

Keywords:

durum wheat, yield stability, genotype by environment interaction

Abstract

The objective of this work was to analyze the grain yield of durum wheat (Triticum durum Desf.) and its stability in the plains region, with petrocalcic subsoil layer, of La Pampa, Argentina. Five genotypes of durum wheat and two controls (bread wheat and triticale) were used during fíve growing seasons. Variability in grain yield was contributed in similar proportions by the environment, the genotype and the genotype x environment interaction. Variability of yield for some genotypes could be explained by the rainfall in October; however, winter-spring freezes should be taken into account in other cases. Triticale variety Eronga 83 showed the highest yield in all the environmental conditions. Durum wheats varieties Buck Crista and Bonaerense INTA Cumenay presented good stability with intermediate yield, while the bread wheat variety Buck Guaraní showed a significant instability. Eronga 83 was the only variety showing a preponderant yield component: the number of grains per spike. The results showed that high yields and stability are not mutually excluding. In conclusion, there are some non-traditional winter cereal genotypes for the plains region that could allow farmers to increase production, stability and diversity.

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References

Acevedo, E. & S. Ceccarelli. 1989. Role oí physiologist-breeder in a breeding program for drought resistance conditions, en: Drought resistance in cereals. (F.W.G. Baker ed.). CAB International, Waliingford, UK. pp. 117-139.

Annicchiarico, P. 1997. Joint regression vsAMMI analysis of genotypeenvironment interactions for cereals in Italy. Euphytica 94: 53-62.

Araus. J.L.; G. A. Slafer, M.P. Reynolds & C. Royo. 2002. Plant breeding and drought in C3 cereals: what should we breed for? Ann. Bot. 89: 925-940.

Balzarini, M.; C. Bruno & A. Arroyo.2005. Análisis de ensayos agrícolas multi-ambientales. Ejemplos con Info-Gen. Ed. Brujas, Córdoba, Arg. 141 p.

Becker, H.C. & J. León.1988. Stability analysis in plant breeding. Plant Breeding. 101: 1-23.

Bell, M.A. & R.A. Fischer.1994. Guide to plant and crop sampling: measurements and observations for agronomic and physiological research in small grain cereals. Wheat Special Report 32. CIMMYT, D.F., México.66 p.

Bilbro, J.D. & L.L. Ray. 1976. Environmental stability and adaptation of severa I cotton cuiltivars. Crop Sei. 16:821-825.

Bozzini, A. 1988. Origin, distribution and production of durum vi/heat in the world, en: Durum wheat: chemistry and technology. (G. Fabriani. & C. Lintas eds.). Am. Assoc. Cereal Chemist Inc.. St. Paul, Min. EEUU. pp.1-16.

Calviño P.A. & V.O. Sadrás. 2002. Onfarm assessment of constraints to wheat yield in the south eastern Pampas. Field Crops Res. 74:1-11.

Campos, P.E. 2004. Diferencias en la población patógena de Puccinia triticina que afecta al los cultivos de trigo pan (Triticum aestivum) y trigo candeal (Triticum turgidum var durum), en: Actas VI Cong. Nac. Trigo. Bahía Blanca, Arg. pp.199-200.

Cooper, M.¡ R.E. Stucker; I.H. DeLacy & B.D. Harch. 1997. Wheat breeding nurseries, target environments, and indirect selection for grain yield. Crop Sci. 37: 1168-1176.

Crossa, J. 1990. Statistical analyses of multilocations trials. Adv. Agron. 44:55-85.

Crossa, J.; H.G. Gauch & R.W. Zobel. 1990. Additive main effects and multiplicative interaction analysis of two international maize eultivar trials. Crop Sei. 30: 493-500.

Eberhart, S.A. & W.A. Russell. 1966. Stability parameters for comparing varieties. Crop Sci. 6:36-40.

Evans, L.T. 1993. Crop evolution, adaptation and yield. Cambridge Univ. Press, New York, EEUU. 545 p.

Evans, L.T. & I.F. Wardlaw. 1976. Aspects of the comparative physiology of grain yield in cereals. Adv. Agron. 28: 301-359.

Fagioli, M. & A. Bono. 1984. Relaciones entre lluvia y rendimiento del trigo en la región semiárida pampeana. INTA EEA-Anguil. Carpeta de Inf. Tée. Serie Ecología:19-20.

Fagioli, M.; A. Bono & H.E. Torroba Gentilini. 1982. Productividad de los cultivos de trigo en la región semiárida pampeana. INTA EEA-Anguil. Pub. Tée. 24. 9 pp.

Felielo, J.C.; CE. de O. Camargo; A. W.P Ferreira Filho & P.B. Gallo. 2001. Avaliaçâo de genotipos de triticate e trigo em ambientes favoráveis e desfavoráveis no estado de Sao Paulo. Bragantia 60: 83-91.

Felieio, J.C.; CE. de O. Camargo; J.C V.N.A. Pereira; N. Bortoletto; P. B. Gallo & A.W.P Ferreira Filho. 2005. Adaptaçâo, estabilidade e potencial productivo de genotipos de Triticum durumL., irrigados por aspersäo no estado de Sao Paulo. Bragantia 64: 377-387.

Finlay. K.W. & G.N. Wilkinson. 1963. The analysis of adaptation in plant-breeding programme. Aust. J. Agrie. Res. 14: 742-754.

Fischer R. A. 1975. Yield potential in a dwarf spring wheat and the effect of shading. Crop Sci. 15: 607-613.

Fischer R. A. 1985. Number of kernels in wheat crops and the influence of solar radiation and temperature. J. Agrie. Sci. 105: 447-461.

Fowler. D.B. & I.A. de la Roche. 1975. Wheat quality evaluation. III. Influence of genotype and environment. Can. J.

Plant. Sci. 55: 263-269.

Franeis, T.R. & L.W. Kannenberg. 1978. Yield stability studies in short-season maize. 1. A descriptive method for grouping genotypes. Can J. Plant Sci. 58: 1029-1034.

Hede, A.R. 2000. A new approach to triticale improvement, en: Research highlight of the CIMMYT wheat program, 1999-2000. p. 21-26.e

INDEC. 2002. Encuesta Nacional Agropecuaria. 2001. Inf. Prensa. ISSN 0327-7968. Bs. As., Arg. 15 p.

Kang. M.S. 1998. Using genotype-by environment interaction for crop cultivar development. Adv. Agron. 62:199-252.

Kirigwi, F.M.; M. van Ginkel; R. Trethowan; R.G. Sears; S. Rajaman &G.M. Pauisen. 2004. Evaluation of selection strategies for wheat adaptation across water regimes. Euphytica 135: 361-371.

Lamadji, S.; A. G. Fautrier; D. L. McNeil & J.R. Sedeóle. 1995. Proposed breeding strategy for yield improvement of hexaploid triticale (x tritieosecale Wittmack) 1. Genetic variability and phenotypic stability. N. Z. J. Crop Hort. Sci. 23:1-11.

Lin, C.S. & M.R. Binns. 1989. Comparison of unpredictable environmental variation generated by year and by seeding-time factors for measuring type 4 stability. Theor. Appl. Genet. 78:61-64.

Lin, C.S. & M.R. Binns. 1994. Concepts and methods for analysis regional triai data for cultivar and location selection. Plan Breed. Rev. 11: 271-297.

Lin, C.S.; M.R. Binns & L.P Lefkoviteh. 1986. Stability analysis: where do we stand?. Crop Sci. 26: 894-900.

Loomis, R.S. & D.J. Connor. 2002. Eeologia de eultivos. Productividad y manejo en sistemas agrarios. Ed. MundiPrensa, Madrid, Esp. 591 p.

Lorda, H.; Y. Bellini Saibene; A. Sipowicz; R. Colazo; Z. Roberto; J. Sarasola & P Lucehetti. 2001. Resultados de la encuesta agrícola 1999. I. Región pampeana del proyecto RADAR, en: EEA INTA-Anguil, Bol. Div. Téc. N^ 1. 50p.

Miranda. R. & A.J. Junquera. 1994. Rendimiento de trigo y precipitaciones, en: Actas III Congreso Nacional de Trigo. Bahía Blanca, Arg.

Mishra, R.; R S. Baenziger; W. K. Russell; R. A. Graybosch; D. D. Baltensperger & K. M. Eskridge. 2006. Crossover interactions for grain yield in multienvironmental trials of winter wheat. Crop Sci. 46:1291-1298.

Okuyama, L.A.; L.C. Federizzi & J.F. Barbosa Neto. 2005. Grain yield stability of wheat genotypes under irrigated and non irrigated conditions. Braz. Arch. Bioi. Tech. 48: 697-704.

Pimente! Gomes, F. 1978. Curso de estadística expérimental. Ed. Hemisferio Sur, Bs. As., Arg. 323 p.

Reynolds, M.P.; R. Trethowan; J. Crosa; M. Vargas & K.D. Sayre. 2004. Physiological factors associated with genotype by environment interaction in wheat. Field Crops Res. 85: 253-274.

Rizza, F.; F.W. Badeck; L. Cattivellí; O. Lidestri; N. Di Fonzo & A.M. Stanca. 2004. Use of a water stress index to identify barley genotypes adapted to rainfed and irrigated conditions. Crop Sei. 44: 2127-2137.

Rosielle, A. A. & J. Hamblin. 1981. The oretical aspects of selection for yield in stress and non-stress environment. Crop Sci. 21:943-946.

Shukla, G.K. 1972. Some statistical aspects of partitioning genotypeenviroment components of variability. Heredity 29-237-245.

Steel, R.G.D. & J.H. Torrie. 1989. Bioestadistica: principios y procedimientos. Ed. Me Graw-Hill/Interamericana, D. F. México. 514 p.

Tollenaar, M. & E.A. Lee. 2002. Yield potential, yield stability and stress tolerance in maize. Field Crops Res. 75:161-169.

Travasso, M.Y.; R. Delecolle & Y.C.H. Baldi. 1994. Principales factores agro-climáticos determinantes del rendimiento de trigo en el sur Bonaerense. RIA. 25: 33-40.

Troyer, A.F. 1996. Breeding for widely adapted popular maize hybrids. Euphytica 92: 163-174.

van Ginkel, M.; D.S. Calhoun; G. Gebeyehu; A. Miranda; C. Tian-you; R. Pargas Lara; R. M. Trethowan; K. Sayre; J. Crossa & S. Rajaram. 1998. Plant traits related to yield of wheat in early, late, or continuous drought conditions. Euphytica 100: 109-121.

Vega, U.A. 1992. Asociación entre el rendimiento promedio, respuesta de producción y estabilidad de la producción de maíz y trigo. Rev. Fac. Agron. (Maracay) 18: 387-396.

Vergara, G.T. & G.A. Casagrande. 2002. Estadísticas agroclimáticas de la Facultad de Agronomía, Santa Rosa, La Pampa, Argentina. Rev. Fac. Agron. UNLPam. 13:1-70.

Verón. S.R.; J.M. Paruelo; O.E. Sala & W.K. Lauenroth. 2002. Environmental controls of primary production in agricultural systems of the Argentine Pampas. Ecosystems 5: 625-635.

Walsh, E. J. 1984. Developing yield potential of oereals. en: Cereal Production. (E.J. Gallagher ed.). Butterworths, London, Ing. p. 69-93.

Westcott, B. 1987. A method of assessing the yield stability of crop genotypes. J. Agrie. Sci. Camb. 108: 267-274.

Wricke G. 1962. über eine méthode zur Erfussung der ökologischen Streubreite in Feldversuchen. Z. flanzenzuecht. 47:92-96.

Yan, W. & L.A. Hunt. 1998. Genotype by environment interaction and crop yield. Plant Breed. Rev. 16:135-178.

Yan, W. & L.A. Hunt. 2001. Interpretation of genotype x environmental interaction for winter wheat yield in Ontario. Crop Sci. 41:19-25.

Yan, W. & L. A. Hunt. 2002. Biplot análisis of diallel data. Crop Sci. 42:21-30.

Yan, W.; L.A. Hunt; Q. Sheng & Z. Szlavnies. 2000. Cultivar evaluation and mega-environment investigation based on GGE biplot. Crop Sci. 40: 597-605.

Zadoks, J.C.; T.T. Chang & C.F. Konzak. 1974. A decimal eode for the growth stages of cereals. Weed Res. 14: 415-421.

Zapata C; P Silva & E. Acevedo. 2004. Comportamiento de isolíneas de altura en relación con el rendimiento y la distribución de asimilados en trigo. Agrie. Téc. (Chile) 64: 139-155.

Zobel, R.W., M.J. Wright & H.G. Gauch. 1988. Statistical analysis of yield trial. Agron. J. 80: 388-393.

Published

2020-04-03

How to Cite

Fernández, M. A. (2020). Yield stability of durum wheat (Triticum durum desf.) in the region of the plains with petrocalcic subsoil layer of La Pampa province. Semiárida, 19, 41–62. Retrieved from https://cerac.unlpam.edu.ar/index.php/semiarida/article/view/4575

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Artículos Científicos y Técnicos