Response of barley genotypes to terminal soil moisture stress: phenology, growth, and yield
Agueda González A C , Isaura Martín B and Luis Ayerbe BA Servicio de Investigación Agraria, CAM, Apdo. 127, 28800 Alcalá de Henares, Spain.
B Centro de Recursos Fitogenéticos, INIA, Apdo. 1045, 28800 Alcalá de Henares, Spain.
C Corresponding author. Email: agueda.gonzales@madrid.org
Australian Journal of Agricultural Research 58(1) 29-37 https://doi.org/10.1071/AR06026
Submitted: 26 January 2006 Accepted: 6 October 2006 Published: 2 January 2007
Abstract
Terminal drought is the main factor limiting the yield of cereals in the central area of Spain because rainfall is scarce and temperatures are high during the grain-filling period. The response of 12 cultivated barley (Hordeum vulgare L.) genotypes consisting of 6 breeding lines showing high yield under terminal water stress and 6 commercial varieties was studied in a rain shelter. Trials were performed over 3 years to determine the influence of terminal water stress on yield and yield components and the relationship between yield and phenological and agronomic traits. When the crop reached the flag-leaf stage, half of the experimental plots were subjected to a water-stress treatment and the remainder were maintained at optimal water conditions. Variations were observed in number of days to ear emergence, days to maturity, and length of grain-filling period. Precocity strongly influenced the length of the grain-filling period so that the earlier genotypes had the longest grain-filling periods. Among yield components, mean grain weight had the greatest influence on yield under terminal water stress conditions. Earliness and length of grain-filling period were the phenological traits that most influenced yield in water stress conditions. These traits and harvest index (HI) showed a significant correlation (P < 0.001) with grain yield. Earliness, mean grain weight, and HI contributed to greater yields under terminal water stress.
Additional keywords: barley, water stress, grain-filling duration, yield components, precocity.
Acknowledgments
We kindly thank CIMMYT and ICARDA for providing various valuable breeding lines for the development of this research. This work was supported by the Instituto Nacional de Investigación Agaria (INIA) of Spain, SC95-085-C06-06 Project.
Acevedo E,
Craufurd PQ,
Austin RB, Pérez-Marco P
(1991) Traits associated with high yield in barley in low-rainfall environments. Journal of Agricultural Science 116, 23–36.
Annicchiarico P, Pecetti L
(1995) Morpho-physiological traits to complement grain yield selection under semi-arid Mediterranean conditions in each of the durum wheat types mediterraneum typicum and syriacum. Euphytica 86, 191–198.
| Crossref | GoogleScholarGoogle Scholar |
Bidinger F,
Musgrave RB, Fischer RA
(1977) Contribution of stored pre-anthesis assimílate to grain yield in wheat and barley. Nature 270, 431–433.
| Crossref | GoogleScholarGoogle Scholar |
Bidinger FR,
Mahalakshmi V, Rao GDP
(1987) Assessment of drought resistance in pearl millet [Pennisetum americanum (L.) Leeke]. I Factors affecting yields under stress. Australian Journal of Agricultural Research 38, 37–48.
| Crossref | GoogleScholarGoogle Scholar |
Bindraban PS,
Sayre KD, Solis-Moya E
(1998) Identifying factors that determine kernel number in wheat. Field Crops Research 58, 223–234.
| Crossref | GoogleScholarGoogle Scholar |
Bruckner PL, Frohberg RC
(1987) Rate and duration of grain fill in spring wheat. Crop Science 27, 451–455.
Cantero-Martínez C,
Villar JM,
Romagosa I, Fereres E
(1995) Growth and yield responses of two contrasting barley cultivars in a Mediterranean environment. European Journal of Agronomy 4, 317–326.
Christen O,
Sieling K,
Richter-Harder H, Hanus H
(1995) Effects of temporary water stress before anthesis on growth, development and grain yield of spring wheat. European Journal of Agronomy 4, 27–36.
Cooper M,
Byth DE, Woodruff DR
(1994) An investigation of the grain yield adaptation of advanced CIMMYT wheat lines to water stress environments in Queensland. I. Crop physiological analysis. Australian Journal of Agricultural Research 45, 965–984.
| Crossref | GoogleScholarGoogle Scholar |
Duggan BL,
Domitruk D, Fowler DB
(2000) Yield component variation in winter wheat grown under drought stress. Canadian Journal of Plant Science 80, 739–745.
Fischer RA, Kohn GD
(1966) The relationship of grain yield to vegetative growth and post-flowering leaf area in the wheat crop under conditions of limited soil moisture. Australian Journal of Agricultural Research 17, 281–295.
| Crossref | GoogleScholarGoogle Scholar |
García del Moral LF,
Ramos JM,
García del Moral MB, Jiménez-Tejada MP
(1991) Ontogenetic approach to grain production in spring barley based on path-coefficient analysis. Crop Science 31, 1179–1185.
Gibson LR, Paulsen GM
(1999) Yield components of wheat grown under high temperature stress during reproductive growth. Crop Science 39, 1841–1846.
Giunta F,
Motzo R, Deidda M
(1993) Effect of drought on yield and yield components of durum wheat and triticale in a Mediterranean environment. Field Crops Research 33, 399–409.
| Crossref | GoogleScholarGoogle Scholar |
Kirby EJM, Riggs TJ
(1978) Developmental consequences of two-row and six-row ear type in spring barley. 2. Shoot apex, leaf and tiller development. Journal of Agricultural Science 91, 207–216.
López-Castañeda C, Richards RA
(1994) Variation in temperate cereals in rainfed environments. I. Grain yield, biomass and agronomic characteristics. Field Crops Research 37, 51–62.
| Crossref | GoogleScholarGoogle Scholar |
Loss SP, Siddique KHM
(1994) Morphological and physiological traits associated with wheat yield increases in Mediterranean environments. Advances in Agronomy 52, 229–276.
McMaster GS,
Wilhelm WW, Bartling PNS
(1994) Irrigation and culm contribution to yield and yield components of winter wheat. Agronomy Journal 86, 1123–1127.
Mitchell JH,
Fukai S, Cooper M
(1996) Influence of phenology on grain yield variation among barley cultivars grown under terminal drought. Australian Journal of Agricultural Research 47, 757–774.
| Crossref | GoogleScholarGoogle Scholar |
Mogensen VO,
Jensen HE, Rab A
(1985) Grain yield, yield components, drought sensitivity and water use efficiency of spring wheat subjected to water stress at various growth stages. Irrigation Science 6, 131–140.
| Crossref | GoogleScholarGoogle Scholar |
van Oosterom EJ,
Ceccarelli S, Peacock JM
(1993) Yield response of barley to rainfall and temperature in Mediterranean environments. Journal of Agricultural Science 121, 307–313.
Reynolds MP,
Trethowan R,
Crossa J,
Vargas M, Sayre KD
(2002) Physiological factors associated with genotype by environment interaction in wheat. Field Crops Research 75, 139–160.
| Crossref | GoogleScholarGoogle Scholar |
Richards RA,
Rebetzke GJ,
Condon AG, van Herwaarden AF
(2002) Breeding opportunities for increasing the efficiency of water use and crop yield in temperate cereals. Crop Science 42, 111–121.
| PubMed |
Saini HS, Westgate ME
(2000) Reproductive development in grain crops during drought. Advances in Agronomy 68, 59–96.
Siddique KHM,
Kirby EJM, Perry MW
(1989) Ear : Stem ratio in old and modern wheat varieties; relationship with improvement in number of grains per ear and yield. Field Crops Research 21, 59–87.
| Crossref | GoogleScholarGoogle Scholar |
Talbert LE,
Lanning SP,
Murphy RL, Martin JM
(2001) Grain fill duration in twelve hard red spring wheat crosses: genetic variation and association with other agronomic traits. Crop Science 41, 1390–1395.
Turner NC
(1997) Further progress in crop water relations. Advances in Agronomy 58, 293–338.
Van Ginkel M,
Calhoun DS,
Gebeyehu G,
Miranda A,
Tian-you C,
Pargas Lara R,
Trethowan RM,
Sayre K,
Crossa J, Rajaram S
(1998) Plant traits related to yield of wheat in early, late, or continuous drought conditions. Euphytica 100, 109–121.
| Crossref | GoogleScholarGoogle Scholar |
Voltas J,
van Eeuwijk FA,
Sombrero A,
Lafarga A,
Igartua E, Romagosa I
(1999) Integrating statistical and ecophysiological analyses of genotype by environment interaction for grain filling of barley I. Individual grain weight. Field Crops Research 62, 63–74.
| Crossref | GoogleScholarGoogle Scholar |
Voltas J,
Romagosa I, Araus JL
(1997) Grain size and nitrogen accumulation in sink-reduced barley under Mediterranean conditions. Field Crops Research 52, 117–126.
| Crossref | GoogleScholarGoogle Scholar |
Voltas J,
Romagosa I, Araus JL
(1998) Growth and final weight of central and lateral barley grains under Mediterranean conditions as influenced by sink strength. Crop Science 38, 84–89.
Wang G,
Kang MS, Moreno O
(1999) Genetic analyses of grain-filling rate and duration in maize. Field Crops Research 61, 211–222.
| Crossref | GoogleScholarGoogle Scholar |
Zadoks JC,
Chang TT, Kozank CF
(1974) A decimal code for the growth stages of cereals. Weed Research 14, 415–421.
| Crossref | GoogleScholarGoogle Scholar |