Effect of photosynthetic resource restriction on grain yield and other agronomic characteristics of cultivars and advanced barley lines under water deficit conditions

Fatemi, Roghayeh; Yarnia, Mehrdad; Mohammadi, Soleman; Khalil Vand, Ebrahim; Mirashkari, Bahram

doi:10.22077/escs.2021.4059.1960

Document Type : Original Article

Authors

¹ Ph.D. Student, Department of Agronomy and Plant Breeding, Tabriz Branch, Islamic Azad University, Tabriz, Iran

² Associate Professor, Department of Agronomy and Plant Breeding, Tabriz Branch, Islamic Azad University, Tabriz, Iran

³ Assistant Professor, Seed and Plant Improvement Research Department, West Azerbaijan Agricultural and Natural Resources Research Center, AREEO, Urmia, Iran

https://doi.org/10.22077/escs.2021.4059.1960

Abstract

Introduction
Barley (Hordeum vulgare L.) is a widely cultivated cereal crop in many rainfed areas in the Mediterranean region where drought is considered the main yield-limiting factor. In such marginal lands, yield losses are associated with drought conditions resulting from low and inconsistent precipitation during the whole plant growth cycle, either early in the fall or winter (initial drought conditions) or late during spring (terminal drought). Drought stress reduces grain yield of barley by negatively affecting the yield components i.e., number of plants per unit area, number of spikes and grains per plant or unit area and single grain weight, which are determined at different stages of plant development.
Materials and methods
In order to investigate the effect of sources limitation on yield and physiological characteristics in barley cultivars and advanced lines in various environmental conditions, an experiment was done in the Agricultural and Natural Resources Research Station of Miandoab in cropping 2016-2017. In this study, 12 varieties and lines of barley were evaluated in five sources limitation treatments including control (without limitation), leaf removal under flag leaf, flag leaf removal, half spike removal and spike coating in normal irrigation and water deficit conditions were evaluated in a randomized complete block design with three replications. In this study spike weight, leaf weight, peduncle weight, internode weight, seed number per spike, total plant weight and single plant yield were measured. Analysis of variance was performed using the SAS9.4 and SPSS programs.
Result and discussion
The results of the combined analysis of variance showed that the effect of year on leaf weight and seed yield was significant at the level of 0.01. There was a significant difference between irrigation levels on all studied traits at the level of 0.01, the interaction effect of year in irrigation was also significant on all traits except total plant weight at the level of 0.01 probability. The effect of resource constraint, irrigation on resource constraint, genotype and the interaction of genotype on resource constraint were significant on all studied traits at the level of 0.01 probability. The interaction effect of year on resource constraint on leaf weight, peduncle weight, number of seeds per spike and seed weight was significant at 0.01 probability level. The interaction effect of year on genotype on total plant weight and number of seeds per spike was also significant. The interaction effect of irrigation in genotype was also significant on all traits at 0.01 probability level. Finally, the triple interaction of irrigation in source restriction in genotype on leaf weight and total plant weight was significant at the level of 0.01 and the number of seeds per spike and grain yield at the level of 0.05 probability was significant. Comparison of the mean of genotype with source restriction interaction treatments showed that most of the studied genotypes under normal irrigation conditions showed the lowest grain yield in treatments of flag leaf removal restriction, half spike target and spike cover, while under water deficit stress conditions, the lowest grain yield was recorded in the studied genotypes under the treatments of flag leaf removal and spike cover. Under normal irrigation conditions under control and removal under the flag leaf, genotypes No. 10, 2, 3, 4, 5, 6, 7, 8 and 12 had the highest grain yield and there was no significant difference between them. Under water deficit stress conditions, in the control treatment, all genotypes except genotype No. 11 and in flag removal treatment, all genotypes, except for genotypes No. 2 and 11, had higher yields compared to genotypes. Under normal irrigation conditions and Water-deficit stress in genotype 3, there was no significant difference between control treatment and resource limitation treatments of remove below the flag leaf, flag leaf removal and half spike removal. In this study, the studied advanced lines did not show a significant advantage over the released barley cultivars in terms of grain yield.
Conclution
It can be concluded that in this study, the studied advanced lines did not show a significant advantage over the released barley cultivars in terms of grain yield.

Keywords

20.1001.1.22287604.1401.15.3.2.0

Main Subjects

Breeding plants for stress conditions

References

Abbate, P.E., Andrade, F.H., Lazaro, L., Bariffi, J.H., Berardocco, H.G., Inza, V.H., Marturano, F., 1998. Grain yields increase in recent Argentine wheat cultivars. Crop Science. 38, 1203-1209.

Abdoli, A., Saeidi, M., Jalali-Honarmand, S., Mansourifar, S., Ghobadi, M.E., 2013. Effect of post-anthesis water deficiency on storage capacity and contribution of stem reserves to the growing grains of wheat cultivars. Plant Knowledge Journal. 2, 99-107.

Abdoli, M., Saeidi, M., 2012. Using different indices for selection of resistant wheat cultivars to post anthesis water deficit in the west of Iran. Annals of Biological Research. 3, 1322-1333.

Ahmadi, A., Joudi, M., Janmohammadi, M., 2009. Late defoliation and wheat yield: Little evidence of post- anthesis source limitation. Field Crops Research. 113, 90-93.

Ahrizad, S., Ahmadi, V., Mohammadi, S.A., 2010. Response of bread wheat recombinant inbred lines to drought stress and their grouping. Journal of Crop Ecophysiology. 4, 67-78. [In Persian with English summary].

Akash, M.W., Al-Abdallat, A.M., Saoub, H.M, Ayad, J.Y., 2009. Molecular and field comparison of selected barley cultivars for drought tolerance. New Seeds. 10, 98-111.

Alam, M.S., Rahman, A.H., Nesa, M.N., Khan, S.K., Siddquie, N.A., 2008. Effect of source and/or sink restriction on the grain yield in wheat. European Journal of Applied Science Research. 4, 258-261.

Amidzadeh, J., Naderi, N., Syadat, S.A., 2009. Assessment of sink limitation and relative shares of different photosynthetic organs of wheat in grain filling. Iranian Journal of Field Crops Research. 7, 555-562. [In Persian with English summary].

Ardalani, M., Saeidi, M., Jalali-Honarmand, S., Ghobadi, M., Abdoli, M., 2012. Evaluation of grain yield and its relationship with remobilization of dry matter in bread wheat cultivars under water deficit stress at the post anthesis. Iranian Dryland Agronomy Journal. 3(2), 173-195. [In Persian with English summary].

Azhand, M., Saeidi, M., Abdoli, M., Khas-Amiri, M., 2015. The impact of source limitations on yield formation, storage capacity and contribution of stem reserves to the growing grains of modern barley cultivars under post-anthesis water deficiency. Plant Knowledge Journal. 4, 13-24

Biscoe, P.V., Scott, R.K., Monteith, J.L., 1975. Barley and its environment. Part III: carbon budget of the stand. Applied Ecology. 12, 269- 291

Biswal, A. K., Kohli, A., 2013. Cereal flag leaf adaptations for grain yield under drought: knowledge status and gaps. Molecular Breeding. 31, 749-766.

Blum, A., Sinmena, J., Mayer, G., Shpiler, L., 1994. Stem reserve mobilisation supports wheat grain filling under heat stress. Australian Journal of Plant Physiology. 21, 771-781.

Bonnet, G.D., Incoll, L.D.,1992. The potential pre-anthesis and post-anthesis contributions of stem internodes to grain yield in crops of winter barley. Annals of Botany. 69, 219-225.

Ehdaie, B., Alloush, B. G.A., Madore, M. A., Waines, J. G., 2006. Genotypic variation for stem reserves and mobilization in wheat: I. Post anthesis changes in internode dry matter. Crop Science. 46, 735-746.

Ehdaiea, B., Alloushb, G.A., Wainesa, J.G., 2008. Genotypic variation in linear rate of grain growth and contribution of stem reserves to grain yield in wheat. Field Crops Research. 106, 34-43.

Emam, Y., Niknejad, M., 2011. An Introduction to the Physiology of Crop Yield. (2nd ed.). Shiraz University Press, Shiraz. [In Persian].

FAO. 2017. Statistical data. www. FAOSTAT. Org.

Golabadi, M., Golkar, P., Bahari, B., 2015. Remobilization assay of dry matter from different shoot organs under drought stress in wheat (Triticum aestivum L.). Agronomy Research. 13, 1202-1214.

Kazemi, H., Naderi, A., Lakzade, O., 2012. Study of effect of resources limitation on the grain yield and yield omponents of six spring wheat genotypes under optimum conditions. Agricultural Knowledge, 3(7), pp. 15-27. [In Persian with English summary].

Khaliq, I., Irshad, A., Ahsan, M., 2008. Awns and flag leaf contribution towards grain yield in spring wheat (Triticum aestivum L.). Cereal Research Communications. 36, 65-76.

Koocheki, A., 1994. Crop Production in Dry Region: Cereals, Legumes, Industrial and forage crops (Translated in Persian). Jihad Daneshghahi Mashhad Press. 202p.

Maddah Hoseini, Sh., Poustini, K., Ahmadi A., Tavakol Afshari, R., Rahimi, A., Tavakoli A. 2010. Role of ear photosynthesis and transpiration in sink size determination in barley. Electronic Journal of Crop Production. 3, 107-123. [In Persian with English summary].

Maydup, M.L., Antonietta, M., Guiamet, J.J., Graciano, C., Lpez, J., Tambussi, E.A., 2010. The contribution of ear photosynthesis to grain filling in bread wheat (Triticum aestivum L.). Field Crops Research. 119, 48-58.

Minchin, P.E.H., Thorpe, M.R., 1996. What determines carbon partitioning between competing sinks? Journal of Experimental Botany. 47, 1293-1296.

Mohammad Taheri, M., Ahmadi, A., Postini, K., 2010. Response of modern and old wheat cultivars improved to fit moderate, cold and warm climates of Iran to source strength reduction. Iranian Journal of Field Crop Science. 41, 271-280. [In Persian with English summary].

Mohavieh Assadi, N., Bijanzadeh, E., Behpouri A. 2020. Investigation on source size limitation and water stress effects on photosynthetic pigments, enzymatic activity and yield of barley cultivars (Hordeum vulgare L.) Environmental Stresses in Crop Sciences. 13, 357-369

Paknejad, F., Fatemi Rika, Z., Elkaee Dehno, M., 2017. Investigation end season drought effect on yield and yield components of ten barley (Hordeum vulgare L.) cultivars in Karaj region. Environmental Stresses in Crop Sciences, 10(3), pp. 391-401. [In Persian with English summary].

Saeedi, H., Moradi, F., Jalali Honarmand, S., 2011. Contribution of spike and Leaves photosynthesis and soluble stem carbohydrates remobilization in grain yield formation in two bread wheat cultivars under post-anthesis stress conditions. Seed and Plant Production. 1, 2-27. [In Persian with English summary].

Saeid, M., Ajand, M., 2015. Effects of source limitation and post anthesis water deficiency on grain yield and gas exchange of different barley cultivars. Journal of Crops Improvement. 16, 839-856. [In Persian with English summary].

Saeidi, M., Moradi, F., Ahmadi, A., Spehri, R., Najafian, G., Shabani, A., 2010. The effects of terminal water stress on physiological characteristics and sink- source relations in two bread wheat (Triticum aestivum L.) cultivars. Iranian Journal of Crop Sciences. 12, 392-408. [In Persian with English summary].

Sanchez, F.J., De-Andres, E.F., Tenorio, J.L., Ayerbe, L., 2003. Growth of epicotyls, turgor maintenance and osmotic adjustment in pea plants (Pisum sativum L.) subjected to water stress. Field Crops Research. 86, 81-90.

Schnyder, H., 1993. The role of carbohydrate storage and redistribution in the source-sink relation of wheat and barley during grain filling-a review. New phytology. 123, 233-245.

Tambussi, E.A., Bort, J., Guiamet, J.J., Nogues, S., Araus, J.L., 2007. The photosynthetic role of ears in C3 cereals: metabolism, water use efficiency and contribution to grain yield. Critical Review of Plant Science. 26, 1-16.

Yang, J., Zhang, J., Hung, Z., Zhu, Q., Wang, L., 2000. Remobilization of carbon reserves is improved by controlled soil drying during grain filling of wheat. Crop Science. 40, 1645-1655.

Yang, J., Zang, J., 2006. Grain filling of cereals under soil drying. New Phytologist. 169, 223-236.

Zhang, J., Chen, W., Dell. B., Vergauwen, R., Zhang, X., Mayer, J.E., Van den Ende, W., 2015. Wheat genotypic variation in dynamic fluxes of WSC components in different stem segments under drought during grain filling. Frontiers in Plant Science. 6, 1-11.

Zhu, G.X., Midmore, D.J., Radford, B.J., Yule, D.F., 2004. Effect of timing of defoliation on wheat (Triticum aestivum L.) in central Queensland. Field Crops Research. 88, 211-226.

Effect of photosynthetic resource restriction on grain yield and other agronomic characteristics of cultivars and advanced barley lines under water deficit conditions

References

References

Volume 15, Issue 3 Open Access PolicySeptember 2022Pages 581-593

Volume 15, Issue 3
Open Access Policy
September 2022
Pages 581-593