Phenotyping root system architecture of cotton (gossypium barbadense L.) grown under salinity
| dc.Affiliation | October University for modern sciences and Arts (MSA) | |
| dc.contributor.author | Mottaleb S.A. | |
| dc.contributor.author | Darwish E. | |
| dc.contributor.author | Mostafa M. | |
| dc.contributor.author | Safwat G. | |
| dc.contributor.other | Cairo University | |
| dc.contributor.other | Egypt; October University for Modern Sciences and Arts | |
| dc.contributor.other | Egypt; Agricultural Botany Department | |
| dc.contributor.other | Plant Physiology Division | |
| dc.contributor.other | Faculty of Agriculture | |
| dc.contributor.other | Cairo University | |
| dc.contributor.other | Egypt; Faculty of Biotechnology | |
| dc.contributor.other | October University for Modern Sciences and Arts | |
| dc.contributor.other | Egypt | |
| dc.date.accessioned | 2020-01-09T20:41:10Z | |
| dc.date.available | 2020-01-09T20:41:10Z | |
| dc.date.issued | 2017 | |
| dc.description | Scopus | |
| dc.description | MSA Google Scholar | |
| dc.description.abstract | Soil salinity causes an annual deep negative impact to the global agricultural economy. In this study, the effects of salinity on early seedling physiology of two Egyptian cotton (Gossypium barbadense L.) cultivars differing in their salinity tolerance were examined. Also the potential use of a low cost mini-rhizotron system to measure variation in root system architecture (RSA) traits existing in both cultivars was assessed. Salt tolerant cotton cultivar Giza 90 produced significantly higher root and shoot biomass, accumulated lower Na+/K+ ratio through a higher Na+ exclusion from both roots and leaves as well as synthesized higher proline contents compared to salt sensitive Giza 45 cultivar. Measuring RSA in mini-rhizotrons containing solid MS nutrient medium as substrate proved to be more precise and efficient than peat moss/sand mixture. We report superior values of main root growth rate, total root system size, main root length, higher number of lateral roots and average lateral root length in Giza 90 under salinity. Higher lateral root density and length together with higher root tissue tolerance of Na+ ions in Giza 90 give it an advantage to be used as donor genotype for desirable root traits to other elite cultivars. 2017 Walter de Gruyter GmbH. All rights reserved. | en_US |
| dc.identifier.doi | https://doi.org/10.1515/agri-2017-0014 | |
| dc.identifier.doi | PubMedID | |
| dc.identifier.issn | 5513677 | |
| dc.identifier.other | https://doi.org/10.1515/agri-2017-0014 | |
| dc.identifier.other | PubMedID | |
| dc.identifier.uri | https://t.ly/pywjE | |
| dc.language.iso | English | en_US |
| dc.publisher | Walter de Gruyter GmbH | en_US |
| dc.relation.ispartofseries | Agriculture | |
| dc.relation.ispartofseries | 63 | |
| dc.subject | October University for Modern Sciences and Arts | |
| dc.subject | جامعة أكتوبر للعلوم الحديثة والآداب | |
| dc.subject | University of Modern Sciences and Arts | |
| dc.subject | MSA University | |
| dc.subject | Gossypium barbadense L | en_US |
| dc.subject | Phenotyping | en_US |
| dc.subject | Root system architecture | en_US |
| dc.subject | Salinity stress | en_US |
| dc.subject | cotton | en_US |
| dc.subject | cultivar | en_US |
| dc.subject | genotype | en_US |
| dc.subject | growth rate | en_US |
| dc.subject | phenotype | en_US |
| dc.subject | root architecture | en_US |
| dc.subject | root system | en_US |
| dc.subject | salinity | en_US |
| dc.subject | salinity tolerance | en_US |
| dc.subject | seedling | en_US |
| dc.subject | Gossypium barbadense | en_US |
| dc.subject | Gossypium hirsutum | en_US |
| dc.title | Phenotyping root system architecture of cotton (gossypium barbadense L.) grown under salinity | en_US |
| dc.type | Article | en_US |
| dcterms.isReferencedBy | Aboukheir, E., Sheshshayee, M.S., Udayakumar, M., (2008) AAB International Conference on Resource Capture by Crops: Integrated Approach, , 14�16 September 2008, University of Nottingham at Sutton Bonington; Abul-Naas, A.A., Omran, M.S., Salt tolerance of seventeen cotton cultivars during germination and early seedling development (1974) Zeitschrift F�r Acker- Und Pflanzenbau, 140, pp. 229-236; Ahmed, F.M., Effect of saline water irrigation at different stages of growth on cotton plant (1994) Assiut Journal of Agricultural Sciences, 25, pp. 63-74; Armengaud, P., Zambaux, K., Hills, A., Sulpice, R., Pattison, R.J., Blatt, M.R., Amtmann, A., EZ-Rhizo: Integrated software for the fast and accurate measurement of root system architecture (2009) Plant Journal, 57, pp. 945-956; Ashour, N.I., Abd-El Hamid, A.E.H.M., Relative salt tolerance of egyptian cotton varieties during germination and early seedlings development (1970) Plant and Soil, 3, pp. 493-495; Basal, H., Bebeli, P., Smith, C.W., Thaxton, P., Root growth parameters of converted race stocks of upland cotton and two BC2F2 populations (2003) Crop Science, 43, pp. 1983-1988; Bates, L.S., Waldeen, R.P., Teare, I.D., Rapid determination of free proline for water-stress studies (1973) Plant and Soil, 39, pp. 205-207; Darwish, E., Mottaleb, S.A., Omara, M., Safwat, G., Effect of salt stress on root plasticity and expression of ion transporter genes in tomato plants (2016) International Journal of Botany and Research (IJBR), 6, pp. 13-26. , https://www.researchgate.net/profile/Heba_Ibrahim4/publication/299289414_EFFECT_OF_SALT_STRESS_ON_ROOT_PLASTICITY_AND_EXPRESSION_OF_ION_TRANSPORTER_GENES_IN_TOMATO_PLANTS/links/570d581a08ae2b772e43200e/EFFECT-OF-SALT-STRESS-ON-ROOT-PLASTICITY-AND-EXPRESSION-OF-ION-TRANSPORTER-GENES-IN-TOMATO-PLANTS.pdf; Davenport, R.J., Munoz-Mayor, A., Jha, D., Es-Sah, P.A., Rus, A., Tester, M., The Na+ transporter AtHKT1;1 controls retrieval of Na+ from the xylem in arabidopsis (2007) Plant, Cell and Environment, 30, pp. 497-507; Devienne-Barret, F., Richard-Molard, C., Chelle, M., Maury, O., Ney, B., Ara-rhizotron: An effective culture system to study simultaneously root and shoot development of arabidopsis (2006) Plant and Soil, 280, pp. 253-266; El-Kadi, D.A., Afiah, S.A., Aly, M.A., Badran, A.E., Bulked segregant analysis to develop molecular markers for salt tolerance in egyptian cotton (2006) Arab Journal of Biotechnology, 9, pp. 129-142. , https://www.researchgate.net/profile/Mohammed_Aly2/publication/228936120_Bulked_segregant_analysis_to_develop_molecular_markers_for_salt_tolerance_in_Egyp-tian_cotton/links/0c96052de7b9fcfc03000000.pdf; El-Zahab, A.A.A., Salt tolerance of eight egyptian cotton varieties. Part II. At the seedling stage (1971) Zeitschrift F�r Acker- Und Pflanzenbau, 133, pp. 308-314; Garciadeblas, B., Senn, M.E., Banuelos, M.A., Rodrguez-Navarro, A., Sodium transport and HKT transporters: The rice model (2003) Plant Journal, 34, pp. 788-801; Gorham, J., Lauchli, A., Leidi, E.O., Plant responses to salinity (2010) Physiology of Cotton, pp. 129-141. , STEWART, J.M. ? OOSTERHUIS, D.M. ? HEITHOLT, J.J. ? MAUNEY, J.R. Eds London: Springer; He, G., Shen, G., Pasapula, V., Luo, J., Ven-Kataramani, S., Qiu, X., Kuppu, S., Zhang, H., Ectopic expression of AtNHX1 in cotton (Gossypium hirsutum l.) increases proline content and enhances photosynthesis under salt stress conditions (2007) Journal of Cotton Science, 11, pp. 266-274. , http://www.cotton.org/journal/2007-11/4/upload/jcs11-266.pdf; Julkowska, M.M., Testerink, C., Tuning plant signaling and growth to survive salt (2015) Trends in Plant Science, 20, pp. 586-594. , http://dx.doi.org/10.1016/j.tplants.2015.06.008; Karley, A.J., Leigh, R.A., Sanders, D., Differential ion accumulation and ion fluxes in the mesophyll and epidermis of barley (2000) Plant Physiology, 122, pp. 835-844; Munns, R., Tester, M., Mechanisms of salinity tolerance (2008) Annual Review of Plant Biology, 59, pp. 651-681; Murashige, T., Skoog, F., A revised medium for rapid growth and bio assays with tobacco tissue cultures (1962) Physiologiae Plantarum, 15, pp. 473-497; Oosterhuis, D.M., Wullschleger, S.D., Drought tolerance and osmotic adjustment of various crops in response to water stress (1988) Arkansas Farm Research, 37, p. 12; Pace, P.F., Cralle, H.T., El-Halawany, S.H., Co-Thren, J.T., Senseman, S.A., Drought-induced changes in shoot and root growth of young cotton plants (1999) Journal of Cotton Science, 3, pp. 183-187. , https://www.cotton.org/journal/1999-03/4/upload/jcs03-183.pdf, accessed 23 July 2016; Qadir, M., Quill�rou, E., Nangia, V., Murtaza, G., Singh, M., Thomas, R.J., Drechsel, P., Noble, A.D., Economics of salt-induced land degradation and restoration (2014) Natural Resources Forum, 38, pp. 282-295; Quisenberry, J.E., Jordan, W.R., Roark, B.A., Fryrear, D.W., Exotic cottons as genetic sources for drought resistance (1981) Crop Science, 21, pp. 889-895; Quisenberry, J.E., Roark, B.A., McMichael, B.L., Use of transpiration decline curves to identify drought-tolerant cotton germplasm (1982) Crop Science, 22, pp. 918-922; Roy, S.J., Negr�o, S., Tester, M., Salt resistant crop plants (2014) Current Opinion in Biotechnology, 26, pp. 115-124; Shabala, S., Cuin, T.A., Potassium transport and plant salt tolerance (2008) Physiologiae Plantarum, 133, pp. 651-669; Shabala, S., Munns, R., Salinity stress: Physiological constraints and adaptive mechanisms (2012) Plant Stress Physiology, pp. 59-93. , SHABALA, S. (Ed.) Oxfod: CAB International; Sinclair, T.R., Ludlow, M.M., Who taught plants thermodynamics? The unfulfilled potential of plant water potential (1985) Australian Journal of Plant Physiology, 12, pp. 213-218; Steele, K.A., Price, A.H., Witcombe, J.R., Shres-Tha, R., Singh, B.N., Gibbons, J.M., Virk, D.S., QTLs associated with root traits increase yield in upland rice when transferred through marker-assisted selection (2013) Theoretical and Applied Genetics, 126, pp. 101-108; Taylor, H.M., Upchurch, D.R., Brown, J.M., Rogers, H.H., Some methods of root investigation (1991) Plant Roots and Their Environment, pp. 553-564. , McMICHAEL, B.L. ? PERSSON, H. Eds New York: Elsevier Science Publishers, Inc; Tuberosa, R., Sanguineti, M.C., Landi, P., Giuliani, M.M., Salvi, S., Conti, S., Identification of QTLs for root characteristics in maize grown in hydroponics and analysis of their overlap with QTLs for grain yield in the field at two water regimes (2002) Plant Molecular Biology, 48, pp. 697-712; Udayakumar, M., Rao, R.C.N., Wright, G.C., Ra-Maswamy, G.C., Ashok, R.S., Gangadhar, G.C., Aftab Hussain, I.S., Measurement of transpiration efficiency in field conditions (1998) Journal of Plant Physiology and Biochemistry, 1, pp. 69-75; Uga, Y., Sugimoto, K., Ogawa, S., Rane, J., Ishi-Tani, M., Hara, N., Kitomi, Y., Inoue, H., Control of root system architecture by DEEPER ROOTING 1 increases rice yield under drought conditions (2013) Nature Genetics, 45, pp. 1097-1102; Weatherly, P.E., Studies in the water relations of the cotton plant. The field measurement of water deficits in leaves (1950) New Phytologist, 49, pp. 81-97; Zhong, H., Lauchli, A., Spatial and temporal aspects of growth in the primary root of cotton seedlings: Effects of NaCl and CaCl2 (1993) Journal of experimental botany, 44, pp. 763-771. , April 24, 2017 | |
| dcterms.source | Scopus |