Abstract
Aims
Crop genotypes may respond differently to various physical soil conditions. The objective of this study was to investigate the responses of the root architectures of two maize cultivars (Zhengdan958 and Denghai605) to various soil compaction and moisture conditions.
Methods
Two compaction levels (1.3 g cm− 3 and 1.6 g cm− 3) and two moisture conditions (60% and 80% field capacity) were investigated to determine their impact on root growth. The root architectures of maize seedlings were assessed via X-ray computed tomography (CT). Soil penetration resistance, above-ground biomass and root biomass values were also determined.
Results
Soil moisture had significant effects on root biomass, above-ground biomass, the ratio of root biomass to above-ground biomass, and all root traits except for root volume. Soil compaction reduced root surface area and total root length of Zhengdan958 at 80% field capacity but not at 60% field capacity. However, soil compaction had little impact on root traits of Denghai605 at both moisture levels. Zhengdan958 had larger root volume, total root length, root diameter, root biomass and above-ground biomass than Denghai605 under noncompacted conditions. The ratio of root biomass to above-ground biomass was greater for Zhengdan958 than Denghai605 at the noncompacted and 60% field capacity conditions.
Conclusions
High moisture content has negative effects on root traits in compacted soil. The response of root architectures to soil compaction was more sensitive in Zhengdan958 than Denghai605. Zhengdan958 showed greater growth performance than Denghai605 under noncompacted conditions, and the drought tolerance of Zhengdan958 was greater than that of Denghai605.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Araki H, Iijima M (2005) Stable isotope analysis of water extraction from subsoil in upland rice (Oryza sativa L.) as affected by drought and soil compaction. Plant Soil 270:147–157
Asfaw A, Blair MW (2012) Quantitative trait loci for rooting pattern traits of common beans grown under drought stress versus non-stress conditions. Mol Breed 30:681–695
Barken LR, Bøsrresen T, Njøss A (1987) Effect of soil compaction by tractor traffic on soil structure, denitrification, and yield of wheat (Triticumaestivum L.). J Soil Sci 38:541–552
Batey T, McKenzie DC (2006) Soil compaction: identification directly in the field. Soil Use Manag 22:123–131
Bengough AG, McKenzie BM, Hallett PD, Valentine TA (2011) Root elongation, water stress, and mechanical impedance: a review of limiting stresses and beneficial root tip traits. J Exp Bot 62:59–68
Boone FR, Van der Werf HMG, Kroesbergen Β, Ten Hag BA, Boers A (1986) The effect of compaction of the arable layer in sandy soils on the growth of maize for silage. 1. Critical matric water potentials in relation to soil aeration and mechanical impedance. Neth J Agric Sci 34:155–171
Bottinelli N, Hallaire V, Goutal N, Bonnaud P, Ranger J (2014) Impact of heavy traffic on soil macroporosity of two silty forest soils: Initial effect and short-term recovery. Geoderma 217:10–17
Broughton S, Zhou G, Teakle NL, Matsuda R, Zhou M, O’Leary RA, Colmer TD, Li C (2015) Waterlogging tolerance is associated with root porosity in barley (Hordeum vulgare L.). Mol Breed 35
Chen YL, Palta J, Clements J, Buirchell B, Siddique KHM, Rengel Z (2014) Root architecture alteration of narrow-leafed lupin and wheat in response to soil compaction. Field Crop Res 165:61–70
Chen D, Chai S, McIntyre CL, Xue G-P (2018) Overexpression of a predominantly root-expressed NAC transcription factor in wheat roots enhances root length, biomass and drought tolerance. Plant Cell Rep 37:225–237
Colombi T, Walter A (2016) Root responses of triticale and soybean to soil compaction in the field are reproducible under controlled conditions. Funct Plant Biol 43:114–128
Colombi T, Braun S, Keller T, Walter A (2017) Artificial macropores attract crop roots and enhance plant productivity on compacted soils. Sci Total Environ 574:1283–1293
da Silva AP, Kay BD, Perfect E (1994) Characterization of the least limiting water range of soils. Soil Sci Soc Am J 58:1775–1781
Etana A, Larsbo M, Keller T, Arvidsson J, Schjonning P, Forkman J, Jarvis N (2013) Persistent subsoil compaction and its effects on preferential flow patterns in a loamy till soil. Geoderma 192:430–436
Fang H, Rong H, Hallett PD, Monney SJ, Zhang W, Zhou H, Peng X (2019) Impact of soil puddling intensity on the root system architecture of rice (Oryza sativa L.) seedlings. Soil Till Res 193:1–7
Fujikawa T, Miyazaki T (2005) Effects of bulk density on the gas diffusion coefficient in repacked and undisturbed soils. Soil Sci 170:892–901
Grzesiak S, Grzesiak MT, Hura T, Marcinska I, Rzepka A (2013) Changes in root system structure, leaf water potential and gas exchange of maize and triticale seedlings affected by soil compaction. Environ Exp Bot 88:2–10
Grzesiak MT, Ostrowska A, Hura K, Rut G, Janowiak F, Rzepka A, Hura T, Grzesiak S (2014) Interspecific differences in root architecture among maize and triticale genotypes grown under drought, waterlogging and soil compaction. Acta Physiol Plant 36:3249–3261
Gysi M, Ott A, Fluhler H (1999) Influence of single passes with high wheel load on a structured, unploughed sandy loam soil. Soil Till Res 52:141–151
Hamamoto S, Moldrup P, Kawamoto K, Komatsu T (2012) Organic matter fraction dependent model for predicting the gas diffusion coefficient in variably saturated soils. Vadose Zone J 11
Hamza MA, Anderson WK (2005) Soil compaction in cropping systems - A review of the nature, causes and possible solutions. Soil Till Res 82:121–145
Hartung W, Zhang J, Davies WJ (1994) Does abscisic acid play a stress physiological role in maize plants growing in heavily compacted soil? J Exp Bot 45:221–226
Ho MD, Rosas JC, Brown KM, Lynch JP (2005) Root architectural tradeoffs for water and phosphorus acquisition. Funct Plant Biol 32:737–748
Hund A, Ruta N, Liedgens M (2009) Rooting depth and water use efficiency of tropical maize inbred lines, differing in drought tolerance. Plant Soil 318:311–325
Hussain A, Black CR, Taylor IB, Roberts JA (2000) Does an antagonistic relationship between ABA and ethylene mediate shoot growth when tomato (Lycopersicon esculentum Mill.) plants encounter compacted soil? Plant Cell Environ 23:1217–1226
Imhoff S, Kay BD, da Silva AP, Hajabbasi MA (2010) Evaluating responses of maize (Zea mays L.) to soil physical conditions using a boundary line approach. Soil Till Res 106:303–310
Lambers H, Atkin OK, Millenaar FF (2002) Respiratory patterns in roots in relationto their functioning. In: Waisel Y, Eshel A, Kafkaki K (eds) Plant Roots: Hidden Half, 3rd edn. Marcel Dekker, Inc, New York, pp 521–552
Li R, Zeng Y, Xu J, Wang Q, Wu F, Cao M, Lan H, Liu Y, Lu Y (2015) Genetic variation for maize root architecture in response to drought stress at the seedling stage. Breed Sci 65:298–307
Lipiec J, Medvedev VV, Birkas M, Dumitru E, Lyndina TE, Rousseva S, Fulajtár E (2003) Effect of soil compaction on root growth and crop yield in Central and Eastern Europe. Int Agrophys 17:61–69
Ludlow MM, Muchow RC (1990) A critical evaluation of traits for improving crop yields in water-limited environments. Adv Agron 43:107–153
Lynch JP (2013) Steep, cheap and deep: an ideotype to optimize water and N acquisition by maize root systems. Ann Bot 112:347–357
Mace ES, Singh V, Van Oosterom EJ, Hammer GL, Hunt CH, Jordan DR (2012) QTL for nodal root angle in sorghum (Sorghum bicolor L. Moench) co-locate with QTL for traits associated with drought adaptation. Theor Appl Genet 124:97–109
Mairhofer S, Sturrock CJ, Bennett MJ, Mooney SJ, Pridmore TP (2015) Extracting multiple interacting root systems using X-ray microcomputed tomography. Plant J 84:1034–1043
McNabb DH, Startsev AD, Nguyen H (2001) Soil wetness and traffic level effects on bulk density and air-filled porosity of compacted boreal forest soils. Soil Sci Soc Am J 65:1238–1247
Mirleau-Thebaud V, Dayde J, Scheiner JD (2017) Growth kinetics at early stages of sunflower (Helianthus annuus L.) under soil compaction. J Plant Nutr 40:2494–2510
Mooney SJ, Pridmore TP, Helliwell J, Bennett MJ (2012) Developing X-ray Computed Tomography to non-invasively image 3-D root systems architecture in soil. Plant Soil 352:1–22
Nahar K, Gretzmacher R (2011) Response of shoot and root development of seven tomato cultivars in hydroponic system under water stress. Acad J Plant Sci 4:57–63
Newton AC, Guy DC, Bengough AG, Gordon DC, McKenzie BM, Sun B, Valentine TA, Hallett PD (2012) Soil tillage effects on the efficacy of cultivars and their mixtures in winter barley. Field Crop Res 128:91–100
Niu W, Guo Q, Zhou X, Helmers MJ (2012) Effect of aeration and soil water redistribution on the air permeability under subsurface drip irrigation. Soil Sci Soc Am J 76:815–820
Passioura JB (1983) Roots and drought resistance. Agric Water Manage 7:265–280
Perret JS, Al-Belushi ME, Deadman M (2007) Non-destructive visualization and quantification of roots using computed tomography. Soil Biol Biochem 39:391–399
Place G, Bowman D, Burton M, Rutty T (2008) Root penetration through a high bulk density soil layer: differential response of a crop and weed species. Plant Soil 307:179–190
Rasband W (2013) ImageJ 1.48e. US National Institutes of Health, Bethesda
Ren B, Zhang J, Dong S, Liu P, Zhao B (2018) Responses of carbon metabolism and antioxidant system of summer maize to waterlogging at different stages. J Agron Crop Sci 204:505–514
Rucker KS, Kvien CK, Holbrook CC, Hook JE (1995) Identification of peanut genotypes with improved drought avoidance traits. Peanut Sci 21:14–18
Saxena NP, Krishnamurthy L, Johansen C (1993) Registration of a drought-resistant chickpea germplasm. Crop Sci 33:1424–1424
Serraj R, Krishnamurthy L, Kashiwagi J, Kumar J, Chandra S, Crouch JH (2004) Variation in root traits of chickpea (Cicer arietinum L.) grown under terminal drought. Field Crop Res 88:115–127
Singh BP, Sainju UM (1998) Soil physical and morphological properties and root growth. Hortscience 33:966–971
Sitaula BK, Hansen S, Sitaula JIB, Bakken LR (2000) Effects of soil compaction on N2O emission in agricultural soil. Chemosphere 2:367–371
Smith CW, Johnston MA, Lorentz S (1997) Assessing the compaction susceptibility of South African forestry soils. 1. The effect of soil type, water content and applied pressure on uni-axial compaction. Soil Till Res 41:53–73
Soil Survey Staff (2003) Keys to Soil Taxonomy, 9th edn. US Department of Agriculture, Washington, DC
Srividhya A, Vemireddy LR, Ramanarao PV, Sridhar S, Jayaprada M, Anuradha G, Srilakshmi B, Reddy HK, Hariprasad AS, Siddiq EA (2011) Molecular mapping of QTLs for drought related traits at seedling stage under PEG induced stress conditions in rice. Am J Plant Sci 2:190–201
Startsev AD, McNabb DH (2009) Effects of compaction on aeration and morphology of boreal forest soils in Alberta, Canada. Can J Soil Sci 89:45–56
Tardieu F, Zhang J, Katerji N, Bethenod O, Palmer S, Davies WJ (1992) Xylem ABA controls the stomatal conductance of field-grown maize subjected to soil compaction or soil drying. Plant Cell Environ 15:193–197
Taylor HM, Brar GS (1991) Effect of soil compaction on root development. Soil Till Res 19:111–119
Tracy SR, Roberts JA, Black CR, McNeill A, Davidson R, Mooney SJ (2010) The X-factor: visualizing undisturbed root architecture in soils using X-ray computed tomography. J Exp Bot 61:311–313
Tracy SR, Black CR, Roberts JA, Mooney SJ (2011) Soil compaction: a review of past and present techniques for investigating effects on root growth. J Sci Food Agric 91:1528–1537
Tracy SR, Black CR, Roberts JA, McNeill A, Davidson R, Tester M, Samec M, Korosak D, Sturrock C, Mooney SJ (2012) Quantifying the effect of soil compaction on three varieties of wheat (Triticum aestivum L.) using X-ray Micro Computed Tomography (CT). Plant Soil 353:195–208
Tracy SR, Black CR, Roberts JA, Mooney SJ (2013) Exploring the interacting effect of soil texture and bulk density on root system development in tomato (Solanum lycopersicum L.). Environ Exp Bot 91:38–47
Tracy SR, Black CR, Roberts JA, Dodd IC, Mooney SJ (2015) Using X-ray Computed Tomography to explore the role of abscisic acid in moderating the impact of soil compaction on root system architecture. Environ Exp Bot 110:11–18
Wasson AP, Richards RA, Chatrath R, Misra SC, Prasad SVS, Rebetzke GJ, Kirkegaard JA, Christopher J, Watt M (2012) Traits and selection strategies to improve root systems and water uptake in water-limited wheat crops. J Exp Bot 63:3485–3498
Whiteley GM, Hewitt JS, Dexter AR (1982) The buckling of plant roots. Physiol Plant 54:333–342
Zarehaghi D, Neyshabouri MR, Gorji M, Hassanpour R, Bandehagh A (2017) Growth and Development of Pistachio Seedling Root at Different Levels of Soil Moisture and Compaction in Greenhouse Conditions. Soil Water Res 12:60–66
Zhang Z, Liu K, Zhou H, Lin H, Li D, Peng X (2018) Three dimensional characteristics of biopores and non-biopores in the subsoil respond differently to land use and fertilization. Plant Soil 428:453–467
Acknowledgements
This work was granted by National Natural Science Foundation of China (41930753; 41725004; 41771264), National Key Research and Development Program of China (2016YFD0300809), the Primary Research and Development Plan of Jiangsu Province of China (BE2017385) and the UK Natural Environmental Research Council (NE/N007611/1).
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible Editor: W Richard Whalley
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
ESM 1
(DOCX 17.1 KB)
Rights and permissions
About this article
Cite this article
Xiong, P., Zhang, Z., Hallett, P.D. et al. Variable responses of maize root architecture in elite cultivars due to soil compaction and moisture. Plant Soil 455, 79–91 (2020). https://doi.org/10.1007/s11104-020-04673-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11104-020-04673-3