Maize plants can enter a standby mode to cope with chilling stress

Riva-Roveda, Laetitia; Escale, Brigitte; Giauffret, Catherine; Périlleux, Claire

doi:10.1186/s12870-016-0909-y

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Maize plants can enter a standby mode to cope with chilling stress

Riva-Roveda, Laetitia; Escale, Brigitte; Giauffret, Catherine et al.

2016 • In BMC Plant Biology, 16, p. 212

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10.1186/s12870-016-0909-y

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27716066

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Keywords :

maize; cold tolerance; leaf growth; photoprotection

Abstract :

[en] Background European Flint maize inbred lines are used as a source of adaptation to cold in most breeding programs in Northern Europe. A deep understanding of their adaptation strategy could thus provide valuable clues for further improvement, which is required in the current context of climate change. We therefore compared six inbreds and two derived Flint x Dent hybrids for their response to one-week at low temperature (10°C day/7 or 4°C night) during steady-state vegetative growth. Results Leaf growth was arrested during chilling treatment but recovered fast upon return to warm temperature, so that no negative effect on shoot biomass was measured. Gene expression analyses of the emerging leaf in the hybrids suggest that plants maintained a ‘ready-to-grow’ state during chilling since cell cycle genes were not differentially expressed in the division zone and genes coding for expansins were on the opposite up-regulated in the elongation zone. In photosynthetic tissues, a strong reduction in PSII efficiency was measured. Chilling repressed chlorophyll biosynthesis; we detected accumulation of the precursor geranylgeranyl chlorophyll a and down-regulation of GERANYLGERANYL REDUCTASE (GGR) in mature leaf tissues. Excess light energy was mostly dissipated through fluorescence and constitutive thermal dissipation processes, rather than by light-regulated thermal dissipation. Consistently, only weak clues of xanthophyll cycle activation were found. CO2 assimilation was reduced by chilling, as well as the expression levels of genes encoding phosphoenolpyruvate carboxylase (PEPC), pyruvate orthophosphate dikinase (PPDK), and the small subunit of Rubisco. Accumulation of sugars was correlated with a strong decrease of the specific leaf area (SLA). Conclusions Altogether, our study reveals good tolerance of the photosynthetic machinery of Northern European maize to chilling and suggests that growth arrest might be their strategy for fast recovery after a mild stress.

Disciplines :

Phytobiology (plant sciences, forestry, mycology...)

Author, co-author :

Riva-Roveda, Laetitia ; Université de Liège - ULiège > Doct. sc. (bioch., biol. mol.&cell., bioinf.&mod.-Bologne)

Escale, Brigitte; Arvalis - Institut du Végétal > Génétique, Physiologie et Protection des plantes

Giauffret, Catherine; Institut Scientifique de Recherche Agronomique - INRA > UR AgroImpact

Périlleux, Claire ; Université de Liège > Département des sciences de la vie > Physiologie végétale

Language :

English

Title :

Maize plants can enter a standby mode to cope with chilling stress

Publication date :

04 October 2016

Journal title :

BMC Plant Biology

eISSN :

1471-2229

Publisher :

BioMed Central

Volume :

Pages :

212

Peer reviewed :

Peer Reviewed verified by ORBi

Name of the research project :

Thermomaïs

Funders :

Arvalis - Institut du Végétal [FR]

Available on ORBi :

since 28 September 2016

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Bibliography

Rebourg C, Chastanet M, Gouesnard B, Welcker C, Dubreuil P, Charcosset A. Maize introduction into Europe: the history reviewed in the light of molecular data. Theor Appl Genet. 2003;106:895-903.
Doebley J, Wendel JD, Smith JSC, Stuber CW, Goodman MM. The origin of cornbelt maize: the isozyme evidence. Econ Bot. 1988;42:120-31.
Tenaillon MI, Charcosset A. A European perspective on maize history. C R Biol. 2011;334:221-8.
Rodríguez VM, Butron A, Sandoya G, Ordas A, Revilla P. Combining maize base germplasm for cold tolerance breeding. Crop Sci. 2007;47:1467-74.
Barrière Y, Alber D, Dolstra O, Lapierre C, Motto M, Ordas A, et al. Past and prospects of forage maize breeding in Europe. II. History, germplasm evolution and correlative agronomic changes. Maydica. 2006;51:435-49.
Lorgeou J, Prioul JL. Agrophysiology: light interception, crop photosynthesis, mineral nutrition and crop managing. In: Prioul JL, Thévenot C, Molnar T, editors. Advances in Maize. London: Society of Experimental Biology; 2011. p. 393-410.
Marocco A, Lorenzoni C, Fracheboud Y. Chilling stress in maize. Maydica. 2005;50:571-80.
Leipner J, Stamp P. Chilling stress in maize seedlings. In: Bennetzen JL, Hake SC, editors. Handbook of Maize. New York: Springer; 2009. p. 291-310.
Miedema P. The effects of low temperature on Zea mays. Adv Agron. 1982;35:93-128.
Louarn G, Chenu K, Fournier C, Andrieu B, Giauffret C. Relative contributions of light interception and radiation use efficiency to the reduction of maize productivity under cold temperatures. Funct Plant Biol. 2008;35:885-99.
Giauffret C, Foyer CH. Effects of chilling temperatures on maize growth and biomass production. In: Prioul JL, Thévenot C, Molnar T, editors. Advances in Maize. London: Society of Experimental Biology; 2011. p. 347-72.
Revilla P, Malvar RA, Cartea ME, Butron A, Ordas A. Inheritance of cold tolerance at emergence and during early season growth in maize. Crop Sci. 2000;40:1579-85.
Leipner J, Jompuk C, Camp KH, Stamp P, Fracheboud Y. QTL studies reveal little relevance of chilling-related seedling traits for yield in maize. Theor Appl Genet. 2008;116:555-62.
Li P, Ponnala L, Gandotra N, Wang L, Si Y, Tausta SL, et al. The developmental dynamics of the maize leaf transcriptome. Nat Genet. 2010;42:1060-7.
Rymen B, Fiorani F, Kartal F, Vandepoele K, Inzé D, Beemster GTS. Cold nights impair leaf growth and cell cycle progression in maize through transcriptional changes of cell cycle genes. Plant Physiol. 2007;143:1429-38.
Hu Y, Zhang L, Zhao L, Li J, He S, Zhou K, et al. Trichostatin A selectively suppresses the cold-induced transcription of the ZmDREB1 gene in maize. PLoS One. 2011;6:e22132.
Chinnusamy V, Zhu J. Cold stress regulation of gene expression in plants. Trends Plant Sci. 2007;12:444-51.
Miura K. ICE1, a transcription factor involved in cold signaling and tolerance. In: Imai R, Yoshida M, Matsumoto N, editors. Plant and microbe adaptations to cold in a changing world. New York: Springer; 2013. p. 189-95.
Sylvester AW, Smith LG. Cell biology of maize leaf development. In: Bennetzen J, Hake S, editors. Handbook of Maize: its biology. New York: Springer; 2009. p. 179-203.
Parent B, Turc O, Gibon Y, Stitt M, Tardieu F. Modelling temperature-compensated physiological rates, based on the co-ordination of responses to temperature of developmental processes. J Exp Bot. 2010;61:2057-69.
Louarn G, Andrieu B, Giauffret C. A size-mediated effect can compensate for transient chilling stress affecting maize (Zea mays) leaf extension. New Phytol. 2010;187:106-18.
Caffarri S, Frigerio S, Olivieri E, Righetti PG, Bassi R. Differential accumulation of Lhcb gene products in thylakoid membranes of Zea mays plants grown under contrasting light and temperature conditions. Proteomics. 2005;5:758-68.
Kingston-Smith AH, Harbinson J, Foyer CH. Acclimation of photosynthesis, H2O2 content and antioxidants in maize (Zea mays) grown at sub-optimal temperatures. Plant Cell Environ. 1999;22:1071-83.
Kutík J, Holá D, Kočová M, Rothová O, Haisel D, Wilhelmová N, et al. Ultrastructure and dimensions of chloroplasts in leaves of three maize (Zea mays L.) inbred lines and their F1 hybrids grown under moderate chilling stress. Photosynthetica. 2004;42:447-55.
Baker NR, Nie GY. Chilling sensitivity of photosynthesis in maize. In: Bajaj YPS, editor. Biotechnology in agriculture and forestry 25 - Maize. Berlin: Springer; 1994. p. 465-81.
Fracheboud Y, Haldimann P, Leipner J, Stamp P. Chlorophyll fluorescence as a selection tool for cold tolerance of photosynthesis in maize (Zea mays L.). J Exp Bot. 1999;50:1533-40.
Baker NR. Chlorophyll fluorescence: A probe of photosynthesis in vivo. Annu Rev Plant Biol. 2008;59:89-113.
Bhosale SU, Rymen B, Beemster GTS, Melchinger AE, Reif JC. Chilling tolerance of central european maize lines and their factorial crosses. Ann Bot. 2007;100:1315-21.
Strigens A, Freitag NM, Gilbert X, Grieder C, Riedelsheimer C, Schrag TA, et al. Association mapping for chilling tolerance in elite Flint and Dent maize inbred lines evaluated in growth chamber and field experiments. Plant Cell Environ. 2013;36:1871-87.
Lejeune P, Bernier G. Effect of environment on the early steps of ear initiation in maize (Zea mays L.). Plant Cell Environ. 1996;19:217-24.
Hendrickson L, Furbank RT, Chow WS. A simple alternative approach to assessing the fate of absorbed light energy using chlorophyll fluorescence. Photosynth Res. 2004;82:73-81.
Böddi B, Loudeche R, Franck F. Delayed chlorophyll accumulation and pigment photodestruction in the epicotyls of dark-grown pea (Pisum sativum). Physiol Plant. 2005;125:365-72.
Pietrini F, Iannelli MA, Battistelli A, Moscatello S, Loreto F, Massacci A. Effects on photosynthesis, carbohydrate accumulation and regrowth induced by temperature increase in maize genotypes with different sensitivity to low temperature. Aust J Plant Physiol. 1999;26:367-73.
Sekhon RS, Lin H, Childs KL, Hansey CN, Buell CR, de Leon N, et al. Genome-wide atlas of transcription during maize development. Plant J. 2011;66:553-63.
Manoli A, Sturaro A, Trevisan S, Quaggiotti S, Nonis A. Evaluation of candidate reference genes for qPCR in maize. J Plant Physiol. 2012;169:807-15.
Pabinger S, Rödiger S, Kriegner A, Vierlinger K, Weinhäusel A. A survey of tools for the analysis of quantitative PCR (qPCR) data. BDQ. 2014;1:23-33.
Pfaffl MW, Horgan GW, Dempfle L. Relative expression software tool (REST©) for group-wise comparison and statistical analysis of relative expression results in real-time PCR. Nucleic Acids Res. 2002;30:e36.
Murchie EH, Lawson T. Chlorophyll fluorescence analysis: a guide to good practice and understanding some new applications. J Exp Bot. 2013;64:3983-98.
Qin F, Sakuma Y, Li J, Liu Q, Li YQ, Shinozaki K, et al. Cloning and functional analysis of a novel DREB1/CBF transcription factor involved in cold-responsive gene expression in Zea mays L. Plant Cell Physiol. 2004;45:1042-52.
Muller B, Bourdais G, Reidy B, Bencivenni C, Massonneau A, Condamine P, et al. Association of specific expansins with growth in maize leaves is maintained under environmental, genetic, and developmental sources of variation. Plant Physiol. 2007;143:278-90.
Tanaka R, Oster U, Kruse E, Rüdiger W, Grimm B. Reduced activity of geranylgeranyl reductase leads to loss of chlorophyll and tocopherol and to partially geranylgeranylated chlorophyll in transgenic tobacco plants expressing antisense RNA for geranylgeranyl reductase. Plant Physiol. 1999;120:695-704.
Sánchez B, Rasmussen A, Porter JR. Temperatures and the growth and development of maize and rice: a review. Global Chang Biol. 2014;20:408-17.
Goh H-H, Sloan J, Dorca-Fornell C, Fleming A. Inducible repression of multiple expansin genes leads to growth suppression during leaf development. Plant Physiol. 2012;159:1759-70.
Bauerfeind MA, Winkelmann T, Franken P, Druege U. Transcriptome, carbohydrate, and phytohormone analysis of Petunia hybrida reveals a complex disturbance of plant functional integrity under mild chilling stress. Front Plant Sci. 2015;6:583.
Clauw P, Coppens F, De Beuf K, Dhondt S, Van Daele T, Maleux K, et al. Leaf responses to mild drought stress in natural variants of Arabidopsis. Plant Physiol. 2015;167:800-16.
Long SP, Spence AK. Toward cool C4 crops. Annu Rev Plant Biol. 2013;64:701-22.
Naidu SL, Long SP. Potential mechanisms of low-temperature tolerance of C4 photosynthesis in Miscanthus x giganteus: an in vivo analysis. Planta. 2004;220:145-55.
Massad RS, Tuzet A, Bethenod O. The effect of temperature on C4-type leaf photosynthesis parameters. Plant Cell Environ. 2007;30:1191-204.
Koch KE. Carbohydrate-modulated gene expression in plants. Annu Rev Plant Physiol Plant Mol Biol. 1996;47:509-40.
Miura K, Jin JB, Lee J, Yoo CY, Stirm V, Miura T, et al. SIZ1-mediated sumoylation of ICE1 controls CBF3/DREB1A expression and freezing tolerance in Arabidopsis. Plant Cell. 2007;19:1403-14.
Genty B, Briantais J-M, Baker NR. The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence. BBA-Gen Subjects. 1989;990:87-92.
Leipner J, Fracheboud Y, Stamp P. Acclimation by suboptimal growth temperature diminishes photooxidative damage in maize leaves. Plant Cell Environ. 1997;20:366-72.
Bratt CE, Arvidsson PO, Carlsson M, Åkerlund HE. Regulation of violaxanthin de-epoxidase activity by pH and ascorbate concentration. Photosynth Res. 1995;45:169-75.
Nie GY, Baker NR. Modifications to thylakoid composition during development of maize leaves at low growth temperatures. Plant Physiol. 1991;95:184-91.
Verheul MJ, Picatto C, Stamp P. Growth and development of maize (Zea mays L.) seedlings under chilling conditions in the field. Eur J Agron. 1996;5:31-43.