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Journal of Arid Land  2018, Vol. 10 Issue (2): 304-315    DOI: 10.1007/s40333-018-0050-x     CSTR: 32276.14.s40333-018-0050-x
Orginal Article     
Effects of temperature and water limitation on the germination of Stipagrostis ciliata seeds collected from Sidi Bouzid Governorate in Central Tunisia
M FAKHFAKH Lobna1,*(), A ANJUM Naser2, CHAIEB Mohamed1
1 Department of Life Sciences, Faculty of Sciences, University of Sfax, Sfax 3000, Tunisia
2 Centre for Environmental and Marine Studies and Department of Chemistry, University of Aveiro, Aveiro 3810-193, Portugal
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Abstract  

Most ecological studies in North Africa reveal a process of continuous degradation of rangeland ecosystems as a result of overgrazing. This degradation appears across the decreasing of perennial grass diversity. Indeed, the majority of steppe ecosystems are characterized by a low density of perennial grass species at present. This study evaluated the effects of temperature and water limitation on the seed germination of Stipagrostis ciliata (Desf.) de Winter, a perennial grass species. The seeds were collected from the Bou Hedma Park, Sidi Bouzid Governorate, Central Tunisia. The thermal time and hydrothermal time models were used to describe the seed germination of S. ciliata under different water potentials and temperatures. The germination response of S. ciliata seeds in darkness was evaluated over a range of temperatures (15°C, 20°C, 25°C, 30°C and 35°C) and across a wide range of osmotic potentials (0.0, -0.2, -0.6, -1.2, -1.6 and -2.0 MPa) of the polyethylene glycol (PEG6000) solutions at each temperature level. Among the tested temperatures, 25°C was found to be the optimal temperature to the germination of S. ciliata seeds. The final germination percentage (75.2%) was obtained with distilled water. The progressive decrease of osmotic potential of the PEG6000 solutions inhibited the seed germination. However, the number of days to first germination was increased with a reduction of osmotic potential. A significant positive relationship was identified between final germination percentage of S. ciliata seeds and osmotic potential of the PEG6000 solutions, with R2 ranging from 0.5678 to 0.8761. Furthermore, a high degree of congruency between predicted and observed germination time course curves was observed. In general, S. ciliata exhibits a significant adaptation capacity for water limitation and high temperature in arid ecosystems.



Key wordsStipagrostis ciliata      germination      temperature      water potential      hydrothermal model      arid zone      Bou Hedma Park     
Received: 07 April 2017      Published: 10 April 2018
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The first and fourth authors contributed equally to this work.

Cite this article:

M FAKHFAKH Lobna, A ANJUM Naser, CHAIEB Mohamed. Effects of temperature and water limitation on the germination of Stipagrostis ciliata seeds collected from Sidi Bouzid Governorate in Central Tunisia. Journal of Arid Land, 2018, 10(2): 304-315.

URL:

http://jal.xjegi.com/10.1007/s40333-018-0050-x     OR     http://jal.xjegi.com/Y2018/V10/I2/304

[1] Aronson J, Kigel J, Shmida A.1993. Reproductive allocation strategies in desert and Mediterranean populations of annual plants grown with and without water stress. Oecologia, 93(3): 336-342.
[2] Baskin C C, Baskin J M.1998. Seeds: Ecology, Biogeography, and Evolution of Dormancy and Germination. San Diego: Academic Press, 666.
[3] Bewley J D, Black M.1994. Seeds: Physiology of Development and Germination (2nd ed.). New York: Plenum Press, 454.
[4] Bonvissuto G L, Busso C A.2007. Germination of grasses and shrubs under various water stress and temperature conditions. International Journal of Experimental Botany, 76: 119-131.
[5] Bradford K J.1990. A water relations analysis of seed germination rates. Plant Physiology, 94(2): 840-849.
[6] Bradford K J, Somasco Q A.1994. Water relations of lettuce seed thermoinhibition. I. Priming and endosperm effects on base water potential. Seed Science Research, 4(1): 1-10.
[7] Bradford K J.1995. Water relations in seed germination. In: Kigel J, Galili G. Seed Development and Germination. New York: Marcel Dekker, 351-395.
[8] Bradford K J.2002. Applications of hydrothermal time to quantifying and modeling seed germination and dormancy. Weed Science, 50(2): 248-260.
[9] Chaieb M, Floret C, Le Floc'h E, et al.1992. Life history strategies and water resource allocation in five pasture species of the Tunisian arid zone. Arid Soil Research and Rehabilitation, 6(1): 1-10.
[10] Chaieb M, Henchi B, Boukhris M.1996. Impact of clipping on root systems of 3 grasses species in Tunisia. Journal of Range Management, 49(4): 336-339.
[11] Chauhan B S, Johnson D E.2008. Germination ecology of Southern crabgrass (Digitaria ciliaris) and India crabgrass (Digitaria longiflora): two important weeds of rice in tropics. Weed Science, 56(5): 722-728.
[12] Dahal P, Bradford K J.1990. Effects of priming and endosperm integrity on seed germination rates of tomato genotypes: II. Germination at reduced water potential. Journal of Experimental Botany, 41(11): 1441-1453.
[13] Dahal P, Bradford K J.1994. Hydrothermal time analysis of tomato seed germination at suboptimal temperature and reduced water potential. Seed Science Research, 4(2): 71-80.
[14] Daur I.2012. Plant flora in the rangeland of western Saudi Arabia. Pakistan Journal of Botany, 44(Suppl.): 23-26.
[15] de la Barrera E, Castellanos A E.2007. High temperature effects on gas exchange for the invasive buffel grass (Pennisetum ciliare [L.] Link). Weed Biological Management, 7(2): 128-131.
[16] De Mendon?a Barreto Cavalcante A, Perez S C J G A.1995. Effect of water stress and salinity on germination of Leucaena leucocephala seeds. Pesquisa Agropecuaria Brasileira, 30(2): 281-289. (in Portugaise)
[17] Dutta S, Bradford K J.1994. Water relations of lettuce seed thermoinhibition. II. Ethylene and endosperm effects on base water potential. Seed Science Research, 4(1): 11-18.
[18] Emmerich W E, Hardegree S P.1991. Seed germination in polyethylene glycol solution: effects of filter paper exclusion and water vapor loss. Crop Sciences, 31(2): 454-458.
[19] Evans C E, Etherington J R.1990. The effect of soil water potential on seed germination of some British plants. New Phytologist, 115(3): 539-548.
[20] Fischer R A, Turner N C.1978. Plant productivity in the arid and semiarid zones. Annual Review of Plant Physiology, 29: 277-317.
[21] Gorai M, Tlig T, Neffatti M.2009. Influence of water stress on seed germination characteristics in invasive Diplotaxis harra (Forssk.) Boiss (Brassicaceae) in arid zone of Tunisia. Journal of Phytology, 1(4): 249-254.
[22] Gummerson R J.1986. The effect of constant temperatures and osmotic potentials on the germination of sugar beet. Journal of Experimental Botany, 37(6): 729-741.
[23] Günster A.1995. Grass cover distribution in the central Namib—a rapid method to assess regional and local rainfall patterns of arid regions? Journal of Arid Environments, 29(1): 107-114.
[24] Gutterman Y.2002. Survival Strategies of Annual Desert Plants. New York, NY, USA: Springer, 348.
[25] Hamasha H R, Hensen I.2009. Seed germination of four Jordanian Stipa spp: differences in temperature regimes and seed provenances. Plant Species Biology, 24(2): 127-132.
[26] Jauffret S, Visser M.2003. Assigning life-history traits to plant species to better qualify arid land degradation in Presaharian Tunisia. Journal of Arid Environments, 55(1): 1-28.
[27] Kellogg E A.2001. Evolutionary history of the grasses. Plant Physiology, 125(3): 1198-1205.
[28] Khan M A, Gul B, Weber D J.2001. Influence of salinity and temperature on the germination of Kochia scoparia. Wetlands Ecological and Management, 9(6): 483-489.
[29] Khan M A, Unger I A.2001. Alleviation of salinity stress and the response to temperature in two seed morphs of Halopyrum mucronatum (Poaceae). Australian Journal of Botany, 49(6): 777-783.
[30] Le Houérou H N.1984. Rain use efficiency: a unifying concept in arid-land ecology. Journal of Arid Environments, 7(3): 213-247.
[31] Le Houérou H N.2005. Atlas of Climatic Diagrams for the Isoclimatic Mediterranean Zones. Montpellier: Copymania, 220.
[32] Liu H L, Zhang L W, Yin L K, et al.2013. Effects of temperature, dry storage, and burial on dormancy and germination of seeds of 13 desert plant species from sand dunes in the Gurbantunggut Desert, Northwest China. Arid Land Research and Management, 27(1): 65-78.
[33] Maestre F T, Cortina J, Vallejo R.2006. Are ecosystem composition, structure, and functional status related to restoration success? A test from semiarid Mediterranean steppes. Restoration Ecology, 14(2): 258-266.
[34] Meyer S E, Debaene-Gill S B, Allen P S.2000. Using hydrothermal time concepts to model seed germination response to temperature, dormancy loss, and priming effects in Elymus elymoides. Seed Science Research, 10(3): 213-223.
[35] Michel B E, Kaufmann M R.1973. The osmotic potential of polyethylene glycol 6000. Plant Physiology, 51(5): 914-916.
[36] Mnif L, Chaieb M.2010. Net photosynthesis and leaf water potential of buffel grass (Cenchrus ciliaris L.) accessions, growing in the arid zone of Tunisia. Journal of Biological Research, 14: 231-238.
[37] Mosallam H A, Morsy A A, Youssef A M, et al.2009. Structure of the common plant population along Alamain-Wadi El- Natrun Desert Roat. Australian Journal of Basic and Applied Sciences, 3(1): 177-193.
[38] Naidu S L, Moose S P, Al-Shoaibi A K, et al.2003. Cold tolerance of C4 photosynthesis in Miscanthus × giganteus: adaptation in amounts and sequence of C4 photosynthetic enzymes. Plant Physiology, 132(3): 1688-1697.
[39] Niu S L, Yuan Z Y, Zhang Y F, et al.2005. Photosynthetic responses of C3 and C4 species to seasonal water variability and competition. Journal of Experimental Botany, 56(421): 2867-2876.
[40] Ouled Belgacem A, Neffati M, Papanastasis V P, et al.2006. Effects of seed age and seeding depth on growth of Stipa lagascae R. & Sch. seedlings. Journal of Arid Environments, 65(4): 682-687.
[41] Reynolds P E, Simpson J A, Thevathasan N V, et al.2007. Effects of tree competition on corn and soybean photosynthesis, growth, and yield in a temperate tree-based agroforestry intercropping system in southern Ontario, Canada. Ecological Engineering, 29(4): 362-371.
[42] Ronnenberg K, Wesche K, Hensen I.2008. Germination ecology of Central Asian Stipa spp: differences among species, seed provenances, and the importance of field studies. Plant Ecology, 196(2): 269-280.
[43] Skinner T E.1964. Physiological and ecological studies on Stipagrostis ciliata and S. obtusa. MSc Thesis. Pretoria: University of Pretoria.
[44] Thanos C A, Kadis C C, Skarou F.1995. Ecophysiology of germination in the aromatic plants thyme, savory and oregano (Labiatae). Seed Science Research, 5(3): 161-170.
[45] Tlig T, Gorai M, Neffati M.2008. Germination responses of Diplotaxis harra to temperature and salinity. Flora-Morphology, Distribution, Functional Ecology of Plants, 203(5): 421-428.
[46] Valencia E, Maestre F T, Le Bagousse-Pinguet Y, et al.2015. Functional diversity enhances the resistance of ecosystem multifunctionality to aridity in Mediterranean drylands. New Phytologist, 206(2): 660-671.
[47] Xiao W H, Zhou Q Z, Li T S, et al.2013. Environmental factors controlling seed germination and seedling recruitment of Stipa bungeana on the Loess Plateau of northwestern China. Ecological Research, 28(5): 801-809.
[48] Yamori W, Hikosaka K, Way D A.2014. Temperature response of photosynthesis in C3, C4, and CAM plants: temperature acclimation and temperature adaptation. Photosynthesis Research, 119(1-2): 101-117.
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