Effect of seasonal variations on the content of some osmolytes of Aleppo pine and holm oak

[1]. Bentouati, A.; Bariteau M., Une sylviculture pour le pin d’Alep des Aurès (Algérie). Forêt méditerranéenne, 2005,XXVI (4), 315-321.Search in Google Scholar

[2]. Mezali, M., Rapport sur le secteur forestier en Algérie. 3e session du forum des Nations Unis sur les forêts, 2003.Search in Google Scholar

[3]. Vennetier, M., Changement climatique et dépérissements forestiers: causes et conséquences. Changement Climatique et Modification Forestière, CNRS, Paris, 2012, 50-60.Search in Google Scholar

[4]. Meddour-Sahar, O. ; Derridj, A., 2012. Bilan des feux de forêts en Algérie: analyse spatio-temporelle et cartographie du risque (période 1985-2010). Sécheresse,2012,23 (2), 133-141.10.1684/sec.2012.0342Search in Google Scholar

[5]. Madoui, A. ; Gehu, J.M. ; Alatou, D., L’effet du feu sur la composition des pinèdes de Pinus halepensis Mill. dans le nord de la forêt de Bou-Taleb, Algérie. Ecologia Mediterranea, 2006, 32, 5-13.Search in Google Scholar

[6]. Lemouissi, S. ; Rached-Kanouni, M.; Hadef, A.; Amine Khoja, A. E. M.; Alatou, D., Adaptation of Holm oak (Quercus ilex L.) to seasonal climate variations. International Journal of Management Sciences and Business research, 2014,3(5), 30–35.Search in Google Scholar

[7]. Rached-Kanouni, M.; Alatou, D.; Sakr, S., Responses of Cork Oak Seedlings to Short-Term Exposures to Low Temperatures. American Journal of Scientific Research, 2012,59, 28–41.Search in Google Scholar

[8]. Megrerouche, R.; Rached-Kanouni, M.; Amine Khodja, A. E. M.; Alatou D., Susceptibility to Fire (Case the Forest of Chettabah, Algeria). International Journal of Management Sciences and Business Research, 2015,4(4), 8–13.Search in Google Scholar

[9]. Quézel, P.; Médail, F., Conséquences écologiques possibles des changements climatiques sur la flore et la végétation du bassin méditerranéen. Bocconea, 2003,16 (1), 397-422.Search in Google Scholar

[10]. Petit, J. P.; Hampe, A.; Cheddadi, R., Climate changes and tree phylogeography in the Mediterranean. Taxon, 2005,54 (4), 877-885.10.2307/25065568Search in Google Scholar

[11]. Nicault, A. ; Rathgeberg, C.; Tessier, L.; Thomasd, A., Observation sur la mise en place du cerne chez le pin d’Alep (Pinus halepensis Mill.): Confrontation entre les mesures de croissance radiale, de densité et les facteurs climatiques. Ann. For. Sci., 2002,58, 759-784.Search in Google Scholar

[12]. Sarir, R. ; Benmahioul B., Etude comparative de la croissance végétative et du développement de jeunes semis de trois espèces de chênes (chêne vert, chêne liège et chêne zéen) cultivés en pépinière. Agric. For. J., 2017, 1 (1), 42-48.Search in Google Scholar

[13]. Laala, A. ; Rached-Kanouni, M. ; Alatou, D., Les variations thermiques saisonniers et leurs impacts sur le comportement écophysiologiques des semis de pin d’Alep. European Scientific Journal,2013,9(24), 143–153.Search in Google Scholar

[14]. Rached-Kanouni, M.; Alatou, D.; Sakr S., Effects of high temperature on concentrations of soluble sugars and quercitol of Cork oak (Quercus suber) seedlings. International Journal of Management Sciences and Business research, 2012,1(6), 1–10.Search in Google Scholar

[15]. Chantuma, P.; Lacote, R.; Sonnarth, S.; Gohet E., Effects of Different Tapping Rest Periods during Wintering and Summer Months on Dry Rubber Yield of Hevea Brasiliensis in Thailand. J Rubber Res, 2017, 20, 261–272.Search in Google Scholar

[16]. Durbak, A.; Yao, H.; McSteen, P., Hormone signaling in plant development. Current Opinion in Plant Biology, 2012,15, 92–96.Search in Google Scholar

[17]. Gechev, TS.; Rille, J., Molecular basis of plant stress. Cellular and Molecular Lije Sciences, 2012,69, 3161–3163.Search in Google Scholar

[18]. Sakai, A.; Larcher; W., Frost survival of plants-Responses and Adaptation to Freezing Stress. Ecol. Studies, 1997,62, 112–133.Search in Google Scholar

[19]. Sakuma, Y.; Liu, Q.; Dubouzet, J. G.; Abe, H.; Shinozaki, K., DNA-binding specificity of the ERF/AP2 domain of Arabidopsis DREBs, transcription factors involved in dehydration- and cold-inducible gene expression. Biochemical and Biophysical Research Communications, 2002,290, 998-1009.Search in Google Scholar

[20]. Sakr, S.; Alves, G.; Morillon, R. ; Maurel, K.; Decourteix, M.; Guilliot, A.; Fleurat-Lessard, P.; Julien, J.L.; Chrispeels M., Plasma membrane aquaporins are involved in winter embolism recovery in walnut tree. Plant Physiology, 2003,133, 630-641.Search in Google Scholar

[21]. Welling, A.; Palva, E.T., Molecular control of cold acclimation in trees. Physiologia Plantarum, 2006,127, 167-181.Search in Google Scholar

[22]. Silpi, U.; Lacointe, A.; Kasempsap, P.; Thanysawanyangkura, S.; Chantuma, P.; Gohet, E.; Musigamart, N.; Clement, A.; Ameglio, T.; Thaler, P., Carbohydrate reserves as a competing sink: evidence from tapping rubber trees. Tree Physiology, 2007,27, 881–889.Search in Google Scholar

[23]. Chinnusamy, V.; Zhu, J.; Zhu, J. K., Gene regulation during cold acclimation in plants. Physiologia Plantarum, 2006,126(1), 52-61.10.1111/j.1399-3054.2006.00596.xSearch in Google Scholar

[24]. Costa E Silva, F.; Shvaleva, A.; Broetto, F.; Ortuno, M.F.; Rodrigues, M.L. ; Almeida, M. H.; Chaves, M. M.; Pereira J.S., Acclimation to short-term low temperatures in two Eucalyptus globulus clones with contrasting drought resistance. Tree Physiol., 2009,29, 77–86.Search in Google Scholar

[25]. Delauney, A. J.; Verma, D. P. S., Proline biosynthesis and osmoregulation in plants. The Plant Journal,1993,4, 215–223.Search in Google Scholar

[26]. Szabados, Z.; Savouré, A., Proline : a multifunctional amino acid. Trends Plant Sci., 2010, 15, 89–97.Search in Google Scholar

[27]. Widodo, Patterson, J. H.; Newbigin, E.; Tester, M.; Bacic, A.; Roessner, U., Metabolic responses to salt stress of barley (Hordeum vulgare L.) cultivars, Sahara and Clipper, which differ in salinity tolerance. J. Exp. Bot., 2009, 60(14), 4089–4103.10.1093/jxb/erp243Search in Google Scholar

[28]. Rached-Kanouni, M; Alatou, D; Sakr, S., Responses of Cork Oak Seedlings to Short-Term Exposures to Low Temperatures. American Journal of Scientific Research, 2012,59, 28–41.Search in Google Scholar

[29]. Rached-Kanouni, M.; Alatou, D.; Sakr S., Effects of high temperature on concentrations of soluble sugars and quercitol of Cork oak (Quercus suber) seedlings, International Journal of Management Sciences and Business Research, 2012,1(6), 1–13.Search in Google Scholar

[30]. Chinnusamy, V.; Schumaker, K.; Zhu, J.K., Molecular genetic perspectives on cross-talk and specifity in abiotic stress signalling in plants. J. Exp. Bot., 2004,55 (395), 225–236.10.1093/jxb/erh005Search in Google Scholar

[31]. Zaki, S.S.; Rady, M.M., Moringa oleifera leaf extract improves growth, physiochemical attributes, antioxidant defense system and yields of salt-stressed Phaseolus vulgaris L. plants. International Journal of ChemTech Research, 2015,8 (11), 120–134.Search in Google Scholar

[32]. Parida, A. K.; Dagaonkar, V. S.; Phalak, M.S.; Aurangabadkar, L.P., Differential responses of the enzymes involved in proline biosynthesis and degradation in drought tolerant and sensitive cotton genotypes during drought stress and recovery. Acta Physiol. Plant. 2008,30(5), 619–627.Search in Google Scholar

[33]. Chinnusamy, V.; Zhu, J.; Zhu, J. K., Cold stress regulation of gene expression in plants. Trends Plant Sci., 2007,12, 444–451.Search in Google Scholar

[34]. Oraki, H.; Khajani, F. P.; Aghaalikhana, M., Effect of water deficit stress on proline contents, soluble sugars, chlorophyll and grain yield of sunflower (Helianthus annuus L.) hybrids. African J. Biotechnol., 2012,11, 164–168.Search in Google Scholar

[35]. Assaha, D.V.M. ; Liu, L.; Ueda, A.; Nagaoka, T.; Saneoka, H., Effects of drought stress on growth, solute accumulation and membrane stability of leafy vegetable, huckleberry (Solanum scabrum Mill.). Journal of Environmental Biology, 2016,37, 107–114.Search in Google Scholar

[36]. Shin, H.; Oh, S.; Kim, K.; Kim, D., Proline accumulates in response to higher temperatures during dehardening in peach shoot tissues. Hort. J., 2016,85(1), 37–45.10.2503/hortj.MI-088Search in Google Scholar

[37]. Lehmann, S.; Funck, D.; Szabados, L.; Rentsch, D., Proline metabolism and transport in plant development. Amino Acids, 2010,39(4), 949–962.10.1007/s00726-010-0525-3Search in Google Scholar

[38]. Kavi Kishor, P. B.; Sreenivasulu, N., Is proline accumulation per se correlated with stress tolerance or is proline homeostasis a more critical issue? Plant Cell Environ. 2014,37 (2), 300-311.Search in Google Scholar

[39]. Verbruggen, N.; Hermans, C., Proline accumulation in plants: A review. Amino Acids, 2008,35, 753–759.Search in Google Scholar

[40]. Angelcheva, L.; Mishra, Y.; Antti, H.; Kjellsen, T.D.; Funk, C.; Strimbeck, R.G.; Schröder, W. P., Metabolic analysis of extreme freezing tolerance in Siberian spruce (Picea obovate). New Phytol. 2014,204 (3), 545–555.Search in Google Scholar

[41]. Baker, S. S.; Wilhelm K.S.; Thomashow M. F., The 5′-Region of Arabidopsis-Thaliana Cor15a Has Cis-Acting Elements That Confer Cold-Regulated, Drought-Regulated and Aba-Regulated Gene-Expression. Plant Mol. Biol., 1994,24, 701–713.Search in Google Scholar

[42]. De Ronde, J.A.; Cress, W.A.; Krüger, G. H. J.; Strasser, R. J.; Van, Staden, J., Photosynthetic response of transgenic soybean plants, containing an Arabidopsis P5CR gene, during heat and drought stress. J. Plant. Physiol., 2004,161, 1211–1224.Search in Google Scholar

[43]. Souren, J. E.; Wiegant, F.A.; Van, wijk, R., The role of hsp70 in protection and repair of luciferase activity in vivo; experimental data and mathematical modelling. Cell Mol. Life Sci., 1999,55, 799–811.10.1007/s000180050333Search in Google Scholar

[44]. Sung, D.Y.; Kaplan, F.; Lee, K. J.; Guy, C. L., Acquired tolerance to temperature extremes. Trends in Plant Science, 2003,8, 179–187.Search in Google Scholar

[45] Dionne, J., Protection hivernale et tolérance au froid du Pâturin Annuel Pea ann. Plant J., 2001,4, 215-223.Search in Google Scholar

[46]. Houde, M. ; Daniel, C.; Lachapelle, M; Allard, F.; Laliberté, S.; Sarhan, F., Immunolocalization of freezing-tolerance-associated proteins in the cytoplasme and nucleoplasm of wheat crown tissues. Plant. J., 1995,8, 583–593.Search in Google Scholar

[47]. Vierling E., Chloroplast-localized Clp proteins. In: Guidebook to molecular chaperones and Protein-Folding Catalysts. M. J. Gething (ed.), Sambrook and Tooze Publications at Oxford University Press, 1997, 255–258.Search in Google Scholar

[48]. Alaoui-Sossé, B.; Parmentier, C.; Dizengremel, P; Barnola, P., Rhythmic growth and carbon allocation in Quercus robur. Starch and sucrose. Plant Physiology and Biochemistry, 1994,32, 331–339.Search in Google Scholar

[49]. Gebre, G. M.; Tschaplinski, T.J., Solute accumulation of chestnut oak and dogwood leaves in response to throughfall manipulation of an upland oak forest. Tree Physiol., 2002,22, 251–260.Search in Google Scholar

[50]. Gebre, G. M.; Kuhns, M. R.; Brandle, J. R., Organic solute accumulation and dehydration tolerance in 3 water-stressed Populus deltoides clones. Tree Physiol., 1994,14, 575–587.Search in Google Scholar

[51]. Cornic, G.; Ghashghaie J., Effect of temperature on net CO₂ assimilation and photosystem II quantum yield of electron transfer of French bean (Phaseolus vulgaris L.) leaves during drought stress. Planta, 1991,185, 255-260.Search in Google Scholar

[52]. Santos, C. V., Regulation of chlorophyll biosynthesis and degradation by salt stress in sunflower leaves. Scientia Horticulturae-Amesterdam,2004,103, 93–99.10.1016/j.scienta.2004.04.009Search in Google Scholar

[53]. Bates L.; Waldren R. P.; Teare I. D., Rapid determination of free proline for water-stress studies. Plant and Soil, 1973,39, 205–207.Search in Google Scholar

[54]. Dubois, M.; Gilles, K.A.; Hamilton J.K; Rebers P.A.; Smith F., Colorimetric method for the determination of sugars and related substances. Anal. Chem., 1956, 28, 350–356.Search in Google Scholar

[55]. Bradford, M. M., A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem., 1976,72, 248-254.10.1016/0003-2697(76)90527-3Search in Google Scholar