تغییرات تنوع اکوتیپی جمعیت های گونه بلندمازو در طول گرادیان خشکی (غربی-شرقی) استان گلستان

 1.Ali Ahmad Korori, S. 1999. Investigation on responses of forest trees enzymes to alteration of environmental factors. Research Institute of Forests and Rangelands. Press, 333p. (In Persian) 2.Alikhani, L., Rahmani, M.S.,
Shabanian, N., and Badakhshan, H. 2014. Genetic diversity assessment of Quercus infectoria and Q. libani populations in North-Zagros forests based on ISSR and IRAP markers. Iranian J. of Rangelands and Forests Plant Breeding and Genetic Research. 22: 1. 79-90. (In Persian)

3.Babaie, F., Jalali, S.G., and Azadfar, D. 2010. Genetic variation investigation on Zelkova carpinifolia, from three Iranian north lowland habitats using leaf peroxidase. Iranian J. of Rangelands and Forests Plant Breeding and Genetic Research. 18: 1. 83-92. (In Persian)

4.Berg, E.E., and Hamrick, J.L. 1993. Regional genetic variation in Turkey oak, Quercus laevis. Canadian J. of Forest Research. 23: 7. 1270-1274.

5.Chen, D.M., Zhang, X.X., Kang, H.Z., Sun, X., Yin, S., Du, H.M., Yamanaka, N., Gapare, W., Wu, H.X., and Liu,
C.J. 2012. Phylogeography of Quercus variabilis based on chloroplast DNA sequence in East Asia: multiple glacial refugia and Mainland-Migrated island populations. Open Access Scientific J. of Public Library of Science ONE.7: 10. e47268.

6.Craft, J., and Ashley, V. 2007. Landscape genetic structure of bur oak (Quercus macrocarpa) savannas in Illinois. Forest Ecology and Management. 239: 13-20.

7.Ebermann, R., and Stich, K. 1982. Peroxidase and amylase isoenzymes in the sapwood and heartwood of trees. Phytochemistry. 21: 2401-2402.

8.Elena-Rossello, J.A., and Cabrera, E. 1996. Isozyme variation in natural populations of Cork-Oak (Quercus suber L.). Silva Genetica. 45: 4. 229-235.

9.Fallah, H., Tabari, M., and Azadfar, D. 2011. Determination ecotypes of Populus caspica Bornm. In plain communities of Caspian forests using morphological markers of leaf and peroxidase isoenzymes. Taxonomy and Biosystematics. 3: 6. 48-57. (In Persian)

10.Ghandehari, V., Ahmadikhah, A., and Payamnoor, V. 2013. Genetic diversity of Buxus hyrcana populations in north of Iran using ISSR markers. Iranian J. of Rangelands and Forests Plant Breeding and Genetic Research. 21: 1. 1-12.
(In Persian)

11.Ghelichkhani, M.M., Tabari, M., Akbarinia, M., and Espahbodi, K. 2006. Influence of light intensity and root pruning on growth. Pajouesh and Sazandegi. 66: 2-7. (In Persian)

12.Gomory, D., Yakovlev, I., Zhelev, P., Jedinakova, J., and Paule, L. 2001. Genetic differentiation of oak populations within the Quercus robur / Quercus petraea complex in Central and Eastern Europe. The Genetics Society of Great Britain. 86: 557-563.

13.Hafezi Shahrudiyan, S. 2010. Genetic diversity of Cupressus sempervirens in stands of north of Iran using molecular and biochemical markers. M.Sc. thesis, Forestry and Wood Technology Faculty, Gorgan University of Agricultural
and Natural Resources Sciences, 188p. (In Persian)

14.Hampe, A., and Petit, RJ. 2005. Conserving biodiversity under climate change, the rear edge matters. Ecology Letters. 8: 461-467.

15.Hamrick, J.L., and Godt, M.J.W. 1996. Conservation genetics of endemic plant species, In: Avise, J.C., Hamrick, J.L. (Eds.), Conservation Genetics: Case Histories from Nature. Chapman and Hall, New York.

16.Hatziskakis, S., Tsiripidis, I., and Papageorgiou, A.C. 2011. Leaf morphological variation in beech (Fagus sylvatica L.) populations in Greece and its relation to their post-glacial origin. Botanical J. of the Linnean Society.165: 422-436.

17.Jiang, Zh., Yuxia, Ch., and Ying, B. 2012. Population genetic structure of Tamarix chinensis in the Yellow River Delta, China. Plant Systematics and Evolution, 298: 147-153.

18.Jimenez, P., Agundez, D., Alla, R., and Gil, L. 1999. Genetic variation in central and marginal populations of Quercus suber L. Silvae Genetica. 48: 6. 278-284.

19.Karimi, L., and Azadfar, D. 2011. Consideration and comparison of genetic diversity of English yew species (Tamarix baccata L.) by using branch and leaf peroxidase. Iranian Journal of Rangelands and Forests Plant Breeding and Genetic Research. 18: 2. 227-238. (In Persian)

20.Kiyani, B. 2005. Forest genetic (Development of tree and forest). Haghshenas Press, Rasht, 212p. (In Persian)

21.Mahmoodi Zarinabadi, M.B., Azadfar, D., and Saeedi, Z. 2014. Comparison of the efficiency of leaf morphological and peroxidase isozyme markers in segregation of Fagus orientalis Lipsky plus and non-plus trees in Shastkalate forest-Gorgan. J. of Wood and Forest Science and Technology. 20: 4. 197-210. (In Persian)

22.Mirderikvand, M., Nematzadeh, Gh.A., Alami, A., and Ghereh yazi, B. 2005. Study of the genetic diversity of Iranian rice using Isozyme markers. Iranian J.of Agriculture sciences. 35: 143-153.(In Persian)

23.Monerri, C., and Guardiola, J. 2001. Peroxidase activity and isoenzyme profile in buds and leaves in relation to flowering in Satsuma mandarin. Scientia Horticulturae. 90: 1-2. 43-56.

24.Naderi Shahab, M.A. 2013. Iran oaks. Azad Peyma Press, Tehran, 305p. (In Persian)

25.Neale, D.B., and Kremer, A. 2011. Forest tree genomics: growing resources and applications. Nature Reviews Genetics. 12: 111-122.

26.Ningre, F., and Colin, F. 2007.Frost damage on the terminal shoot as a risk factor of fork incidence on common beech (Fagus sylvatica L.). Annals of Forest Science. 64: 79-86.

27.Ohsawa, T., Saito, Y., Sawada, H., and Ide, Y. 2008. Impact of altitude and topography on genetic diversity of Quercus serrate populations in the Chichibu Mountains, central Japan. Flora–Morphology, Distribution, Functional Ecology of Plants. 203: 187-196.

28.Okaura, T., Quang, N.D., Ubukata, M., and Harada, K. 2007. Phylogeographic structure and late quaternary population history of the Japanese oak Quercuse mongolica var. crispula and related species revealed by chloroplast DNA variation. Genes and Genetic Systems. 82: 465-477.

29.Peakall, R., and Smouse, P.E. 2006. GENALEX 6.2: genetic analysis in Excel. Population genetic software for teaching and research. Molecular Ecology Notes. 6: 288-295.

30.Petit, R.J., Csaikl, U.M., Bordacs, S., Burg, K., Coart, E., Cottrell, J., Dam, B.V., Deans, J.D., Dumolin-Lapegue, S., Fineschi, S., Finkeldey, R., Gillies, A., Glaz, I., Goicoechea, P.G., Jensen, J.S., Konig, A.O., Lowe, A.J., Madsen, S.F., Matyas, G., Munro, R.C., Olalde, M., Pemonge, M., Popescu, F., Slade, D., Tabbener, H., Taurchini, D., Vries, S.G., Ziegenhagen, B., and Kremer, A. 2002. Chloroplast DNA variation in European white oaks phylogeography and patterns of diversity based data from over
2600 populations. Forest Ecology and Management. 156: 5-26.

31.Rahmani, A., Seighali, N., and Ebrahimzadeh, H. 2014. Exploring the changes of peroxidase activity in different concentrations of H₂O₂ and different amounts of pH in Saffron in sleep-wake. New Cellular and Molecular Biotechnology J. 3: 10. 79-84. (In Persian)

32.Reisi, Sh., Jalali, S.Gh.A., and Espahbodi, K. 2011. An investigation of genetic variation of (Quercus castaneifolia C.M Mey) in Neka and Noor forest of Mazandaran using peroxides activities. Taxonomy and Biosystematics. 3: 7. 11-22. (In Persian)

33.Rohlf, F.J. 1998. NTSYS-pc ver. 2.02. Numerical taxonomy and multivariate analysis system. Exeter Publishing, Setauket.

34.Ruhimoghadam, A., Hoseini, S.M., Ebrahimi, A., Rahmani, A., and Tabari, M. 2008. The effect of mixing rates on qualitative and quantitative characteristics of oak-Zelkova plantation. Pajouesh va Sazandgi. 77: 155-168. (In Persian)

35.Sabeti, H. 2004. Trees and shrubs of Iran. Yazd University Press, 876p.(In Persian)

36.Sakka, H., Baraket, G., Abdessemad, A., Tounsi, K., Ksontini, M., and Salhi-Hannachi, A. 2015. Molecular phylogeny and genetic diversity of Tunisian Quercus species using chloroplast DNA CAPS markers. Biochemical Systematic and Ecology. 60: 258-265.

37.Samuel, R., Pinsker, W., and Ehrendorfer, F. 1995. Electrophoretic analysis of genetic variation within and between populations of Quercus cerris, Q. pubescens, Q. petraea and Q. robur (Fagaceae) from Eastern Austria. Botanica Acta. 108: 4. 290-299.

38.Shabanian, N., Alikhani, L., and Rahmani, M.S. 2015. Phenotypic and genotypic diversity in brant oak (Quercus brantii) populations of declining north-Zagros forests using biochemical characteristics and molecular SCoT marker. Iranian J. of Rangelands and Forests Plant Breeding and Genetic Research. 23: 1. 13-29.(In Persian)

39.Shabanian, N., Havasi, A., and Mehrabi, A.A. 2016. Genetic differentiation in Persian oak (Quercus brantii) populations using genomic inter-microsatellite markers. Iranian Journal of Rangelands and Forests Plant Breeding and Genetic Research.24: 1. 66-78. (In Persian)

40.Shiran, B., Mashayekhi, S., Jahanbazi, H,. Soltani, A., and Bruschi, P. 2011. Morphological and molecular diversity among populations of Quercus brantii Lindl. In western forest of Iran. Plant Biosystems-An International Journal Dealing with all Aspects of Plant Biology: Official J. of the Societa Botanica Italiana. 145: 2. 452-460.

41.Whitham, T.G., Bailey, J.K., Schweitzer, J.A., Shuster, S.M., Bangert, R.K., LeRoy, C.J., Lonsdorf, E.V., Allan, G.J., DiFazio, S.P., Potts, B.M., Fischer, D.G., Gehring, C.A., Lindroth, R.L., Marks, J.C., Hart, S.C., Wimp, G.M., and Wooley, S.C. 2006. A framework for community and ecosystem genetics: from genes to ecosystems. Nature Reviews Genetics. 7: 510-523.

42.Zhang, X., Li, Y., Liu, C., Xia, T., Zhang, Q., and Fang, Y. 2015. Phytogeography of the temperate tree species Quercus acutissima in China: Inferences from chloroplast DNA variations. Biochemical Systematic and Ecology. 63: 190-197.