Variation in needle and cone traits in natural populations of Pinus yunnanensis

Yulan Xu; Keith Woeste; Nianhui Cai; Xiangyang Kang; Genqian Li; Shi Chen; Anan Duan

doi:10.1007/s11676-015-0153-6

Journal of Forestry Research ›› 2015, Vol. 27 ›› Issue (1) : 41 -49. DOI: 10.1007/s11676-015-0153-6

Original Paper

Variation in needle and cone traits in natural populations of Pinus yunnanensis

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Abstract

Pinus yunnanensis Franch. is a major component of coniferous forests in southwestern China. Little is known about its intraspecific variation. Morphological variations in needle and cone traits of P. yunnanensis were analyzed to quantify variability among and within natural populations. Seven traits were measured on 10 needles collected from 30 trees in each of the 18 sampled populations of P. yunnanensis. Four cone traits were measured in 221 individual trees from nine populations. The results showed that there were significant differences (p < 0.01) both among populations and within populations in each needle and cone trait. The proportion of phenotypic variation of nearly all needle and cone traits was over 50 % within populations, which showed trees within populations accounted for a majority of the total variation. The needle traits showed higher variability within population than cone traits. Variability in the needle traits was correlated with geo-climatic parameters (longitude, latitude, altitude, temperature, and precipitation). Needle length and the ratio of needle length to fascicle sheath length showed clinal variation in response to latitudinal and altitudinal gradients. A hierarchical classification of all populations based on needle traits led to the formation of four major groups. The findings provide important genetic information for the evaluation of variation. Moreover, it will assist in management of genetic diversity of P. yunnanensis.

Keywords

Genetic diversity / Conservation / Yunnan pine / Cone morphology / Needle morphology

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Yulan Xu, Keith Woeste, Nianhui Cai, Xiangyang Kang, Genqian Li, Shi Chen, Anan Duan. Variation in needle and cone traits in natural populations of Pinus yunnanensis. Journal of Forestry Research, 2015, 27(1): 41-49 DOI:10.1007/s11676-015-0153-6

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Alberto FJ, Aitken SN, Alia R, González-Martínez SC, Hänninen H, Kremer A, Lefèvre F, Lenormand T, Yeaman S, Whetten R, Savolainen O. Potential for evolutionary responses to climate change—evidence from tree populations. Glob Change Biol, 2013, 19(6): 1645-1661.

[2]	Ali MA, Jabran K, Awan SI, Abbas A, Ehsanullah ZM, Acet T, Farooq J, Rehman A. Morpho-physiological diversity and its implications for improving drought tolerance in grain sorghum at different growth stages. Aust J Crop Sci, 2011, 5(3): 311-320.

[3]	Beaulieu J, Simon JP. Variation in cone morphology and seed characters in Pinus strobus in Quebec. Can J Bot, 1995, 73(2): 262-271.

[4]	Bobowicz MA, Radziejewska A. The variability of Scots pine from Piekielna Gora as expressed by morphological and anatomical traits of needles. Acta Soc Bot Pol, 1989, 58(3): 375-384.

[5]	Boratyńska K, Jasińska AK, Ciepłuch E. Effect of tree age on needle morphology and anatomy of Pinus uliginosa and Pinus silvestris: species-specific character separation during ontogenesis. Flora, 2008, 203(8): 617-626.

[6]	Boulli A, Baaziz M, M’Hirit O. Polymorphism of natural populations of Pinus halepensis Mill. in Morocco as revealed by morphological characters. Euphytica, 2001, 119: 309-316.

[7]	Calamassi R, Puglisi SR, Vendramin GG. Genetic variation in morphological and anatomical needle characteristics in Pinus brutia Ten. Silv Genet, 1988, 37(5–6): 199-206.

[8]	Chen SH, Wu JK. A preliminary study on the seed division of Pinus yunnanensis. J Southwest For Coll, 1987, 2: 1-6.

[9]	Chinese Academy of Sciences Flora of China. 1978, Beijing: Science Press, 255 259

[10]	Dangasuk OG, Panetsos KP. Altitudinal and longitudinal variations in Pinus brutia (Ten.) of Crete Island, Greece: some needle, cone and seed traits under natural habitats. New For, 2004, 27: 269-284.

[11]	De Vall WB. A diagnostic taxonomic constant for separating slash and longleaf pines. Proc Fla Acad Sci, 1940, 4: 113-115.

[12]	Donahue JK, Upton JL. Geographical variation in leaves, cone and seeds of Pinus gregii in native forests. For Ecol Manag, 1996, 82: 145-157.

[13]	Forde MB. Variation in natural populations of Pinus radiata in California. Part 3. Cone characters. NZ J Bot, 1964, 2: 459-485.

[14]	Gil L, Climent J, Nanos N, Mutke S, Ortiz I, Schiller G. Cone morphology variation in Pinus canariensis Sm. Plant Syst Evol, 2002, 235: 35-51.

[15]	Hamrick JL, Linhart YB, Mitton JB. Relationships between life history characteristics and electrophoretically detectable genetics variation in plants. Annu Rev Ecol Syst, 1979, 1: 173-200.

[16]	Hijmans RJ, Cameron SE, Parra JL, Jones PG, Jarvis A. Very high resolution interpolated climate surfaces for global land areas. Int J Climatol, 2005, 25: 1965-1978.

[17]	Ji M, Zhang Q, Deng J, Zhang X, Wang Z. Intra-versus inter-population variation of cone and seed morphological traits of Pinus tabulaeformis Carr. in northern China: impact of climate-related conditions. Pol J Ecol, 2011, 59(4): 717-727.

[18]	Jin ZZ, Peng J. Yunnan Pine (Pinus yunnanensis Franch.). 2004, Kunming: Yunnan Science and Technology Press, 1 66

[19]	Leinonen T, Cano JM, Mäkinen H, Merilä J. Contrasting patterns of body shape and neutral genetic divergence in marine and lake populations of three spine sticklebacks. J Evol Biol, 2006, 19: 1803-1812.

[20]	Leinonen T, O’hara RB, Cano JM, Merilä J. Comparative studies of quantitative trait and neutral marker divergence: a meta-analysis. J Evol Biol, 2008, 21: 1-17.

[21]	Li BD. The distribution of forest of Pinus yunnanensis and its areal areas. J Yunnan Univ, 1984, 1: 33-56.

[22]	Li LF, Zheng W, Han MY, Su JW. Progress of genetic improvement of Pinus yunnanensis and breeding strategy analysis. J West China For Sci, 2010, 39(2): 4-7.

[23]	Loha A, Tigabu M, Teketay D, Lundkvist K, Fries A. Provenance variation in seed morphometric traits, germination, and seedling growth of Cordia africana Lam.. New For, 2006, 32: 71-86.

[24]	López R, López de Heredia U, Collada C, Cano FJ, Emerson BC, Cochard H, Gil L. Vulnerability to cavitation, hydraulic efficiency, growth and survival in an insular pine (Pinus canariensis). Ann Bot, 2013, 111: 1167-1179.

[25]	Maley ML, Parker WH. Phenotypic variation in cone and needle characters of Pinus banksiana (jack pine) in northwestern Ontario. Can J Bot, 1993, 71(1): 43-51.

[26]	Melzack RN, Grunwald C, Schiller G. Morphological variation in Aleppo pine (Pinus halepensis Mill.) in Israel. Isr J Bot, 1981, 30(4): 199-205.

[27]	Panetsos CP. Natural hybridization between Pinus halepensis and Pinus brutia in Greece. Silv Genet, 1975, 24(5–6): 163-168.

[28]	Pham TD, Thi Nguyen TD, Carlsson AS, Bui TM. Morphological evaluation of sesame (Sesamum indicum L.) varieties from different origins. Aust J Crop Sci, 2010, 4(7): 498-504.

[29]	Piedra ET. Geographic variation in needles, cones and seeds of Pinus tecunumanii in Guatemala. Silv Genet, 1984, 33(2/3): 72-79.

[30]	Raeymaekers JAM, Van Houdt JKJ, Larmuseau MHD, Geldof S, Volckaert FAM. Divergent selection as revealed by P _ST and QTL-based F _ST in three-spined stickleback (Gasterosteus aculeatus) populations along a coastal-inland gradient. Mol Ecol, 2007, 16: 891-905.

[31]	Rawat K, Bakshi M. Provenance variation in cone, seed and seedling characteristics in natural populations of Pinus wallichiana A.B. Jacks (Blue Pine) in India. Ann For Res, 2011, 54(1): 39-55.

[32]	Roy SM, Thapliyal RC, Phartyal SS. Seed source variation in cone, seed and seedling characteristics across the natural distribution of Himalayan low level pine Pinus roxburghii Sarg.. Silv Genet, 2004, 53(3): 116-128.

[33]	Sevık H, Ayan S, Turna I, Yahyaoglu Z. Genetic diversity among populations in Scotch pine (Pinus silvestris L.) seed stands of Western Black Sea Region in Turkey. Afr J Biotechnol, 2010, 9(43): 7266-7272.

[34]	Singh O, Thapliyal M. Variation in cone and seed characters in blue pine (Pinus wallichiana) across natural distribution in western Himalayas. J For Res, 2012, 23(2): 235-239.

[35]	Spitze K. Population-structure in Daphnia obtusa: quantitative genetic and allozymic variation. Genetics, 1993, 135: 367-374.

[36]	Steel RG, Torrie JH, Dickey DA. Principles and procedures of statistics. 1960, New York: McGrow-Hill Book Company Inc., 481.

[37]	Turna I, Güney D. Altitudinal variation of some morphological characters of Scots pine (Pinus sylvestris L.) in Turkey. Afr J Biotechnol, 2009, 8(2): 202-208.

[38]	Turna I, Yahyaoglu Z, Yüksek F, Ayaz FA, Guney D. Morphometric and electrophoretic analysis of 13 populations of Anatolian black pine in Turkey. J Environ Biol, 2006, 27(3): 491-497.

[39]	Urbaniak L, Karliński L, Popielarz R. Variation of morphological needle characters of Scots pine (Pinus silvestris L.) populations in different habitats. Acta Soc Bot Pol, 2003, 72(1): 37-44.

[40]	Vasudeva R, Hanumantha M, Gunaga RP. Genetic variation for floral traits among teak (Tectona grandis Linn.f.) clones: implications to seed orchard fertility. Curr Sci, 2004, 87: 358-362.

[41]	Wahid N, González-Martínez SC, El Hadrami I, Boulli A. Variation of morphological traits in natural populations of maritime pine (Pinus pinaster Ait.) in Morocco. Ann For Sci, 2006, 63: 83-92.

[42]	Wang CM, Wang J, Jiang HQ. A study on comparative morphology of Pinus yunnanensis needles under different habitats. J Southwest For Coll, 2003, 23: 4-7.

[43]	Wang CM, Wang J, Jiang HQ. A study on comparative anatomy of Pinus yunnanensis needles under different habitats. J Southwest For Coll, 2004, 24: 1-5.

[44]	Wu ZY. Flora Yunnanica (Tomus 4): Spermatophyta. 1986, Beijing: Science Press, 54 57

[45]	Yu H, Ge S, Huang RF, Jiang HQ. A preliminary study on genetic variation and relationships of Pinus yunnanensis and its closely related species. Acta Bot Sin, 2000, 42: 107-110.