Abstract
Male and female cone crop patterns and gender expression inPinus densiflora were examined in three adjacent Korean populations over four to five years. Three parameters — cone ratio, sexual system, and standardized phenotypic gender — were assessed according to cone production. Both male and female cone crops and cone ratios varied by year and by site. After controlling for plant size, population differences in cone crops and cone ratios became stronger. At all three sites, the proportion of trees with differing sexual systems tended to fluctuate among years. Overall, 37% of all tagged trees changed their sexual system at least once, mostly ranging between monoecy and male. These particular trees were relatively small and exhibited slow radial growth compared with the non-sex-changing trees, suggesting a trade-off between vegetative and reproductive growth. Despite annual variations in their standardized phenotypic genders, the rankings of trees remained concordant between successive years at all sites. These results indicate that, inP. densiflora, male and female cone crops and, consequently, gender expression, may be affected by diverse factors that include plant size, trade-offs between vegetative and reproductive growth, and genetic components.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Literature Cited
Allison TD (1990) Pollen production and plant density affect pollination and seed production in Taxuscanadensis. Ecology71: 516–522
Allison TD (1991) Variation in gender expression in Canada yew (Taxus canadensis). Amer J Bot78: 569–578
Apsit VJ, Nakamura RR, Wheeler NC (1989) Differential male reproductive success in Douglas-fir. Theor Appl Genet77: 681–684
Arista M, Talavera S (1997) Gender expression inAbies pinsapo Boiss., a Mediterranean fir. Ann Bot79: 337–342
Bickel AM, Freeman DC (1993) Effects of pollen vector and plant geometry on floral sex ratio in monoecious plants. Amer Midl Nat130: 239–247
Caron GE, Powell GR (1989) Patterns of seed-cone and pollencone production in youngPicea mar/ana trees. Can J For Res19: 359–364
Carrer M, Urbinati C (2004) Age-dependent tree-ring growth responses to climate inLarix decidua andPinus cernbra. Ecology85: 730–740
Costich D (1995) Gender specialization across a climatic gradient: Experimental comparison of monoecious and dioeciousEcballium. Ecology76: 1036–1050
Dickson RL, Sweet GB, Mitchell ND (2000) PredictingPinus radiata female strobilus production for seed orchard site selection in New Zealand. For Ecol Manage133: 197–215
Floyd ME (1983) Dioecy in fivePinus edulis populations in the Southwestern United States. Amer Midl Nat110: 405–411
Freeman DC, McArthur ED, Harper KT (1984) The adaptive significance of sexual lability in plants usingAtriplex canescens as a principal example. Ann Mo Bot Gard71: 265–277
Hanawa J (1966) Growth and development in the shoot apex ofPinus densiflora: I. Growth periodicity and structure of the terminal vegetative shoot apex. Bot Mag Tokyo79: 736–746
Kang H (2005) A five-year study of mast seeding inPinus densiflora. J Plant Biol48: 159–169
Kang H, Yoon J (2000) Cone sex ratio and pollen traits inPinus densiflora (Pinaceae). Kor J Biol Sci4: 131–140
Klinkhamer PCL, de Jong TJ, Metz H (1997) Sex and size in cosexual plants. Trends Ecol Evol12: 260–265
Koenig WD, Mumme RL, Carmen WJ, Stanback MT (1994) Acorn production by oaks in central coastal California: Variation within and among years. Ecology75: 99–109
KMA (Korea Meteorological Administration) (2006) Climate in Korea. http://kma.go.kr/kor/weather/climate/climate_03_01.jsp/ 27 Jan. 2006
Lev-Yadun S, Liphschitz N (1987) The ontogeny of gender ofCupressus sempervirens. L Bot Gaz148: 407–412
Linhart YB, Milton JB (1985) Relationships among reproduction, growth rates, and protein heterozygosity in ponderosa pine. Amer J Bot72: 181–184
Lloyd DG (1980) Sexual strategies in plants: III. A quantitative method for describing the gender of plants. New Zeal J Bot18: 103–108
Lloyd DG, Bawa KS (1984) Modification of the gender of seed plants in varying conditions. Evol Biol17: 255–338
McDowell SC, McDowell NG, Marshall JD, Hultine K (2000) Carbon and nitrogen allocation to male and female reproduction in Rocky Mountain Douglas-fir (Pseudotsuga menziesii var.glauca, Pinaceae). Amer J Bot87: 539–546
Ortiz PL, Arista M, Talavera S (2002) Sex ratio and reproductive effort in the dioeciousJuniperus communis subsp.alpina (Suter) èelak. (Cupressaceae) along an altitudinal gradient. Ann Bot89: 205–211
Rapp M, Cabanettes A (1981) Biomass and productivity of aPinus pinea L. stand,In NS Margaris, HA Mooney, eds, Components of Productivity of Mediterranean-Climate Region — Basic and Applied Aspects. Junk, Hague, pp 131–134
SAS (2004) SAS/STAT8 software. Ver. 9.1, SAS Institute, Cary, USA
Schoen D, Denti D, Stewart SC (1986) Strobilus production in a clonal white spruce seed orchard: Evidence for unbalanced mating. Silvae Genet35: 201–205
Shapcott A, Brown MJ, Kirkpatrick JB, Reid JB (1995) Stand structure, reproductive activity and gender expression in Huon pine (Lagarostrobos franklinii (Hook L.) Quinn.). J Biogeogr22: 1035–1045
Shibata M, Tanaka H, Nakashizuka T (1998) Causes and consequences of mast seed production of four co-occurringCarpinus species in Japan. Ecology79: 54–64
Smith CC, Hamrick JL, Kramer CL (1988) The effects of stand density on frequency of filled seeds and fecundity in lodgepole pinePinus contorta Dougl.). Can J For Res18: 435–460
Sork VL, Bramble J, Sexton O (1993) Ecology of mast-fruiting in three species of North American deciduous oaks. Ecology74: 528–541
Stoll P, Schmid B (1998) Plant foraging and dynamic competition between branches ofPinus sylvestris in contrasting light environments. J Ecol86: 934–945
Stromberg JC, Patten DT (1990) Flower production and floral ratios of a southwestern riparian tree, Arizona walnut (Juglans major). Amer Midl Nat124: 278–288
Tapias R (1998) Estudio de las adaptaciones al fuego dePinus pinaster Ait. de la Sierra del Teleno. Comparación con otras poblaciones dePinus pinaster, P. halepensis, P. nigra yP. Pinea. Ph.D. thesis, Universidad Politécnica de Madrid, Madrid
Trabaud L, Valina J (1998) Importance of tree size inPinus halepensis fire survival,In L Trabaud, J Valina, eds, Fire Management and Landscape Ecology. International Association of Wildland Fire, Fairfield, pp 189–196
Uyeki H (1928) On the physiognomy ofPinus densiflora growing in Korea and sylvicultural treatment for its improvement. Bull Agric for Coll Suwon Korea 3
von Ende CN (2001) Repeated-measures analysis,In SM Scheiner, J Gurevitch, eds, Design and Analysis of Ecological Experiments. Oxford University Press, New York, pp 134–157
Waring RH, Schlesinger WH (1985) Forest Ecosystems. Orlando, Academic Press
Yamashita N, Abe T (2002) Size distribution, growth and inter-year variation in gender expression ofBischofia javanica, an invasive tree. Ann Bot90: 599–605
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Kang, H. Changes in gender expression in korean populations ofPinus densiflora over a five-year period. J. Plant Biol. 50, 181–189 (2007). https://doi.org/10.1007/BF03030628
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF03030628