Summary
Common garden testing of populations of different origin started with forest trees more than two hundred years ago. Since then, so-called provenance tests have been established with most commercially important species. Beyond the strictly silvicultural goals, the tests offer excellent opportunities to study intraspecific genetic variation patterns and represent probably the most powerful available tool for testing hypotheses of climatic adaptation in trees.
Analysis of adaptive traits (mostly juvenile height growth) in provenance experiments indicate the existence of very effective constraints on adaptedness. The performance of populations plotted against an ecological-climatic factor exhibits a characteristic pattern and can be described by response functions. The population average of a fitness-related trait for a locally adapted population is often significantly lower than that of populations from other environments; usually the ones from milder climate perform better. The phenomenon is interpreted as adaptation lag. Suboptimal adaptation is compensated by a high level of genetic diversity. Molecular genetic studies confirm the high level of allelic and individual genetic diversity in forest trees. A consequence of individual homeostasis, phenotypic stability of populations is usually also high; the sensitivity to environmental changes is generally moderate. Phenotypically stable populations are valuable not only because of a wider range of potential cultivation but specifically because of a greater ability to adjust to unexpected changes. This trait should receive more attention in the future for obvious reasons.
The maintenance of a high within-population genetic variance is favored by the genetic system of the investigated species (effective gene flow, outbreeding, high genetic load, etc.). Random events and long-lasting biotic interactions are further effects impairing the efficiency of natural selection.
In view of expected climate instability, genetic adaptability of forest trees causes serious concern due to their long lifespan compared to the rapidity of expected changes in environmental conditions. The potential of provenance tests to interpret long-term adaptational processes should be utilized to analyze, model and predict response of trees to climate change. Although seldomly appreciated, provenance research might be among the most important contributions of forestry to biological sciences.
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References
Ayala R.J., 1969. An evolutionary dilemma: fitness of genotypes versus fitness of population. Canad. J. Genet. Cytol. 11: 439–456.
Bergmann F. & H.R. Gregorius, 1993. Ecogeographical distribution and thermostability of isocitrate dehydrogenase (IDH) allozymes in European silver fir (Abies alba). Biochem. Syst. Ecol. 21: 597–605.
Clausen, J., D.D. Keck & W.M. Hiesey, 1940, 1945, 1948, 1958. Experimental studies on the nature of species. Vol. 1 to IV. Carnegie Inst. Publ. Nr. 520, 564, 581 and 615, Washington, D.C.
Dormling, I., 1979. Influence of light intensity and temperature on photoperiodic response of Norway spruce provenances. Proc. IUFRO Norway Spruce Breeding Conf., Bucharest, 398–408.
Durand, R., 1984. L'arboretum National des Barres. Paris.
Ericsson, G., 1980. Severity index and transfer effects on survival and volume production of Pinus silvestris in Northern Sweden. Stu. For. Suec. Nr. 156.
Glertych M., 1979. Summary of results of Scots pine height growth in IUFRO provenance experiments. Silvae Gen. 28 (4): 136–152.
Glertych M. & J.L. Farrar, 1962. A provenance study of jack pine seedlings. Silvae Gen. 11: 111–114.
Giertych M. & J. Oleksyn, 1981. Summary of results on Scots pine volume production in Ogievskij's pre-revolutionary Russian provenance experiments. Silvae Gen. 30 (2–3): 57–74.
Hamrick, J.L. & M.J. Godt, 1990. Allozyme diversity in plant species. In: A.H.D. Brown, M.T. Clegg, A.L. Kahler & B.S. Weir (Eds). Plant population genetics, breeding and genetic resources. pp. 43–63. Sinauer Ass.
Hiesey, W.M., J. Clausen & D.D. Keck, 1942. Relations between climate and intraspecific variation in plants. Am. Natur. 72.
Koski V., 1991. Generative reproduction and genetic processes in nature. In: M. Giertych & Cs. Mátyás (Eds). Genetics of Scots pine. pp. 59–72. Elsevier Publ. & Akademiai Kiado Budapest.
Koski, V. & M. Sievänen, 1985. Timing of growth cessation in relation to the variations in the growing season. In: P.M.A. Tigerstedt, P. Puttonen & V. Koski (Eds). Crop Physiology of Forest Trees. pp. 167–193. Helsinki Univ. Press.
Kung, F.H., 1981. Delineating seed collection zones based on multiplantation provenance tests. Proc. 16th South. For. Tree Impr. Conf. May 22–28, 1981. pp. 83–96. Virginia, USA.
Langlet O., 1971. Two hundred years of genecology. Taxon 20 (5/6): 653–722.
Ledig F.T., 1986. Heterozygosity heterosis and fitness in outbreeding plants. In: M. Soule (Ed). Conservation biology: the science of scarcity and diversity. pp. 77–106. Sinauer Assoc., Sunderland, Mass.
Ledig, F.T., 1992. Genecology: the fitness of the organism and the fitness of the environment. Proc. 12th North Am. For. Biol. Workshop, Aug. 17–20, 1992. pp. 27–49. Sault Ste Marie, Ont., Canada.
Ledig F.T. & J. Kitzmiller, 1992. Genetic strategies for reforestation in the face of global climate change. For Ecol. Manage. 50: 153–169.
Lindgren, D. & A. Persson, 1995. Vitalization of results from provenance tests. Proc. XXth IUFRO World Congr., Tampere (in press).
Mátyás Cs., 1981. Phenological variability of East European Scots pine provenances. Erdészeti Kutat., Budapest, 74: 71–80 (in Hungarian).
Mátyás Cs., 1986. Improved planting stock in forestry. Akademiai Publ., Budapest (in Hungarian).
Mátyás, Cs., 1987. Adaptation processes in forest tree populations. Dr. Sci. Thesis, Sopron, 195 pp. (in Hungarian).
Mátyás, Cs., 1989. Genetic and ecological constraints of adaptation. Proc. IUFRO Int. Symp. on Forest Genetics, Breeding and Physiology. pp. 79–90. Voronezh, USSR.
Mátyás, Cs., 1991. Adaptation lag: a general feature of natural populations. Proc. Joint Meeting of WFGA and IUFRO Working Parties, Olympia, Wa. (USA) Aug. 20–25, 1990. Pap. Nr. 2.226.
Mátyás Cs., 1994. Modeling climate change effects with provenance test data. Tree Physiol. 14: 797–804.
Mátyás Cs., 1995. Climate of the Sierras. Unpubl. report, USDA PSW Expt. Sta., IFG Placerville, 30 pp.
Mátyás Cs. & C.W. Yeatman, 1987: Adaptive variation of height growth of Pinus banksiana populations. Erd. Faip. Egy. Közl. 1–2: 191–197 (in Hungarian).
Mátyás Cs. & C.W. Yeatman, 1992. Effects of geographical transfer on growth and survival of jack pine populations. Silvae Gen. 43 (6): 370–376.
Mitton J.B. & M.C. Grant, 1984. Associations among protein heterozygosity, growth rate, and developmental homeostasis. Ann. Rev. Ecol. Syst. 15: 479–499.
Morgenstern E.K., 1978. Range-wide variation of black spruce. Can. J. For. Res. 8: 463–473.
Müller-Starck G., 1991. Genetic processes in seed orchards. In: M. Giertych & Cs. Mátyás (Eds). Genetics of Scots pine. pp. 147–162. Elsevier Publ. & Akademiai Kiadó Budapest.
Parsons P.A., 1987. Evolutionary rates under environmental stress. Evol. Biol. 21: 311–347.
Powers D.A., T. Lauerman, D. Crawford & L. DiMichele, 1991. Genetic mechanisms for adapting to a changing environment. Ann. Rev. Genet. 25: 629–659.
Prokazin E.P. & A.V. Bogachev, 1975. Hereditary adaptation of Scots pine to climate factors and possibilities of its assessment and prognosis. In: Genetics, selection and seed production. VNIILM, Pushkino (USSR) (in Russian).
Prus-Glowacky W., 1991. Biochemical polymorphism. In: M. Giertych & Cs. Mátyás (Eds). Genetics of Scots pine. pp. 73–81. Elsevier Publ. & Akademiai Kiadó Budapest.
Raymond, C.A. & D. Lindgren, 1986. A model of genetic flexibility. In: D. Lindgren (Ed). Provenances and forest tree breeding for high latitudes. pp. 159–177. Kempe Symp. Rapp. 6, Umea.
Rehfeldt G.E., 1988. Ecological genetics of Pinus contorta from the Rocky Mountains (USA): a synthesis. Silvae Gen. 37 (3–4): 131–135.
Sarvas, R., 1972, 1974. Investigations on the annual cycle of development of forest trees. Part I and II. Comm. Inst. For Fenniae 76.3 and 84.1.
Savolainen O., 1994. Genetic variation and fitness: conservation lessons from pines. In: V. Loeschke, I. Tomink & S.K. Jain (Eds). Conservation genetics. pp. 27–36. Birkhauser Verl., Basel.
Scheiner S.M., 1993. Genetics and evolution of phenotypic plasticity. Ann. Rev. Ecol. Syst. 23: 1–14.
Schmidtling, R.C., 1995. Developing a seed transfer model for short-leaf pine. Proc. 8th Bienn. South. Silvic. Conf. Auburn AL, Nov. 1994 (in press).
Sorensen, F.C. & J.C. Weber, 1994. Genetic variation and seed transfer guidelines for ponderosa pine in the Ochoco and Malheur National Forests of Central Oregon. USDA Dor. Serv. Res. Pap. PNW-RP 468.
Tigerstedt, P.M.A., 1992. Why do exotic trees often exceed the yield of endemic trees? In: D. Lindgren (Ed). Pinus contorta—from untamed forests to domesticated crop. pp. 60–68. Umea.
Timofeev V.P., 1973. Growth traits of Scots pine of various origin at the forest experimental fields of the Timiryazev Agric. Academy. Izd.-vo Kolos, Moscow, 2: 130–146 (in Russian).
Vaartaja O., 1959. Evidence of photoperiodic ecotypes in trees. Ecol. Monogr. 29: 91–111.
Weisgerber H., W. Dietze, J. Kleinschmidt, J. Racz, H. Dietrich & R. Dimpflmeier, 1976. Ergebnisse des internationalen Fichten-Provenienzversuches '1962. Teil 1: Phenologische Beobachtungen und Höhenwachstum bis zur ersten Freilandaufnahme. Allg. Forst- und Jagdztg. 147: 227–235.
Wright J.W. & W.I. Bull, 1963. Geographic variation in Scots pine. Silvae Gen. 12: 1–40.
Yeatman, C.W., 1966. Geographic variation in jack pine seedlings. Ph.D. Thesis. 128 pp.
Ying, Ch.C. & K. Illingworth, 1986. Lodgepole pine provenance research in northwestern Canada with particular reference to the Yukon territory. In: D. Lindgren (Ed). Provenances and forest tree breeding for high latitudes. pp. 189–200. Kempe Symp. Rapp. 6, Umea.
Ying Ch.C. & Q. Liang, 1994. Geographic pattern of adaptive variation of lodgepole pine within the species' coastal range: field performance at age 20 years. Forest Ecol. Manage. 67: 281–298.
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Mátyás, C. Climatic adaptation of trees: rediscovering provenance tests. Euphytica 92, 45–54 (1996). https://doi.org/10.1007/BF00022827
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DOI: https://doi.org/10.1007/BF00022827