References
- Bjørnstad Å. 1981. Photoperiodic after-effect of parent plant environment in Norway spruce (Picea abies (L.) Karst seedlings. Reports from Norwegian Forest research Institute No 36, 30 pp.
- Bose AK, Moser B, Rigling A, Lehmann MM, Milcu A, Peter M, et al. 2020. Memory of environmental conditions across generations affects the acclimation potential of Scots pine. Plant Cell Environ. 43:1288–1299.
- Bräutigam K, Vinning KG, Lafon-Placette C, Fossdal CG, Mirouze M, Marcos JG, et al. 2013. Epigenetic regulation of adaptive responses of forest tree species to the environment. Ecol Evol. 3:399–415.
- Dewan S, Mijnsbrugge KV, Fennel PD, Steinecker M, Michael B, Verheyen K. 2018. Maternal temperature during seed maturation affects seed germination and timing of bud set in seedlings of European black poplar. For Ecol Manag. 410:126–135.
- Edvardsen ØM, Johnsen Ø, Dietrichson J. 1996. Growth rhythm and frost hardiness in northern progeny trial with plants from lyngdal seed orchard (In Norwegian with English summary). Research Paper of Skogforsk. 9/96:1–9.
- Gömöry D, Foffová E, Longauer R, Krajmerová D. 2015. Memory effect associated with early-growth environment in Norway spruce and European larch. Eur J Forest Res. 134:89–97.
- Hannerz M, Sonesson J, Ekberg I. 1999. Genetic correlations between growth and growth rhythm observed in a short-term test and performance in long-term field tests of Norway spruce. Can J For Res. 29:768–778.
- Johnsen Ø. 1989a. Phenotypic changes in progenies of northern clones of Picea abies grown in a southern seed orchard. I. frost hardiness in a phytotron experiment. Scand J For Res. 4:317–330.
- Johnsen Ø. 1989b. Phenotypic changes in progenies of northern clones of Picea abies grown in a southern seed orchard. II. seasonal growth rhythm and height in field trials. Scand J For Res. 4:331–341.
- Johnsen Ø, Dæhlen OG, Østreng G, Skrøppa T. 2005a. Daylength and temperature during seed production interactively affect adaptive performance of Picea abies progenies. New Phytol. 168:589–596.
- Johnsen Ø, Fossdal CG, Nagy N, Mølmann J, Dæhlen OG, Skrøppa T. 2005b. Climatic adaptation in Picea abies progenies is affected by the temperature during zygotic embryogenesis and seed maturation. Plant, Cell Environ. 28:1090–1102.
- Johnsen Ø, Skrøppa T, Haug G, Apeland I, Østreng G. 1995. Sexual reproduction in a greenhouse and reduced autumn frost hardiness of Picea abies progenies. Tree Physiol. 15:551–555.
- Johnsen Ø, Skrøppa T, Junttila O, Dæhlen OG. 1996. Influence of female flowering environment on autumn frost-hardiness of Picea abies progenies. Theor Appl Genet. 92:797–802.
- Krutzsch P. 1973. Norway spruce development of buds. IUFRO S2.02.11. 4 p.
- Kvaalen H, Johnsen Ø. 2008. Timing of bud set in Picea abies is regulated by a memory of temperature during zygotic and somatic embryogenesis. New Phytol. 177:49–59.
- Langvall O. 2011. Impact of climate change, seedling type and provenance on the risk of damage to Norway spruce (Picea abies (L.) Karst.) seedlings in Sweden due to early summer frosts. Scand J For Res. 26:56–63.
- SAS Institute. 2003. SAS procedures guide. version 9. Cary, NC: SAS Institute Inc.
- Skrøppa T. 1988. The seed weight did not affect first year’s bud set in Picea abies. Scand J For Res. 3:437–439.
- Skrøppa T. 1994. Growth rhythm and hardiness of Picea abies progenies of high altitude parents from seeds produced at low elevations. Silvae Genet. 43:90–100.
- Skrøppa T, Kohmann K, Johnsen Ø, Steffenrem A, Edvardsen ØM. 2007. Field performance and early test results of offspring from two Norway spruce seed orchards containing clones transferred to warmer climates. Can J For Res. 37:1–8.
- Skrøppa T, Magnussen S. 1993. Provenance variation in shoot growth components of Norway spruce. Silvae Genet. 32:111–120.
- Skrøppa T, Tollefsrud MM, Sperisen C, Johnsen Ø. 2010. Rapid change in adaptive performance from one generation to the next in Picea abies – Central European trees in a nordic environment. Tree Genetics and Genomes. 6:93–99.
- Solvin TM. 2020. Quantification of genetic and epigenetic variation in phenology and growth in Norway spruce. Philosophiae Doctor Thesis 2020:39. Norwegian University of Life Sciences.
- Solvin TM, Steffenrem A. 2019. Modelling the epigenetic response if increased temperature during reproduction on Norway spruce phenology. Scand J For Res. 34:83–93.
- Sow MD, Allona I, Ambroise C, Conde D, Fichot R, Gribkova VJ, et al. 2018. Epigenetics in forest trees: state of the art and potential implications for breeding and management in a context of climate change. Adv Bot Res. 88:387–453.
- Webber JP, Ott J, Owens Binder W. 2005. Elevated temperature during reproductive development affects traits and progeny performance in Picea glauca x engelmannii complex. Tree Physiol. 25:1219–1227.
- Wei RP, Lindgren K, Lindgren D. 2001. Parental effects on cold acclimation and height growth in lodgepole pine seedlings. Silvae Genet. 50:252–257.
- Yakovlev I, Asante DKA, Fossdal CG, Junttila O, Johnsen Ø. 2011. Differential gene expression related to an epigenetic memory affecting climatic adaptation in Norway spruce. Plant Sci. 180:132–139.
- Yakovlev I, Fossdal CG, Skrøppa T, Olsen JS, Jahren A, Johnsen Ø. 2012. An adaptive epigenetic memory in conifers with important implications for seed production. Seed Sci Res. 22:63–76.