Landscape gradient of autumn photosynthetic decline in Abies sachalinensis seedlings

doi:10.1007/s11676-022-01592-0

Abstract

Abstract:

Understanding what environmental factors are genetically linked to a phenological event is critical for predicting responses to climate change. Photosynthetic phenology often varies among a species of evergreen conifers due to local adaptation. However, few empirical studies have revealed relevant relationships between climatic factors in provenance environments and photosynthetic phenology. This study evaluated the effects of environmental conditions of the growing site and seed source provenance on the seasonal changes in maximal photochemical quantum yield of photosystem II (F _v/F _m) in a common garden experiment with 2-year-old seedlings of Sakhalin fir (Abies sachalinensis), a representative species with local adaptation, from four seed source provenances. A logistic model was constructed to explain the seasonal variation of F _v/F _m from July to October and the relationships between the estimated model parameters and representative factors featuring provenance environments were evaluated. The landscape gradient of the detected model parameters responsible for the provenance environments was visualized in a map of the distribution area. The lowest temperature was the most plausible factor in the growing environment to explain the seasonal changes of F _v/F _m. Among the representative meteorological factors of provenance environments, the lowest temperatures in July showed significant relationships with two model parameters, explaining the lower limit of F _v/F _m and the higher sensitivity of autumn F _v/F _m decline. The estimated spatial maps of model parameters consistently showed that the higher the lowest temperature in July in the provenance environment, the lower the F _v/F _m in October and the greater the decrease in the autumn F _v/F _m decline. Therefore, the lowest summer temperature could be associated with the local adaptation of autumn photosynthetic phenology in A. sachalinensis.

Key words: Phenology, Local adaptation, Genetic cline, Lowest temperature

Tetsuto Sugai, Wataru Ishizuka, Toshihiro Watanabe. Landscape gradient of autumn photosynthetic decline in Abies sachalinensis seedlings[J]. JOURNAL OF FORESTRY RESEARCH, 2023, 34(1): 187-195.

Tetsuto Sugai, Wataru Ishizuka, Toshihiro Watanabe. [J]. 林业研究(英文版), 2023, 34(1): 187-195.

References 28

1	Adams WW, Demmig-Adams B. The xanthophyll cycle and sustained thermal energy dissipation activity in Vinca minor and Euonymus kiautschovicus in winter. Plant Cell Environ, 1995, 18(2): 117-127, DOI
2	Aitken SN, Adams WT. Genetics of fall and winter cold hardiness of coastal Douglas-fir in Oregon. Can J For Res, 1996, 26(10): 1828-1837, DOI
3	Aitken SN, Whitlock MC. Assisted gene flow to facilitate local adaptation to climate change. Annu Rev Ecol Evol Syst, 2013, 44(1): 367-388, DOI
4	Busch F, Huner NP, Ensminger I. Increased air temperature during simulated autumn conditions does not increase photosynthetic carbon gain but affects the dissipation of excess energy in seedlings of the evergreen conifer Jack pine. Plant Physiol, 2007, 143(3): 1242-1251, DOI
5	Casmey M, Hamann A, Hacke UG. Adaptation of white spruce to climatic risk environments in spring: implications for assisted migration. For Ecol Manag, 2022, 525(1): 120555, DOI
6	Chang CYY, Bräutigam K, Hüner NP, Ensminger I. Champions of winter survival: cold acclimation and molecular regulation of cold hardiness in evergreen conifers. New Phytol, 2021, 229(2): 675-691, DOI
7	Csilléry K, Ovaskainen O, Sperisen C, Buchmann N, Widmer A, Gugerli F. Adaptation to local climate in multi-trait space: evidence from silver fir (Abies alba Mill.) populations across a heterogeneous environment. Heredity, 2020, 124(1): 77-92, DOI
8	Eiga S. Ecogenetical study of the freezing resistance of Saghalin fir (Abies sachalinensis MAST.) in Hokkaido. Bull For Tree Bree Inst, 1984, 2(1): 61-107
9	Ensminger I, Sveshnikov D, Campbell DA, Funk C, Jansson S, Lloyd J, Shibistova O, Öquist G. Intermittent low temperatures constrain spring recovery of photosynthesis in boreal Scots pine forests. Glob Change Biol, 2004, 10(6): 995-1008, DOI
10	Forrest J, Miller-Rushing AJ. Toward a synthetic understanding of the role of phenology in ecology and evolution. Philos Trans R Soc Lond B Biol Sci, 2010, 365(1555): 3101-3112, DOI
11	Franks SJ, Weber JJ, Aitken SN. Evolutionary and plastic responses to climate change in terrestrial plant populations. Evol Appl, 2014, 7(1): 123-139, DOI
12	Fréchette E, Chang CYY, Ensminger I. Variation in the phenology of photosynthesis among eastern white pine provenances in response to warming. Glob Change Biol, 2020, 26(9): 5217-5234, DOI
13	Genty B, Briantais JM, Baker NR. The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence. Biochim Biophys Acta Gen Subj, 1989, 990(1): 87-92, DOI
14	Gonsamo A, Chen JM, Price DT, Kurz WA, Wu C. Land surface phenology from optical satellite measurement and CO₂ eddy covariance technique. J Geophys Res, 2012, 117(G3): G03032
15	Ishizuka W, Kon H, Kita K, Kuromaru M, Goto S. Local adaptation to contrasting climatic conditions in Sakhalin fir (Abies sachalinensis) revealed by long-term provenance trials. Eco Res, 2021, 36(4): 720-732, DOI
16	Kikuzawa K, Ackerly D. Significance of leaf longevity in plants. Plant Species Biol, 1999, 14(1): 39-45, DOI
17	Kitamura K, Uchiyama K, Ueno S, Ishizuka W, Tsuyama I, Goto S. Geographical gradients of genetic diversity and differentiation among the southernmost marginal populations of Abies sachalinensis revealed by EST-SSR polymorphism. Forests, 2020, 11(2): 233, DOI
18	Noordermeer D, Velasco V, Ensminger I. Autumn warming delays downregulation of photosynthesis and does not increase risk of freezing damage in interior and coastal Douglas-fir seedlings. Front For Glob Change, 2021, DOI
19	Öquist G, Huner NP. Photosynthesis of overwintering evergreen plants. Annu Rev Plant Biol, 2003, 54(1): 329-355, DOI
20	QGIS Development Team J (2018) QGIS geographic information system. Open source geospatial foundation project
21	R Core Team (2022) R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. Website https://www.R-project.org
22	Reich PB, Oleksyn J, Modrzynski J, Tjoelker MG. Evidence that longer needle retention of spruce and pine populations at high elevations and high latitudes is largely a phenotypic response. Tree Physiol, 1996, 16(7): 643-647, DOI
23	Sakai A. Comparative study on freezing resistance of conifers with special reference to cold adaptation and its evolutive aspects. Can J Bot, 1983, 61(9): 2323-2332, DOI
24	Sang Z, Hamann A, Aitken SN. Assisted migration poleward rather than upward in elevation minimizes frost risks in plantations. Clim Risk Manag, 2021, DOI
25	Sapporo Regional Headquarters (2017) Climate change in Hokkaido: past 120 years and projections for the future, 2nd edn, Japan. https://www.data.jma.go.jp/sapporo/bosai/publication/kiko/kikohenka/pdf/report.pdf
26	Tsuyama I, Ishizuka W, Kitamura K, Taneda H, Goto S. Ten years of provenance trials and application of multivariate random forests predicted the most preferable seed source for silviculture of Abies sachalinensis in Hokkaido, Japan. Forests, 2020, 11(10): 1058, DOI
27	Verhoeven A, Osmolak A, Morales P, Crow J. Seasonal changes in abundance and phosphorylation status of photosynthetic proteins in eastern white pine and balsam fir. Tree Physiol, 2009, 29(3): 361-374, DOI
28	West-Eberhard MJ. West-Eberhard MJ, Mary J. Development. Developmental plasticity and evolution, 2003 Oxford University Press 89-90, DOI

[1]	Fabrina Bolzan Martins, Mábele de Cássia Ferreira, Flávia Fernanda Azevedo Fagundes, Gabriel Wilson Lorena Florêncio. Thermal and photoperiodic requirements of the seedling stage of three tropical forest species [J]. JOURNAL OF FORESTRY RESEARCH, 2023, 34(1): 209-220.
[2]	Marín Pompa-García, J. Julio Camarero, Michele Colangelo. Different xylogenesis responses to atmospheric water demand contribute to species coexistence in a mixed pine–oak forest [J]. JOURNAL OF FORESTRY RESEARCH, 2023, 34(1): 51-62.