Photoperiod and temperature as dominant environmental drivers triggering secondary growth resumption in Northern Hemisphere conifers

Huang, Jian‐Guo; Ma, Qianqian; Rossi, Sergio; Biondi, Franco; Deslauriers, Annie; Fonti, Patrick; Liang, Eryuan; Mäkinen, Harri; Oberhuber, Walter; Rathgeber, Cyrille; Tognetti, Roberto; Treml, Václav; Yang, Bao; Zhang, Jiao‐Lin; Antonucci, Serena; Bergeron, Yves; Camarero, J. Julio; Campelo, Filipe; Čufar, Katarina; Cuny, Henri E.; Luis, Martín de; Giovannelli, Alessio; Gričar, Jožica; Gruber, Andreas; Gryc, Vladimír; Güney, Aylin; Huang, Wei; Jyske, Tuula; Kašpar, Jakub; King, Gregory; Krause, Cornélia; Lemay, Audrey; Liu, Feng; Lombardi, Fabio; Castillo, Edurne Martínez del; Morin, Hubert; Nabais, Cristina; Nöjd, Pekka; Peters, Richard L.; Prislan, Peter; Saracino, Antonio; Swidrak, Irene; Vavrčík, Hanuš; Vieira, Joana; Yu, Biyun; Zhang, Shaokang; Zeng, Qiao; Zhang, Yaling; Ziaco, Emanuele

doi:10.1073/pnas.2007058117

Cited by 142 publications

(95 citation statements)

References 57 publications

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“…Besides water, temperature is known to influence wood formation, both in terms of phenology and growth rate. Growth start has been found to be largely temperature‐dependent (Delpierre et al., 2018; Huang et al., 2020; Oribe & Funada, 2017; Rossi et al., 2016) and using the temperature‐based CLM5.0 GDD‐model to simulate growth start worked well in confirming a likely

t_{1}

for our site. This implies that temperature may be involved in growth onset at our site to some degree, even though the daily‐resolution correlation analysis did not find a significant temperature‐effect on TRWi early in the year.…”

Section: Discussionsupporting

confidence: 73%

Direct response of tree growth to soil water and its implications for terrestrial carbon cycle modelling

Eckes-Shephard

Tiavlovsky²,

Chen

et al. 2020

Global Change Biology

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Section: Discussionsupporting

confidence: 73%

Direct response of tree growth to soil water and its implications for terrestrial carbon cycle modelling

Eckes-Shephard

Tiavlovsky²,

Chen

et al. 2020

Global Change Biology

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“…Moreover, simulated and observed proportions of formed cells are tightly synchronized mainly at the beginning of the tree-ring ( Figure 6 ). This is not surprising, because onset of cambial activity ( Rossi et al, 2008 , 2016 ; Treml et al, 2015 ; Delpierre et al, 2019 ; Huang et al, 2020 ) and regulation of first phases of xylogenesis ( Deslauriers and Morin, 2005 ) are strictly temperature-controlled in cold environments. The algorithm of the VS-model uses the cumulative temperature threshold to estimate the date of spring onset of cambial cell growth and, in the next step, calculates daily resolved kinetics of cell growth and differentiation based on the cell position in the radial file and climatically driven external growth rates ( Vaganov et al, 2006 ).…”

Section: Discussionmentioning

confidence: 99%

“…Northern and high-elevation forests experience prominent year-to-year changes in cambial dynamics (process of xylem tissue development), phenology (timing of cambial activity) and kinetics (speed of xylem cell differentiation). The initiation of cambial activity in cold regions is driven mainly by temperature ( Rossi et al, 2008 ; Delpierre et al, 2019 ; Huang et al, 2020 ). Consequently, the date of cambial activity onset tightly follows the variability of spring temperature around specific thresholds ( Rossi et al, 2007 ; Treml et al, 2015 ).…”

Section: Introductionmentioning

confidence: 99%

Forward Modeling Reveals Multidecadal Trends in Cambial Kinetics and Phenology at Treeline

et al. 2021

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Significant alterations of cambial activity might be expected due to climate warming, leading to growing season extension and higher growth rates especially in cold-limited forests. However, assessment of climate-change-driven trends in intra-annual wood formation suffers from the lack of direct observations with a timespan exceeding a few years. We used the Vaganov-Shashkin process-based model to: (i) simulate daily resolved numbers of cambial and differentiating cells; and (ii) develop chronologies of the onset and termination of specific phases of cambial phenology during 1961–2017. We also determined the dominant climatic factor limiting cambial activity for each day. To asses intra-annual model validity, we used 8 years of direct xylogenesis monitoring from the treeline region of the Krkonoše Mts. (Czechia). The model exhibits high validity in case of spring phenological phases and a seasonal dynamics of tracheid production, but its precision declines for estimates of autumn phenological phases and growing season duration. The simulations reveal an increasing trend in the number of tracheids produced by cambium each year by 0.42 cells/year. Spring phenological phases (onset of cambial cell growth and tracheid enlargement) show significant shifts toward earlier occurrence in the year (for 0.28–0.34 days/year). In addition, there is a significant increase in simulated growth rates during entire growing season associated with the intra-annual redistribution of the dominant climatic controls over cambial activity. Results suggest that higher growth rates at treeline are driven by (i) temperature-stimulated intensification of spring cambial kinetics, and (ii) decoupling of summer growth rates from the limiting effect of low summer temperature due to higher frequency of climatically optimal days. Our results highlight that the cambial kinetics stimulation by increasing spring and summer temperatures and shifting spring phenology determine the recent growth trends of treeline ecosystems. Redistribution of individual climatic factors controlling cambial activity during the growing season questions the temporal stability of climatic signal of cold forest chronologies under ongoing climate change.

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“…In their Letter, Elmendorf and Ettinger (1) question the dominant role of photoperiod in driving secondary growth resumption (hereafter referred to as xylem formation onset) of the Northern Hemisphere conifers, recently reported by Huang et al (2). Their opinions are grounded on the following three aspects, including 1) the seasonality of the photoperiod, 2) the dependence of the predictor variables (e.g., photoperiod, forcing, and chilling) on the response variable (the date of onset of xylem formation, day of the year [DOY]), and 3) the limited value of the obtained models for interannual forecasting.…”

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confidence: 98%

Reply to Elmendorf and Ettinger: Photoperiod plays a dominant and irreplaceable role in triggering secondary growth resumption

Huang¹,

Campelo²,

Ma³

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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Photoperiod and temperature as dominant environmental drivers triggering secondary growth resumption in Northern Hemisphere conifers

Cited by 142 publications

References 57 publications

Direct response of tree growth to soil water and its implications for terrestrial carbon cycle modelling

Direct response of tree growth to soil water and its implications for terrestrial carbon cycle modelling

Forward Modeling Reveals Multidecadal Trends in Cambial Kinetics and Phenology at Treeline

Reply to Elmendorf and Ettinger: Photoperiod plays a dominant and irreplaceable role in triggering secondary growth resumption

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