Climate warming could free cold-adapted trees from C-conservative allocation strategy of storage over growth

Zhou, Quan1 ; Shi, Hang1 ; He, Rui1 ; Liu, Haikun1 ; Zhu, Wenting1 ; Wu, Shengjun2 ; Zhang, Quanfa1 ; Dang, Haishan1

Published Nov 06, 2023 on Dryad. https://doi.org/10.5061/dryad.8w9ghx3t6

Data files

Nov 06, 2023 version files 72.19 KB

Dataset-1_Transplant_experiment.xlsx

27.14 KB
Dataset-2_Chamber_warming.xlsx

41.65 KB
README.md

3.40 KB

Abstract

Carbon allocation has been fundamental for long-lived trees to survive cold stress at their upper elevation range limit. Although carbon allocation between NSC (non-structural carbohydrate) storage and structural growth is well-documented, it still remains unclear how ongoing climate warming influences these processes, particularly whether these two processes will shift in parallel or respond divergently to warming. Using a combination of an in situ downward-transplant warming experiment and an ex situ chamber warming treatment, we investigated how subalpine fir trees at their upper elevation limit coordinated carbon allocation priority among different sinks (e.g., NSC storage and structural growth) at whole-tree level in response to elevated temperature. We found that transplanted individuals from the upper elevation limit to lower elevations generally induced an increase in specific leaf area, but there was no detected evidence of warming effect on leaf-level saturated photosynthetic rates. Additionally, our results challenged the expectation that climate warming will accelerate structural carbon accumulation while maintaining NSC constant. Instead, individuals favored allocating available carbon to NSC storage over structural growth after one year of warming, despite the amplification in total biomass encouraged by both in situ and ex situ experimental warming. Unexpectedly, continued warming drove a regime shift in carbon allocation priority, which was manifested in the increase of NSC storage in synchrony to structural growth enhancement. These findings imply that climate warming would release trees at their cold edge from C-conservative allocation strategy of storage over structural growth. Thus, understanding the strategical regulation of the carbon allocation priority and the distinctive function of carbon sink components is of great implication for predicting tree fate in the future climate warming.

README: Data on: Climate warming could free cold-adapted trees from C-conservative allocation strategy of storage over growth

https://doi.org/10.5061/dryad.8w9ghx3t6

This dataset is the data used in the paper on global change biology entitled "Climate warming could free cold-adapted trees from the C-conservative allocation strategy of storage over growth". We used a combination of an in situ downward-transplant warming experiment and an ex situ chamber warming treatment to assess the impact of global warming on whole-tree C allocation of firs grown at their cold edge

Description of the data and file structure

The Dataset-1 file includes the data considering the effects of downward-transplant warming on functional traits, growth, and NSC storage.

Asat: saturated photosynthesis (µmol CO₂ m^-2 s^-1);
sla: specific leaf area, total one-sided fresh leaf area divided by dry weight (cm² g^-1);
twig_density: density of the twig as the ratio of dry mass to the volume of that mass (g cm^-3);
root_density: density of the root as the ratio of dry mass to the volume of that mass (g cm^-3);
height_increment: the difference between tree height at the beginning and the end of the growing season (cm);
RBAI: relative stem basal area increment (cm² cm^-2 yr^-1);
shoot_increment: shoot length increment (mm);
RGR: dividing the whole-tree biomass at the end of the growing season by that at the beginning of the growing season (g g^-1yr^-1);
NSC: the biomass-weighted mean concentration of whole-tree NSC, including soluble sugars and starch (mg/g)

Definition of column names

Elevation (m): in order to simulate warmer climates, saplings from the upper elevation site (3150 m) were transplanted to the middle (2950 m) and the low elevation sites (2760 m);
Total_biomass: whole-tree dry matter weight (g);
Twig_biomass: twig (shoot) dry matter weight (g);
root_biomass: root dry matter weight (g);
initial_height: initial tree height (cm);
initial_shoot: initial shoot length (mm);
May_biomass: total biomass of samples sampled in May (g);
Sep_biomass: total biomass of samples sampled in September (g)
Code: the identity of the individuals;
Chamber: the identity of the growth chamber

The Dataset-2 file includes data considering the effects of chamber warming treatment on growth and NSC storage.

height_increment: The difference between the current measurement and the last time the tree height was measured (cm);
shoot_increment: The difference between the current measurement and the last time the shoot length was measured (mm);
RBAI: relative basal area increment (cm² cm^-2)
biomass: the biomass of the sample at each samplings (g);
NSC: the biomass-weighted mean concentration of whole-tree NSC, including soluble sugars and starch (mg/g)

Definition of column names

date: sampling dates;
treatment: chamber warming treatment (i.e., "cur" refers to the current ambient air temperature scenario, "50-y" and "100-y" refer to the temperature scenarios after 50 and 100 years of warming, respectively);
Code: the identity of the individuals;
Chamber: the identity of the growth chamber