欧洲云杉PSⅡ的热稳定性对温度升高的响应

doi:10.11707/j.1001-7488.20200703

Abstract

Abstract:

Objective: In this study,5-year-old European spruce(Picea abies) seedlings were used to evaluate the thermal stability and self-repairing ability of PSⅡ in the future climate warming. Method: Three clones,10 ramets of each clone,30 ramets in total,were selected and cultured in an artificial climate chamber under normal conditions. Two weeks later,hand-PEA and image-PAM were used to detect the fluorescence parameters and image of leaves as control. After preheating for 5 hours in a low light incubator at 38℃,seedlings were heated for 30 minutes at 40,42,43,44,46,48,50,52,53 and 54℃,respectively. Three clones(one ramet per clone) were treated in each experimental group. Hand-PEA and image-PAM were used to detect the fluorescence parameters of leaves and two critical temperatures of tress were selected. Seedlings treated under two critical temperatures were cultured in an artificial climate chamber for two weeks. Hand-PEA and image-PAM were used to detect the fluorescence parameters and images of leaves,and to study the self-repairing ability of spruce PSⅡ after heat shock. Result: 1) Through the study of Y(Ⅱ),Y(NO) and Y(NPQ) fluorescence images and kinetic curves,it was found that under 44 ℃ heat stress,PSⅡ of P. abies reached the initial stress temperature,and under 52 ℃ heat stress,it reached the maximum stress temperature. Compared with herbs,other woody species and related species,the thermal stability of PSⅡ was at a higher level for P. abies. 2) The fluorescence parameters of F₀,F_m,F_v/F_M,NPQ,q_L and q_P of PSⅡ and the fluorescence kinetic parameters of NPQ,q_L and q_P were detected by image-PAM at critical temperature: the fluorescence kinetic parameters of F_m and F_v/F_m were weakened,the fluorescence images of q_L and q_P were enhanced,and the fluorescence kinetic parameters of NPQ,q_L and q_P were higher than those of the control at 44 ℃. The fluorescence kinetic curves of F_v/F_m,q_L and q_P were lower than those of the control. 3) The hand-PEA was used to further detect the change of fluorescence parameters of PSⅡ. Under 44 ℃ short-time heat shock,F_v/F_m and OJIP curves did not change significantly,PI_ABS decreased only to 79.5% of the control group. The ability of chlorophyll(Chl) to absorb and capture light energy,the transmission of electrons,and the activity of center protein in electron transfer chain were not significantly inhibited. The heat chock also promoted the ability of Chl to absorb energy(ABC) photochemical reaction and fluorescence quenching. However,under the short-term heat shock of 52 ℃,the function of PSⅡ was obviously inhibited,and the OJIP curve also showed a large "K" band,F_v/F_m was reduced to 63.2% of the control group. PI_ABS was only 6.6% of the control group. The absorption and capture of light energy,photochemical reaction,fluorescence quenching and electron transfer ability of chlorophyll(Chl) were severely inhibited at the moment of F_m,and the oxygen evolution complex(OEC) of electron transfer chain was also severely damaged. Therefore,it was predicted that increasing temperature mainly inhibited the activity of reaction center and electron transfer on receptor side of PSⅡ in leaves,changed the energy flow and distribution in PSⅡ reaction center. But it had little effect on the donor side of PSⅡ. 4) After two weeks of recovery in normal growth condition,the fluorescence parameters and images of the needles of the seedlings that were previously subjected to heat shock under the two stress temperatures were restored to the level of the control,indicating that P. abies had a strong recovery ability to the short-term stress. Conclusion: Therefore,we predict that PSⅡ of P. abies has a strong elastic adaptation physiological mechanism to cope with the short-term high temperature in extreme weather at noon under the future climate change,and its temperature range of heat shock stress can be withstood that is 44-52 ℃.

Key words: Picea abies, PSⅡ, fluorescence parameters and images, heat shock stress, critical temperature

CLC Number:

718.43

Zirui Jia,Ya Wang,Jianwei Ma,Sanping An,Jiwen Hu,Junhui Wang. Response to Thermal Stability of PSⅡ for Temperature Rising in Picea abies[J]. Scientia Silvae Sinicae, 2020, 56(7): 22-32.

Figures/Tables 8

Fig.1

Fig.2

Fig.3

Fig.4

Fig.5

Table 1

Fluorescence parameter and standardizing result under the critical temperature of heat shock stress"

参数Parameters	CG44		CG52		HS44		HS52		RT44		RT52
参数Parameters	Raw	Stan	Raw	Stan	Raw	Stan	Raw	Stan	Raw	Stan	Raw	Stan
ABS/RC	2.018±0.128	1	2.042±0.171	1	2.132±0.110	1.056	5.681±2.527	2.782	1.923±0.111	0.953	2.048±0.223	1.003
DI₀/RC	0.320±0.020	1	0.322±0.028	1	0.382±0.059	1.193	2.994±2.192	9.296	0.310±0.031	0.969	0.364±0.071	1.130
TR₀/RC	1.698±0.114	1	1.720±0.147	1	1.750±0.071	1.030	2.687±0.382	1.562	1.612±0.088	0.949	1.684±0.163	0.979
ET₀/RC	0.840±0.060	1	0.846±0.044	1	0.847±0.072	1.009	0.373±0.350	0.441	0.755±0.026	0.899	0.803±0.063	0.949
RE₀/RC	0.275±0.017	1	0.273±0.017	1	0.353±0.026	1.284	0.494±0.255	1.807	0.236±0.020	0.860	0.280±0.055	1.025
phi(P₀)(或F_v/F_m)	0.841±0.007	1	0.842±0.006	1	0.822±0.02	0.977	0.536±0.166	0.637	0.839±0.010	0.997	0.823±0.019	0.978
psi(E₀)	0.495±0.018	1	0.494±0.034	1	0.484±0.026	0.978	0.156±0.157	0.315	0.469±0.018	0.948	0.478±0.018	0.968
phi(E₀)	0.416±0.015	1	0.416±0.027	1	0.397±0.022	0.955	0.010±0.115	0.240	0.393±0.015	0.945	0.393±0.016	0.946
delta(R₀)	0.328±0.024	1	0.324±0.022	1	0.419±0.045	1.277	5.760±8.224	17.806	0.313±0.026	0.955	0.347±0.046	1.073
phi(R₀)	0.136±0.010	1	0.135±0.015	1	0.166±0.017	1.218	0.096±0.047	0.712	0.123±0.0136	0.904	0.136±0.017	1.012
ABS/CSo(或F₀)	488±19.596	1	464.917±67.426	1	515.444±20.305	1.056	995.778±308.743	2.142	468.444±47.434	0.960	488.667±138.816	1.051
DI₀/CS₀	77.446±4.499	1	73.165±10.144	1	92.082±11.760	1.189	506.791±305.308	6.927	75.719±10.891	0.978	87.660±30.255	1.198
TR₀/CS₀	410.554±16.736	1	391.751±57.619	1	423.362±17.114	1.031	488.986±40.054	1.248	392.726±37.606	0.957	401.006±110.348	1.024
ET₀/CS₀	203.079±10.064	1	192.351±25.211	1	204.957±17.071	1.009	77.095±79.443	0.401	184.121±18.672	0.907	190.949±52.418	0.993
RE₀/CS₀	66.6±5.505	1	62.347±10.139	1	85.486±7.686	1.284	89.652±40.822	1.438	57.604±6.665	0.865	66.917±21.248	1.073
ABS/CS_m(或F_m)	3 079.917±176.989	1	2 957.583±467.681	1	2 912.222±259.751	0.946	2 203±245.674	0.745	2 908.667±260.248	0.944	2 751.667±721.709	0.930
DI₀/CS_m	488±19.596	1	464.917±67.426	1	515.444±20.305	1.056	995.778±308.743	2.142	468.444±47.434	0.960	488.667±138.816	1.051
TR₀/CS_m	2 591.917±164.338	1	2 492.667±401.952	1	2 396.778±258.456	0.925	1 207.222±496.475	0.484	2 440.222±225.406	0.941	2 263±596.677	0.908
ET₀/CS_m	1 282±86.877	1	1 222.833±173.747	1	1 159.444±142.538	0.904	243.111±307.727	0.199	1143.667±110.101	0.892	1 076±273.551	0.880
RE₀/CS_m	419.583±28.990	1	395.833±64.816	1	486±76.479	1.158	219.111±134.327	0.554	357.333±35.770	0.852	374.111±101.221	0.945
PI_ABS	2.592±0.27	1	2.604±0.491	1	2.061±0.326	0.795	0.173±0.315	0.066	2.420±0.363	0.934	2.154±0.5	0.827

Table 1

Fig.6

Fig.7

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Response to Thermal Stability of PSⅡ for Temperature Rising in Picea abies

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