Characteristics of stem and leaf functional traits of Rhododendron capitatum on the north slope of Zhagaliang， Gansu

doi:10.11686/cyxb2020536

Abstract

Abstract:

Alpine plants show unique functional plasticity in the process of adapting to environmental constraints such as high altitude， low atmospheric pressure and a short growing season. This research explored the morphological variation in twigs and leaves of Rhododendron capitatum along an altitude gradient to evaluate the functional significance of this variation for resource acquisition， survival and reproduction. In August 2019， various leaf and twig traits of 23 groups of R.capitatum were measured at altitudes from 3400-3700 m. It was found that with increase in altitude， the leaf dry matter content （LDMC）， density （LDE）， thickness （LT） and total leaf dry matter content （TLDMC） were increased. Leaf length （LL）， width （LW）， area （LA）， volume （LV）， dry weight （LDW）， stem length （SL）， stem dry weight （SDW）， total leaf dry weight （TLDW）， total leaf area （TLA）， stem slender ratio （SSR） and stem volume （SV） showed a “V” shaped altitudinal trend with the lowest values at around 3600 m altitude. Higher altitude significantly increased thickness （LT）， dry matter content （LDMC）， density （LDE）， but significantly decreased specific leaf area （SLA）， total leaf area （TLA） and total specific leaf area （TSLA）， respectively. There were significant correlations between most measured traits. The variance components of leaf traits between R. capitatum plants growing at the same altitude were significantly higher than those between plants at different altitudes. The smallest coefficient of phenotypic differentiation of twigs and leaves was 3.19% for stem dry matter content （SDMC）， the largest was 57.73% for leaf density （LDE）， and the average across traits was 20.65%. The results show that some traits of R. capitatum are not sensitive to elevation changes， and that a few key traits like leaf area （LA）， specific leaf area （SLA）， leaf dry matter content （LDMC） and leaf density （LDE） act as functional traits to adapt to alpine habitats. R. capitatum showed lower phenotypic variation among plants along elevation gradients than among plants at the same altitude.

Key words: alpine, functional traits, altitude, phenotype differentiation, Rhododendron capitatum

Ke-tong YANG, Guo-peng CHEN, Jun-ren XIAN, Xiao-ya YU, Jin-wu ZHANG, Li WANG. Characteristics of stem and leaf functional traits of Rhododendron capitatum on the north slope of Zhagaliang， Gansu[J]. Acta Prataculturae Sinica, 2022, 31(2): 111-120.

Figures/Tables 4

References 36

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枝叶性状 Stem-leaf traits	方差分量Variance component			方差分量百分比 Percentage of variance component （%）			表型分化系数 Phenotype differentiation coefficient （%）
枝叶性状 Stem-leaf traits	海拔间 Among altitude	海拔内 Within altitude	随机误差 Random errors	海拔间 Among altitude	海拔内 Within altitude	随机误差 Random errors	表型分化系数 Phenotype differentiation coefficient （%）
LL	143.011	609.681	136.987	16.07	68.53	15.40	19.00
LW	39.049	114.645	37.957	20.38	59.82	19.81	25.41
LT	0.009	0.022	0.003	26.47	64.71	8.82	30.00
LA	0.945	3.303	0.837	18.58	64.96	16.46	22.25
LV	0.001	0.004	0.001	16.67	66.67	16.67	25.00
LDW	0.000	0.000	0.000	23.98	38.01	38.01	38.68
LDMC	0.029	0.059	0.016	27.89	56.73	15.39	32.96
LSI	0.699	12.017	0.699	5.21	89.58	5.21	5.50
SLA	12943.759	10530.442	3953.805	47.19	38.39	14.42	55.14
LDE	0.127	0.093	0.044	48.11	35.23	16.67	57.73
SD	0.456	5.921	0.456	6.67	86.65	6.67	7.15
SL	964.248	4494.216	945.091	15.06	70.19	14.76	17.67
SDW	0.002	0.008	0.002	16.67	66.67	16.67	20.00
SDMC	0.003	0.091	0.002	3.13	94.79	2.08	3.19
TLDW	0.005	0.027	0.005	13.51	72.97	13.51	15.63
TLDMC	0.018	0.144	0.005	10.78	86.23	2.99	11.11
TLA	656721.350	2818816.985	382925.341	17.02	73.06	9.92	18.90
TLSWR	8.292	43.497	7.454	14.00	73.42	12.58	16.01
LNO.	23.800	316.133	17.920	6.65	88.34	5.01	7.00
TSLA	30006.371	132296.387	1115.683	18.36	80.96	0.68	18.49
SSR	272.912	1828.979	249.795	11.61	77.77	10.62	12.98
SV	922.583	7295.199	909.918	10.11	79.92	9.97	11.23
SDE	0.373	9.309	0.224	3.76	93.97	2.26	3.85
平均值 Mean	-	-	-	17.30	70.76	11.94	20.65

枝叶性状 Stem-leaf traits	方差分量Variance component			方差分量百分比 Percentage of variance component （%）			表型分化系数 Phenotype differentiation coefficient （%）
枝叶性状 Stem-leaf traits	海拔间 Among altitude	海拔内 Within altitude	随机误差 Random errors	海拔间 Among altitude	海拔内 Within altitude	随机误差 Random errors	表型分化系数 Phenotype differentiation coefficient （%）
LL	143.011	609.681	136.987	16.07	68.53	15.40	19.00
LW	39.049	114.645	37.957	20.38	59.82	19.81	25.41
LT	0.009	0.022	0.003	26.47	64.71	8.82	30.00
LA	0.945	3.303	0.837	18.58	64.96	16.46	22.25
LV	0.001	0.004	0.001	16.67	66.67	16.67	25.00
LDW	0.000	0.000	0.000	23.98	38.01	38.01	38.68
LDMC	0.029	0.059	0.016	27.89	56.73	15.39	32.96
LSI	0.699	12.017	0.699	5.21	89.58	5.21	5.50
SLA	12943.759	10530.442	3953.805	47.19	38.39	14.42	55.14
LDE	0.127	0.093	0.044	48.11	35.23	16.67	57.73
SD	0.456	5.921	0.456	6.67	86.65	6.67	7.15
SL	964.248	4494.216	945.091	15.06	70.19	14.76	17.67
SDW	0.002	0.008	0.002	16.67	66.67	16.67	20.00
SDMC	0.003	0.091	0.002	3.13	94.79	2.08	3.19
TLDW	0.005	0.027	0.005	13.51	72.97	13.51	15.63
TLDMC	0.018	0.144	0.005	10.78	86.23	2.99	11.11
TLA	656721.350	2818816.985	382925.341	17.02	73.06	9.92	18.90
TLSWR	8.292	43.497	7.454	14.00	73.42	12.58	16.01
LNO.	23.800	316.133	17.920	6.65	88.34	5.01	7.00
TSLA	30006.371	132296.387	1115.683	18.36	80.96	0.68	18.49
SSR	272.912	1828.979	249.795	11.61	77.77	10.62	12.98
SV	922.583	7295.199	909.918	10.11	79.92	9.97	11.23
SDE	0.373	9.309	0.224	3.76	93.97	2.26	3.85
平均值 Mean	-	-	-	17.30	70.76	11.94	20.65

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