基于光合指标的平欧杂种榛扦插苗根系生长发育评价模型

doi:10.11707/j.1001-7488.LYKX20230632

摘要/Abstract

摘要：

目的: 通过探究平欧杂种榛扦插苗不同生长时期根系表型动态特征以及光合特性变化规律，建立根系生长与光合指标的关系模型，用于模拟和预测扦插苗根系生长状况，为今后探究成龄树根系生长指标对光合指标的响应奠定基础。方法: 以1年生平欧杂种榛扦插苗为研究对象，分别测定扦插苗在生根期、生长初期、生长中期和生长旺盛期净光合速率、蒸腾速率、胞间CO₂浓度和气孔导度等光合指标；并利用根系扫描仪扫描完整根系测定总根长、总表面积、根系平均直径、根系总体积及根尖数等根系生长指标。采用二次多项式逐步回归法，构建基于光合指标的根系生长发育评价模型，以期明确光合指标与根系生长指标的关系。结果: 1）各根系生长指标在不同生长期存在显著差异，生长旺盛期的总根长是生根期的3.6倍、根系总表面积是生根期的2.8倍、根系总体积是生根期的2倍。2）根尖数是反映根系活力状况的指标之一，在生长中期达到峰值，是生根期的8.9倍，而在生长旺盛期数量骤减至不足生长中期的50%。3）净光合速率、蒸腾速率、胞间CO₂浓度、气孔导度等光合指标在扦插苗的各生长期存在显著差异，生根期的净光合速率是生长旺盛期的1.8倍、蒸腾速率是生长旺盛期的4.3倍。胞间CO₂浓度随着生长期推移而增加，在生长旺盛期达到生根期的1.3倍；气孔导度有先增后降的变化趋势，在生长中期达到高峰（生根期的2.4倍），在生长旺盛期锐减（生长中期的25%）。4）扦插苗的根系总体积、总根长及总表面积与胞间CO₂浓度和气孔导度呈正相关；净光合速率和蒸腾速率与根系平均直径呈正相关；根尖数与气孔导度呈正相关。5）构建的基于光合指标的根系生长发育评估模型（R²=0.75）预测结果较好且精度高（MSE=0.12），能较全面地反映根系生长发育状况。结论: 光合指标及根系生长指标在不同根系生长时期差异显著，该研究建立的基于光合指标的根系生长发育评估模型可为无损评估平欧杂种榛扦插苗根系生长提供科学、便捷的方法。

关键词: 平欧杂种榛, 根系发育, 根系生长期, 光合特性, 根系生长模型

Abstract:

Objective: This study aims to investigate dynamic features of root phenotypes and photosynthetic characteristics of Corylus heterophylla × C. avellana cuttings at different growth stages. A model representing the relationship between root growth and photosynthetic indices was established and used to simulate root growth conditions of cuttings, so as to lay the foundation for future exploration of the response of mature root growth indicators to photosynthetic indicators. Method: Photosynthetic indices (net photosynthetic rate, transpiration rate, intercellular CO₂ concentration and stomatal conductance) of one-year-old C. heterophylla × C. avellana cuttings were measured at different growth periods (rooting, early growth, intermediate growth, and vigorous growth periods). A root scanner was used to scan the complete root system and determine root growth indicators such as total root length, total surface area, average root diameter, total root volume, and number of root tips. A quadratic polynomial stepwise regression method was used to construct a root growth and development evaluation model based on photosynthetic indices to clarify the relationship between photosynthetic indicators and root growth indicators. Result: 1) There were significant differences in various root growth indicators at the different growth stages. The total root length, total surface area, and total root volume during the vigorous root period were effective indices of root growth conditions and exceeded those during the rooting period by factors of 3.6, 2.8, and 2.0, respectively. 2) The maximum number of root tips occurred during the intermediate growth period and exceeded those during the rooting and vigorous growth periods by factors of 8.9 and 2, respectively. These results suggest that number of root tips is an effective index of root activity. 3) There were significant differences in photosynthetic indicators such as net photosynthetic rate, transpiration rate among the different root growth periods of the cuttings. The net photosynthetic rate and transpiration rate during rooting period exceeded those during the vigorous growth period by factors of 1.8 and 4.3, respectively. The intercellular CO₂ concentration increased with growth, and that during the vigorous growth exceeded that during the rooting period by a factor of 1.3. The stomatal conductance increased and then decreased with progressive growth periods, reaching a peak in the intermediate growth period when it exceeded that during the rooting period by a factor of 2.4, following which it decreased sharply by 75% in the vigorous growth period. 4) The total root volume, total root length, and total surface area of cuttings were positively correlated with intercellular CO₂ concentration and stomatal conductance. The net photosynthetic rate and transpiration rate were positively correlated with average root diameter, and the number of root tips was positively correlated with stomatal conductance. 5) The performance indices (R²=0.75; mean squared error MSE=0.12) confirmed the excellent performance of the proposed photosynthetic indices-based model for evaluating root growth and development. Conclusion: Root system growth indicators and photosynthetic indicators show significant differences at different growth periods. Overall, the proposed model based on photosynthetic indicators serves as a feasible and effective approach for non-destructive evaluation of root growth and development of cuttings of C. heterophylla × C. avellana. It can also lay the foundation for exploring the response of root growth indicators of mature trees to photosynthetic indicators.

Key words: Corylus heterophylla × C. avellana, root development, root growth period, photosynthetic characteristics, root growth model

中图分类号:

S718.3

吕梦燕,任军,张立民,陈思羽,赵佳丽,鲁佳乐,孔晨,戴维,金桂香. 基于光合指标的平欧杂种榛扦插苗根系生长发育评价模型[J]. 林业科学, 2025, 61(3): 100-107.

Mengyan Lü,Jun Ren,Limin Zhang,Siyu Chen,Jiali Zhao,Jiale Lu,Chen Kong,Wei Dai,Guixiang Jin. Evaluation Model for Root Growth and Development of Corylus heterophylla × C. avellana Cuttings Based on Photosynthetic Indexes[J]. Scientia Silvae Sinicae, 2025, 61(3): 100-107.

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根系指标 Root indicators	生根期 Rooting period	生长初期 Early growth period	生长中期 Intermediate growth period	生长旺盛期 Vigorous growth period	P
总根长 Total root length/mm	140.82±51.43d	249.30±96.38c	363.50±109.32b	511.55±146.90a	<0.001
总表面积 Total surface area/mm²	25.21±6.75c	36.85±10.91b	44.06±9.08b	70.96±16.03a	<0.001
根系平均直径 Average diameter/mm	0.62±0.13a	0.51±0.14ab	0.40±0.06b	0.45±0.09b	0.014
根系总体积 Total volume/mm³	0.40±0.12b	0.47±0.19b	0.43±0.07b	0.80±0.23a	0.001
根尖数 Number of root tips	633.40±225.95b	2326.2±1385.90b	5629.40±3788.34a	2545.60±1219.46b	0.002

项目 Items	因子载荷值Factor load value
项目 Items	因子1 Factor 1	因子2 Factor 2	因子3 Factor 3
总根长 Total root length	0.771	?0.573	0.230
总表面积 Total surface area	0.945	?0.302	0.117
根系平均直径 Average diameter	?0.044	0.965	?0.223
根系总体积Total volume	0.964	0.225	?0.033
根尖数Number of root tips	0.077	?0.215	0.973
贡献率Contribution rate（%）	48.48	28.96	21.3

光合指标 Photosynthesis indices	生根期 Rooting period	生长初期 Early growth period	生长中期 Intermediate growth period	生长旺盛期 Vigorous growth period	P
净光合速率 Net photosynthesis/（μmol·m^?2 s^?1）	11.25±0.73a	10.10±0.97b	8.75±2.92bc	5.68±1.54c	0.003
蒸腾速率 Transpiration rate/（mmol·m^?2 s^?1）	0.013±0.002a	0.008±0.002b	0.008±0.002b	0.003±0.002c	<0.001
胞间CO₂浓度 Intercellular CO₂ concentration/（μmol·mol^?1）	323.45±13.13b	416.62±29.38a	435.03±12.00a	432.81±9.36a	<0.001
气孔导度 Stomatal Conductance/（mol·m^?2 s^?1）	0.27±0.06bc	0.47±0.18ab	0.65±0.26a	0.26±0.15c	0.009

根系指标 Root Indicators	R²	P	光合指标 Photosynthesis indices	R²	P
总根长 Total root length	0.792**	<0.001	净光合速率速率 Net photosynthesis	0.676**	<0.001
总表面积 Total surface area	0.809**	<0.001	蒸腾速率 Transpiration rate	?0.815**	<0.001
根系平均直径 Average diameter	?0.398	0.054	胞间CO₂浓度 Intercellular CO₂ concentration	0.702**	<0.001
根系总体积 Total volume	0.637**	0.001	气孔导度 Stomatal conductance	?0.046	0.831
根尖数 Number of root tips	0.304	0.148	空气中CO₂浓度 Fractional concentration of CO₂ in atmosphere	0.888**	<0.001

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