Variation in leaf N allocation and mesophyll conductance to CO2 in four tree species under low soil P stress in subtropical China

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-07 DOI:10.1007/s11738-024-03707-y

Jingchao Tang, Baodi Sun, Ruimei Cheng, Zuomin Shi, Da Luo, Shirong Liu, Mauro Centritto

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Abstract

Low P (LP) levels in leaves can affect their photosynthetic N-use efficiency (PNUE), internal N allocation, and mesophyll conductance to CO₂ (g_m). The changes in leaf internal N allocation and g_m in N-fixing trees and the consequent changes in PNUE under low soil P treatments are not well understood. In this study, we exposed seedlings of Dalbergia odorifera, Erythrophleum fordii (N-fixing trees), Castanopsis hystrix, and Betula alnoides (non-N-fixing trees) to three levels of soil P. The effects were not consistent among species, and LP had no specific effect on N-fixing species. Saturated net CO₂ assimilation rate (A_sat) values in D. odorifera and C. hystrix were remarkably lower under LP than under high P (HP) because C_c in D. odorifera and V_cmax and J_max in C. hystrix were reduced. N_area values in D. odorifera and C. hystrix were also reduced under LP, and the degree of reduction of N_area was larger than that of A_sat, which resulted in decreased PNUE in these species. P_R and g_m in D. odorifera and P_R, P_B, and g_m in C. hystrix significantly decreased under LP and were internal factors affecting the variation in PNUE in these two trees. P_CW was significantly and linearly related to P_R only in C. hystrix, indicating that more N was invested in the cell walls to resist the damage caused by low soil P, at the expense of Rubisco N. Our results showed that soil P deficiency affected leaf N utilization, photosynthetic efficiency, and seedling growth.

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中国亚热带低土壤磷胁迫下四种树种叶片氮分配和叶绿体中层对二氧化碳传导的变化

叶片中的低磷（LP）水平会影响其光合作用氮利用效率（PNUE）、内部氮分配和叶绿体对二氧化碳的传导（gm）。固氮树种叶片内部氮分配和gm的变化，以及在低土壤P处理下PNUE的相应变化还不十分清楚。在本研究中，我们将 Dalbergia odorifera、Erythrophleum fordii（固氮树种）、Castanopsis hystrix 和 Betula alnoides（非固氮树种）的幼苗暴露于三种水平的土壤磷中。在低磷条件下，D. odorifera 和 C. hystrix 的饱和二氧化碳净同化率（Asat）值明显低于高磷（HP）条件下，因为 D. odorifera 的 Cc 以及 C. hystrix 的 Vcmax 和 Jmax 都降低了。在 LP 条件下，D. odorifera 和 C. hystrix 的 Narea 值也有所降低，且 Narea 的降低程度大于 Asat 的降低程度，从而导致这些物种的 PNUE 降低。在 LP 条件下，D. odorifera 的 PR 和 gm 以及 C. hystrix 的 PR、PB 和 gm 显著减少，是影响这两种树木 PNUE 变化的内部因素。只有 C. hystrix 的 PCW 与 PR 呈显著线性关系，这表明更多的氮被投入到细胞壁中以抵御土壤缺磷造成的损害，但却牺牲了 Rubisco 的氮。

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