Long-term effects of 7-year warming experiment in the field on leaf hydraulic and economic traits of subtropical tree species

Rising temperature associated with climate change may have substantial impacts on forest tree functions. We conducted a 7-year warming experiment in sub-tropical China by translocating important native forest tree species (<i>Machilas breviflora</i>, <i>Syzygium rehderianum</i>,<i> Schima superba</i> and <i>Itea chinensis</i>) from cooler high-elevation-sites (600 m) to 1-2 ℃ warmer low-elevation-sites (300 and 30 m) to investigate warming effects on leaf hydraulic and economic traits. Here, we report data from the last three years (Years 5-7) of the experiment. Warming increased leaf hydraulic conductance (K_leaf) of <i>S. superba </i>to meet the higher evaporative demand. <i>M. breviflora </i>(300 m), <i>S. rehderianum</i>,<i> S. superba</i> and <i>I. chinensis </i>(300 m and 30 m) exhibited higher area-based and mass-based maximum photosynthetic rates (A_a and A_m, respectively) related to increasing stomatal conductance (g_s) and stomatal density in the wet season, which led to rapid growth; however, we observed decreased growth of <i>M. breviflora </i>at 30 m due to lower stomatal density and decreased A_a in the wet season. Warming increased photosynthetic nitrogen use efficiency (PNUE) and photosynthetic phosphorus use efficiency (PPUE), but reduced leaf dry mass per unit area (LMA) due to lower leaf thickness, suggesting that these tree species allocated more resources into upregulating photosynthesis rather than into structural investment. Our findings highlight that there was trait variation in the capacity of trees to acclimate to warmer temperatures such that<i> I. chinensis </i>may benefit from warming, but <i>S. superba</i> may be negatively influenced by warming in future climates.