RESUMEN
A link exists between hydraulic traits and leaf habit. However, few attempts have addressed a possible link between hydraulic traits and altered leaf habit in introduced ranges. Within its native range, the Amazon rainforest, Hevea brasiliensis (Willd. ex A. Juss) Muell. Arg. is an evergreen but it becomes drought-deciduous in non-native ranges. The reason for this change remains poorly understood. The hydraulic-related traits, gas exchange rates and water status of H. brasiliensis and the co-occurring evergreen Drypetes indica (Muell. Arg.) Pax et Hoffm. were examined in Xishuangbanna, China. The water potential at turgor loss point in both species almost overlapped, but the water potential at which leaf relative water content reached 70% was more negative in D. indica. The water loss rate from excised leaves was quicker in H. brasiliensis. Leaf and stem hydraulic conductivity were more susceptible to drought-induced embolisms in H. brasiliensis than in D. indica. Vessels were significantly wider in H. brasiliensis but D. indica had more vessels. H. brasiliensis displayed higher rain-season gas exchange rates than D. indica. During the dry season, low soil water potential rendered water transport inefficient in H. brasiliensis; this effect was less pronounced in D. indica. D. indica has traits that help prevent hydraulic failure but has a low photosynthetic capacity. The opposite was found for H. brasiliensis. The results suggest that a combination of hydraulic traits, gas exchange characteristics and water status during the dry season might trigger a change in the leaf habits of H. brasiliensis in introduced ranges.
RESUMEN
The response of plants to drought has received significant attention, but far less attention has been given to the dynamic response of plants during recovery from drought. Photosynthetic performance and hydraulic capacity were monitored in seedlings of Hevea brasiliensis under water stress and during recovery following rewatering. Leaf water relation, gas exchange rate and hydraulic conductivity decreased gradually after water stress fell below a threshold, whereas instantaneous water use efficiency and osmolytes increased significantly. After 5 days of rewatering, leaf water relation, maximum stomatal conductance (g(s-max)) and plant hydraulic conductivity had recovered to the control levels except for sapwood area-specific hydraulic conductivity, photosynthetic assimilation rate and osmolytes. During the phase of water stress, stomata were almost completely closed before water transport efficiency decreased substantially, and moreover, the leaf hydraulic pathway was more vulnerable to water stress-induced embolism than the stem hydraulic pathway. Meanwhile, g(s-max) was linearly correlated with hydraulic capacity when water stress exceeded a threshold. In addition, a positive relationship was shown to occur between the recovery of g(s-max) and of hydraulic capacity during the phase of rewatering. Our results suggest (i) that stomatal closure effectively reduces the risk of xylem dysfunction in water-stressed plants at the cost of gas exchange, (ii) that the leaf functions as a safety valve to protect the hydraulic pathway from water stress-induced dysfunction to a larger extent than does the stem and (iii) that the full drought recovery of gas exchange is restricted by not only hydraulic factors but also non-hydraulic factors.
Asunto(s)
Hevea/fisiología , Transpiración de Plantas/fisiología , Plantones/fisiología , Agua/metabolismo , Suelo , Factores de TiempoRESUMEN
Size-related changes in hydraulic architecture, carbon allocation and gas exchange of Sclerolobium paniculatum (Leguminosae), a dominant tree species in Neotropical savannas of central Brazil (Cerrado), were investigated to assess their potential role in the dieback of tall individuals. Trees greater than approximately 6-m-tall exhibited more branch damage, larger numbers of dead individuals, higher wood density, greater leaf mass per area, lower leaf area to sapwood area ratio (LA/SA), lower stomatal conductance and lower net CO(2) assimilation than small trees. Stem-specific hydraulic conductivity decreased, while leaf-specific hydraulic conductivity remained nearly constant, with increasing tree size because of lower LA/SA in larger trees. Leaves were substantially more vulnerable to embolism than stems. Large trees had lower maximum leaf hydraulic conductance (K(leaf)) than small trees and all tree sizes exhibited lower K(leaf) at midday than at dawn. These size-related adjustments in hydraulic architecture and carbon allocation apparently incurred a large physiological cost: large trees received a lower return in carbon gain from their investment in stem and leaf biomass compared with small trees. Additionally, large trees may experience more severe water deficits in dry years due to lower capacity for buffering the effects of hydraulic path-length and soil water deficits.
Asunto(s)
Carbono/metabolismo , Fabaceae/fisiología , Hojas de la Planta/fisiología , Tallos de la Planta/fisiología , Agua/fisiología , Brasil , Dióxido de Carbono/metabolismo , Estomas de Plantas/fisiología , Transpiración de Plantas/fisiología , Árboles/fisiología , Madera/fisiologíaRESUMEN
Leaf and stem functional traits related to plant water relations were studied for six congeneric species pairs, each composed of one tree species typical of savanna habitats and another typical of adjacent forest habitats, to determine whether there were intrinsic differences in plant hydraulics between these two functional types. Only individuals growing in savanna habitats were studied. Most stem traits, including wood density, the xylem water potential at 50% loss of hydraulic conductivity, sapwood area specific conductivity, and leaf area specific conductivity did not differ significantly between savanna and forest species. However, maximum leaf hydraulic conductance (K (leaf)) and leaf capacitance tended to be higher in savanna species. Predawn leaf water potential and leaf mass per area were also higher in savanna species in all congeneric pairs. Hydraulic vulnerability curves of stems and leaves indicated that leaves were more vulnerable to drought-induced cavitation than terminal branches regardless of genus. The midday K (leaf) values estimated from leaf vulnerability curves were very low implying that daily embolism repair may occur in leaves. An electric circuit analog model predicted that, compared to forest species, savanna species took longer for their leaf water potentials to drop from predawn values to values corresponding to 50% loss of K (leaf) or to the turgor loss points, suggesting that savanna species were more buffered from changes in leaf water potential. The results of this study suggest that the relative success of savanna over forest species in savanna is related in part to their ability to cope with drought, which is determined more by leaf than by stem hydraulic traits. Variation among genera accounted for a large proportion of the total variance in most traits, which indicates that, despite different selective pressures in savanna and forest habitats, phylogeny has a stronger effect than habitat in determining most hydraulic traits.