Abstract
Environmental and physiological regulation of transpiration were examined in several gap-colonizing shrub and tree species during two consecutive dry seasons in a moist, lowland tropical forest on Barro Colorado Island, Panama. Whole plant transpiration, stomatal and total vapor phase (stomatal + boundary layer) conductance, plant water potential and environmental variables were measured concurrently. This allowed control of transpiration (E) to be partitioned quantitatively between stomatal (g s) and boundary layer (g b) conductance and permitted the impact of invividual environmental and physiological variables on stomatal behavior and E to be assessed. Wind speed in treefall gap sites was often below the 0.25 m s−1 stalling speed of the anemometer used and was rarely above 0.5 m s−1, resulting in uniformly low g b (c. 200–300 mmol m−2 s−1) among all species studied regardless of leaf size. Stomatal conductance was typically equal to or somewhat greater than g b. This strongly decoupled E from control by stomata, so that in Miconia argentea a 10% change in g s when g s was near its mean value was predicted to yield only a 2.5% change in E. Porometric estimates of E, obtained as the product of g s and the leaf-bulk air vapor pressure difference (VPD) without taking g b into account, were up to 300% higher than actual E determined from sap flow measurements. Porometry was thus inadequate as a means of assessing the physiological consequences of stomatal behavior in different gap colonizing species. Stomatal responses to humidity strongly limited the increase in E with increasing evaporative demand. Stomata of all species studied appeared to respond to increasing evaporative demand in the same manner when the leaf surface was selected as the reference point for determination of external vapor pressure and when simultaneous variation of light and leaf-air VPD was taken into account. This result suggests that contrasting stomatal responses to similar leaf-bulk air VPD may be governed as much by the external boundary layer as by intrinsic physiological differences among species. Both E and g s initially increased sharply with increasing leaf area-specific total hydraulic conductance of the soil/root/leaf pathway (G t), becoming asymptotic at higher values of G t. For both E and g s a unique relationship appeared to describe the response of all species to variations in G t. The relatively weak correlation observed between g s and midday leaf water potential suggested that stomatal adjustment to variations in water availability coordinated E with water transport efficiency rather than bulk leaf water status.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Baker JM, Van Bavel CHM (1987) Measurement of the mass flow of water in the stems of herbaceous plants. Plant Cell Environ 10:777–782
Becker P, Rabenold PE, Idol JR, Smith AP (1988) Gap and slope gradients of soil and plant water potentials during the dry season in a tropical moist forest. J Trop Ecol 4:173–184
Bunce J (1985) Effect of boundary layer conductance on the stomatal response to humidity. Plant Cell Environ 8:55–57
Croat TB (1978) Flora of Barro Colorado Island. Stanford University Press. Stanford
Fanjul L, Barradas VL (1985) Stomatal behaviour of two heliophile understorey species of a tropical deciduous forest in Mexico. J Appl Ecol 22:943–954
Foster RB, Brokaw NVL (1982) Structure and history of the vegetation of Barro Colorado Island. In: Leigh E Jr, Rand AS, Windsor DM (eds), The ecology of a tropical forest. Seasonal rhythms and long-term changes. Smithsonian Institution Press, Washington, pp 67–81
Grace J, Fasehun FE, Dixon M (1980) Boundary layer conductance of the leaves of some tropical timber trees. Plant Cell Environ 3:443–450
Grace J, Okali DUU, Fasehun FE (1982) Stomatal conductance of two tropical trees during the wet season in Nigeria. J Appl Ecol 19:659–670
Gutiérrez MV, Harrington R, Meinzer FC, Fownes JH (1994) The effect of environmentally induced stem temperature gradients on transpiration estimates from the heat balance method in two tropical woody species. Tree Physiol 14:179–190
Heilman JL, Ham JM (1990) Measurement of mass flow rate of sap in Ligustrum japonicum. Hort Sci 25:465–467
Jackson PC, Cavelier J, Goldstein G, Meinzer FC, Holbrook NM (1995) Partitioning of water resources among plants of a lowland tropical forest. Oecologia (in press)
Jarvis PG, McNaughton KG (1986) Stomatal control of transpiration: Scaling up from leaf to region. Adv Ecol Res 15:1–49
Körner Ch, Scheel JA, Bauer H (1979) Maximum leaf diffusive conductance in vascular plants. Photosynthetica 13:45–82
Martin P (1989) The significance of radiative coupling between vegetation and the atmosphere. Agric For Meterol 49:45–53
McNaughton KG, Jarvis PG (1991) Effects of spatial scale on stomatal control of transpiration. Agric For Meteorol 54:279–301
Meinzer FC, Grantz DA, Smit B (1991) Root signals mediate coordination of stomatal and hydraulic conductance in growing sugarcane. Aust J Plant Physiol 18:329–338
Meinzer FC, Goldstein G, Holbrook NM, Jackson P, Cavelier J (1993) Stomatal and environmental control of transpiration in a lowland tropical forest tree. Plant Cell Environ 16:429–436
Mulkey SS, Wright SJ, Smith AP (1991) Drought acclimation of an understory shurb (Psychotria limonensis; Rubiaceae) in a seasonally dry tropical forest in Panama. Am J Bot 78:579–587
Mulkey SS, Smith AP, Wright SJ, Machado JL, Dudley R (1992) Contrasting leaf phenotypes control seasonal variation in water loss in a tropical forest shrub. Proc Natl Acad Sci USA 89:9084–9088
Mulkey SS, Wright SJ, Smith AP (1993) Comparative physiology and demography of three neotropical forest shrubs: Alternative shade-adaptive character syndromes. Oecologia 96:526–537
Reekie EG, Wayne P (1992) Leaf canopy display, stomatal conductance, and photosynthesis in seedlings of three tropical pioneer trees subjected to drought. Can J Bot 70:2334–2338
Roberts J, Cabral OMR, De Aguiar LF (1990) Stomatal and boundary-layer conductances in an Amazonian terra firme rain forest. J Appl Ecol 27:336–353
Saliendra NZ, Meinzer FC (1989) Relationship between root/soil hydraulic properties and stomatal behavior in sugarcane. Aust J Plant Physiol 16:241–250
Sperry JS, Pockman WT (1993) Limitation of transpiration by hydraulic conductance and xylem cavitation in Betula occidentalis. Plant Cell Environ 16:279–287
Steinberg S, Van Bavel CHM, McFarland MJ (1989) A gauge to measure mass flow rate of sap in stems and trunks of woody plants. J Am Soc Hort Sci 114:466–472
Steinberg S, McFarland MJ, Worthington JW (1990) Comparison of trunk and branch sap flow with canopy transpiration in pecan. J Exp Bot 41:653–659
Wright SJ (1991) Seasonal drought and phenology of understory shrubs in a tropical moist forest. Ecology 72:1643–1657
Wright SJ, Cornejo FH (1990) Seasonal drought and leaf fall in a tropical forest. Ecology 71:1165–1175
Wright SJ, Machado JL, Mulkey SS, Smith AP (1992) Drought acclimation among tropical forest shrubs (Psychotria, Rubiaceae). Oecologia 89:457–463
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Meinzer, F.C., Goldstein, G., Jackson, P. et al. Environmental and physiological regulation of transpiration in tropical forest gap species: the influence of boundary layer and hydraulic properties. Oecologia 101, 514–522 (1995). https://doi.org/10.1007/BF00329432
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00329432