Humidity response of cuticular conductance of beech (Fagus sylvatica L.) leaf discs maintained at high relative water content

Cuticular conductance of adaxial (astomatous) and abaxial (stomatous)surfaces ofFagus sylvatica L. leaves was measured under varyingvapour pressure deficits (D). Conductance was determined fromgravimetric measurements of water flux made using a leaf discenvelope specially designed to maintain leaf relative watercontent and minimize reduction in cuticular hydration. The adaxialsurface provided a determination of ‘true’ cuticularconductance (g_c) and transpiration (E_c). The abaxial surfacewas used to estimate minimum leaf surface conductance (g^MIN_sur)and transpiration (E^MIN_sur). In experiment I, leaf discs wereplaced under one of a range of water vapour pressure deficits(0.4-2.0 kPa). Both g_c and g^MIN_sur decreased approximately 2-foldwith an increase in D between 0.4-2.0 kPa. The decrease in g_cwas linear, but g^MIN_sur declined more steeply at D between 0.4-0.95kPa than at D between 0.95-2.0 kPa. In experiment II, leaf discswere exposed to a stepwise change in D. After a period of acclimationto D of 0.95 kPa, responses of g_c and g^MIN_sur to an increaseor decrease in D were recorded. The response time of g_c to increasingor decreasing D were similar (<60 min). By contrast, g^MIN_surresponded more slowly to increasing than to decreasing D. Thesesignificant responses of g_c and g^MIN_sur to increasing and decreasingD are discussed in relation to hydration state of the cuticleand current knowledge of cuticle structure. Key words: Cuticle, cuticular conductance, cuticular membrane, Fagus sylvatica, humidity, vapour pressure deficit