Abstract
Water transport in conifers occurs through single-celled tracheids that are connected to one another via intertracheid pit membranes. These membranes have two components: the porous margo, which allows water to pass through the membrane, and the impermeable torus, which functions to isolate gas-filled tracheids. During drought, tracheids can become air filled and thus hydraulically dysfunctional, a result of air entering through the pit membrane and nucleating cavitation in the water column. What are the hydraulic tradeoffs associated with cavitation resistance at the pit level, and how do they vary within the structural components of the intertracheid pit? To address these questions, we examined pit structure in 15 species of Cupressaceae exhibiting a broad range of cavitation resistances. Across species, cavitation resistance was most closely correlated to the ratio of the torus to pit aperture diameter but did not vary systematically with margo porosity. Furthermore, our data indicate that constraints on pit hydraulic efficiency are shared: the pit aperture limits pit conductivity in more drought-resistant taxa, while increased margo resistance is more likely to control pit conductivity in species that are more vulnerable to cavitation. These results are coupled with additional data concerning pit membrane structure and function and are discussed in the context of the evolutionary biogeography of the Cupressaceae.
Highlights
Water transport in conifers occurs through single-celled tracheids that are connected to one another via intertracheid pit membranes
Species vulnerability to cavitation was determined by measuring the segment percentage loss of conductivity in response to progressively more negative xylem pressures induced by centrifugation (Alder et al, 1997; see “Materials and Methods”)
The xylem pressures at which stems showed 50% loss of conductivity spanned a broad range from 22.8 6 0.62 MPa in the semiriparian Glyptostrobus pensilis to a low of 211.3 6 3.52 MPa recorded in xericadapted Widdringtonia cedarbergensis
Summary
Water transport in conifers occurs through single-celled tracheids that are connected to one another via intertracheid pit membranes. Our data indicate that constraints on pit hydraulic efficiency are shared: the pit aperture limits pit conductivity in more drought-resistant taxa, while increased margo resistance is more likely to control pit conductivity in species that are more vulnerable to cavitation These results are coupled with additional data concerning pit membrane structure and function and are discussed in the context of the evolutionary biogeography of the Cupressaceae. Should an air-seeding event (cavitation) occur, causing a tracheid to become air filled, (i.e. embolized), the negative xylem pressure in the water-filled tracheid will act on the air-water interface in the margo pores by deflecting the pit membrane in the direction of the functional tracheid, thereby appressing the torus against the pit aperture border (Bailey, 1913; Liese, 1965; Liese and Bauch, 1967; Petty, 1972). Compounding this complexity is an additional problem: despite one qualitative survey of pits from 120 gymnosperms (Bauch et al, 1972), very little is known about the structural variation of the margo, and even less about how this variation could relate to cavitation resistance
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