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Hydraulic architecture of Monstera acuminata: evolutionary consequences of the hemiepiphytic growth form

Published online by Cambridge University Press:  01 February 2000

J. LÓPEZ-PORTILLO
Affiliation:
Instituto de Ecología, A. C., Apdo Postal 63, Xalapa 91000 Veracruz, México
F. W. EWERS
Affiliation:
Department of Botany and Plant Pathology, Michigan State University, East Lansing, Michigan 48824, USA
G. ANGELES
Affiliation:
Instituto de Ecología, A. C., Apdo Postal 63, Xalapa 91000 Veracruz, México
J. B. FISHER
Affiliation:
Fairchild Tropical Garden, 11935 Old Cutler Road, Miami, Florida 33156, USA
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Abstract

The hydraulic architecture of the secondary hemiepiphyte Monstera acuminata was examined in native plants from Los Tuxtlas, Veracruz, Mexico, to determine how it compared to better-known growth forms such as trees, shrubs, lianas and primary hemiepiphytes. Monstera acuminata starts its life cycle as a prostrate herb. As it ascends a tree or other vertical support, the stem becomes thicker, produces larger leaves, and may die back from the base upwards until only aerial feeding roots serve to connect the stem to the soil. Unlike the pattern of vessel-size distribution along the stems of woody dicotyledons, M. acuminata has its wider vessels at the top of the stem, decreasing in diameter towards the base. Also peculiar is the fact that Huber values (axis area/distal leaf area) tend to increase exponentially at higher positions within the plant. Based on the hydraulic conductivity (kh) and leaf-specific conductivity (LSC, kh/distal leaf area), the base of the stem potentially acts as a severe hydraulic constriction. This constriction is apparently not limiting, as aerial roots are produced further up the stem. The plants have remarkably strong root pressures, up to 225 kPa, which may contribute to the maintenance of functional vessels by refilling them at night or during periods of very high atmospheric humidity, as in foggy weather and rain. In common with dicotyledonous plants, vessel length, vessel diameter, kh, specific conductivity (ks, kh/axis area) and LSCs were all positively correlated with axis diameter. The features of the hydraulic architecture of M. acuminata may be an evolutionary consequence of an anatomical constraint (lack of vascular cambium and therefore of secondary growth) and the special requirements of the hemiepiphytic growth form.

Type
Research Article
Copyright
© Trustees of the New Phytologist 2000

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