Please use this identifier to cite or link to this item: http://hdl.handle.net/123456789/488
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dc.contributor.authorSchmitz, N.-
dc.contributor.authorJansen, S.-
dc.contributor.authorVerheyden, A-
dc.contributor.authorKairo, J.-
dc.contributor.authorBeeckman, H.-
dc.contributor.authorKoedam, N.-
dc.date.accessioned2018-10-15T14:56:19Z-
dc.date.available2018-10-15T14:56:19Z-
dc.date.issued2007-
dc.identifier.citationAnnals of Botany Vol. 100 pp. 271–281en_US
dc.identifier.issn0305-7364-
dc.identifier.urihttp://hdl.handle.net/123456789/488-
dc.description.abstractBackground and Aims According to the air-seeding hypothesis, embolism vulnerability in xylem elements is linked directly to bordered pit structure and functioning. To elucidate the adaptive potential of intervessel pits towards fluctuating environmental conditions, two mangrove species with a distinct ecological distribution growing along a natural salinity gradient were investigated. †Methods Scanning and transmission electron microscopic observations were conducted to obtain qualitative and quantitative characteristics of alternate intervessel pits in A. marina and scalariform intervessel pits in Rhizophora mucronata. Wood samples from three to six trees were collected at seven and five sites for A. marina and R. mucronata, respectively, with considerable differences between sites in soil water salinity. †Key Results Vestured pits without visible pores in the pit membrane were observed in A. marina, the mangrove species with the widest geographical distribution on global as well as local scale. Their thick pit membranes (on average 370 nm) and minute pit apertures may contribute to reduced vulnerability to cavitation of this highly salt-tolerant species. The smaller ecological distribution of R. mucronata was in accordance with wide pit apertures and a slightly higher pitfield fraction (67 % vs. 60 % in A. marina). Nonetheless, its outer pit apertures were observed to be funnel-shaped shielding non-porous pit membranes. No trends in intervessel pit size were observed with increasing soil water salinity of the site. †Conclusions The contrasting ecological distribution of two mangrove species was reflected in the geometry and pit membrane characteristics of their intervessel pits. Within species, intervessel pit size seemed to be independent of spatial variations in environmental conditions and was only weakly correlated with vessel diameter. Further research on pit formation and function has to clarify the large variations in intervessel pit size within trees and even within single vesselsen_US
dc.language.isoenen_US
dc.publisherOxford journalsen_US
dc.subjectRhizophora mucronataen_US
dc.subjectAvicennia marinaen_US
dc.subjectIntervessel pitsen_US
dc.subjectSalinityen_US
dc.subjectKenyaen_US
dc.subjectPit membraneen_US
dc.subjectVesturesen_US
dc.subjectEcological wood anatomyen_US
dc.subjectCavitation vulnerabilityen_US
dc.subjectXylemen_US
dc.subjectFeld-emission SEMen_US
dc.subjectTEMen_US
dc.titleComparative Anatomy of Intervessel Pits in Two Mangrove Species Growing Along a Natural Salinity Gradient in Gazi Bay, Kenyaen_US
dc.typeArticleen_US
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