Microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species

Mistletoes absorb water from the vascular system of their hosts and thus the water use of mistletoes can be influenced by the water status of their hosts besides abiotic environmental conditions; however, there is a lack of studies on the dynamics of mistletoe water utilization in relation to both t...

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Autores principales: Yang, D., Goldstein, G., Wang, M., Zhang, W.-W., Wang, A.-Y., Liu, Y.-Y., Hao, G.-Y.
Formato: JOUR
Materias:
Hemi-parasitic plant
plant water relations
transpiration
vascular parasitic plant
water use.
water
evapotranspiration
microclimate
parasitology
photosynthesis
physiology
tree
Viscum
xylem
Microclimate
Photosynthesis
Plant Transpiration
Trees
Water
Xylem
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_0829318X_v37_n4_p501_Yang
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_0829318X_v37_n4_p501_Yang
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spelling todo:paper_0829318X_v37_n4_p501_Yang2023-10-03T15:40:08Z Microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species Yang, D. Goldstein, G. Wang, M. Zhang, W.-W. Wang, A.-Y. Liu, Y.-Y. Hao, G.-Y. Hemi-parasitic plant plant water relations transpiration vascular parasitic plant water use. water evapotranspiration microclimate parasitology photosynthesis physiology tree Viscum xylem Microclimate Photosynthesis Plant Transpiration Trees Viscum Water Xylem Mistletoes absorb water from the vascular system of their hosts and thus the water use of mistletoes can be influenced by the water status of their hosts besides abiotic environmental conditions; however, there is a lack of studies on the dynamics of mistletoe water utilization in relation to both types of controlling factors. By building a canopy platform at 20 m above the ground, we monitored the dynamic changes of sap flow of Viscum coloratum (Kom.) Nakai (Loranthaceae) in combination with continuous measurements of microclimatic variables and volumetric water content (VWC) of its host tree branch xylem. We found that the host tree VWC exhibited substantial fluctuations during sunny days but lower VWC of the host did not negatively affect the sap flow of V. coloratum. Hourly and daily mean transpiration rates (Esap) of V. coloratum calculated from sap flow measurements showed strong positive correlations with photosynthetic photon flux density (PPFD) and vapor pressure deficit (VPD) measured in close vicinity to the point of mistletoe attachment. The mean Esap of V. coloratum was substantially higher than that of their host during clear days (4.55 ± 0.54 vs 2.01 ± 0.15 kg m-2 day-1). Moreover, the mistletoe-to-host transpiration ratio was not constant but became increasingly larger with the increase of PPFD or VPD on both hourly and daily bases, suggesting a weaker control of water loss in the mistletoe in comparison to its host species. The strong dependence of mistletoe Esap on micrometeorological variables and its decoupling from the host tree xylem water status suggests that the development of dense tree canopy functions as a potential mechanism for the host trees in reducing the competitive water use of mistletoes. These findings have important implications for the interactions between mistletoe species and their host trees in temperate forests. © 2016 The Author. Fil:Goldstein, G. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_0829318X_v37_n4_p501_Yang
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Hemi-parasitic plant
plant water relations
transpiration
vascular parasitic plant
water use.
water
evapotranspiration
microclimate
parasitology
photosynthesis
physiology
tree
Viscum
xylem
Microclimate
Photosynthesis
Plant Transpiration
Trees
Viscum
Water
Xylem
spellingShingle Hemi-parasitic plant
plant water relations
transpiration
vascular parasitic plant
water use.
water
evapotranspiration
microclimate
parasitology
photosynthesis
physiology
tree
Viscum
xylem
Microclimate
Photosynthesis
Plant Transpiration
Trees
Viscum
Water
Xylem
Yang, D.
Goldstein, G.
Wang, M.
Zhang, W.-W.
Wang, A.-Y.
Liu, Y.-Y.
Hao, G.-Y.
Microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species
topic_facet Hemi-parasitic plant
plant water relations
transpiration
vascular parasitic plant
water use.
water
evapotranspiration
microclimate
parasitology
photosynthesis
physiology
tree
Viscum
xylem
Microclimate
Photosynthesis
Plant Transpiration
Trees
Viscum
Water
Xylem
description Mistletoes absorb water from the vascular system of their hosts and thus the water use of mistletoes can be influenced by the water status of their hosts besides abiotic environmental conditions; however, there is a lack of studies on the dynamics of mistletoe water utilization in relation to both types of controlling factors. By building a canopy platform at 20 m above the ground, we monitored the dynamic changes of sap flow of Viscum coloratum (Kom.) Nakai (Loranthaceae) in combination with continuous measurements of microclimatic variables and volumetric water content (VWC) of its host tree branch xylem. We found that the host tree VWC exhibited substantial fluctuations during sunny days but lower VWC of the host did not negatively affect the sap flow of V. coloratum. Hourly and daily mean transpiration rates (Esap) of V. coloratum calculated from sap flow measurements showed strong positive correlations with photosynthetic photon flux density (PPFD) and vapor pressure deficit (VPD) measured in close vicinity to the point of mistletoe attachment. The mean Esap of V. coloratum was substantially higher than that of their host during clear days (4.55 ± 0.54 vs 2.01 ± 0.15 kg m-2 day-1). Moreover, the mistletoe-to-host transpiration ratio was not constant but became increasingly larger with the increase of PPFD or VPD on both hourly and daily bases, suggesting a weaker control of water loss in the mistletoe in comparison to its host species. The strong dependence of mistletoe Esap on micrometeorological variables and its decoupling from the host tree xylem water status suggests that the development of dense tree canopy functions as a potential mechanism for the host trees in reducing the competitive water use of mistletoes. These findings have important implications for the interactions between mistletoe species and their host trees in temperate forests. © 2016 The Author.
format JOUR
author Yang, D.
Goldstein, G.
Wang, M.
Zhang, W.-W.
Wang, A.-Y.
Liu, Y.-Y.
Hao, G.-Y.
author_facet Yang, D.
Goldstein, G.
Wang, M.
Zhang, W.-W.
Wang, A.-Y.
Liu, Y.-Y.
Hao, G.-Y.
author_sort Yang, D.
title Microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species
title_short Microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species
title_full Microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species
title_fullStr Microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species
title_full_unstemmed Microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species
title_sort microenvironment in the canopy rivals the host tree water status in controlling sap flow of a mistletoe species
url http://hdl.handle.net/20.500.12110/paper_0829318X_v37_n4_p501_Yang
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AT zhangww microenvironmentinthecanopyrivalsthehosttreewaterstatusincontrollingsapflowofamistletoespecies
AT wangay microenvironmentinthecanopyrivalsthehosttreewaterstatusincontrollingsapflowofamistletoespecies
AT liuyy microenvironmentinthecanopyrivalsthehosttreewaterstatusincontrollingsapflowofamistletoespecies
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