Hydraulic conductance and the maintenance of water balance in flowers

Roddy, Adam B.; Brodersen, Craig R.; Dawson, Todd E.

doi:10.1111/pce.12761

Cited by 66 publications

(138 citation statements)

References 64 publications

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“…According to physical principles and experimental evidence, regulating the atmospheric moisture was an efficient solution for suppressing the excess driving force. The mass of plant water transport through the plant must balance the transpiration losses from the leaves, which can be expressed as follows1516:…”

Section: Discussionmentioning

confidence: 99%

Vapour pressure deficit control in relation to water transport and water productivity in greenhouse tomato production during summer

Zhang

et al. 2017

Sci Rep

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Although atmospheric vapour pressure deficit (VPD) has been widely recognized as the evaporative driving force for water transport, the potential to reduce plant water consumption and improve water productivity by regulating VPD is highly uncertain. To bridge this gap, water transport in combination with plant productivity was examined in tomato (Solanum lycopersicum L.) plants grown under contrasting VPD gradients. The driving force for water transport was substantially reduced in low-VPD treatment, which consequently decreased water loss rate and moderated plant water stress: leaf desiccation, hydraulic limitation and excessive negative water potential were prevented by maintaining water balance. Alleviation in water stress by reducing VPD sustained stomatal function and photosynthesis, with concomitant improvements in biomass and fruit production. From physiological perspectives, suppression of the driving force and water flow rate substantially reduced cumulative transpiration by 19.9%. In accordance with physiological principles, irrigation water use efficiency as criterions of biomass and fruit yield in low-VPD treatment was significantly increased by 36.8% and 39.1%, respectively. The reduction in irrigation was counterbalanced by input of fogging water to some extent. Net water saving can be increased by enabling greater planting densities and improving the evaporative efficiency of the mechanical system.

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Section: Discussionmentioning

confidence: 99%

Vapour pressure deficit control in relation to water transport and water productivity in greenhouse tomato production during summer

Zhang

et al. 2017

Sci Rep

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“…For example, the water costs of flowers can limit flower size and impede leaf function (Galen, ; Galen, Sherry, & Carroll, ; Lambrecht, ; Lambrecht & Dawson, ; Teixido & Valladares, , ). This requirement of maintaining water balance has led to coordinated shifts in hydraulic traits that vary systematically across the angiosperm phylogeny (Roddy, Brodersen, & Dawson, ) and with other pollination traits, such as floral lifespan (Zhang et al, ).…”

Section: Introductionmentioning

confidence: 99%

Water relations of Calycanthus flowers: Hydraulic conductance, capacitance, and embolism resistance

Roddy

Simonin

McCulloh

et al. 2018

Plant Cell & Environment

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For most angiosperms, producing and maintaining flowers is critical to sexual reproduction, yet little is known about the physiological processes involved in maintaining flowers throughout anthesis. Among extant species, flowers of the genus Calycanthus have the highest hydraulic conductance and vein densities of species measured to date, yet they can wilt by late morning under hot conditions. Here, we combine diurnal measurements of gas exchange and water potential, pressure-volume relations, functional responses of gas exchange, and characterization of embolism formation using high resolution X-ray computed microtomography to determine drought responses of Calycanthus flowers. Transpiration from flowers frequently exceeded transpiration from leaves, and flowers were unable to limit transpiration under conditions of high vapour pressure deficit. As a result, they rely heavily on hydraulic capacitance to prevent water potential declines. Despite having high water potentials at turgor loss, flowers were very resistant to embolism formation, with no embolism apparent until tepal water potentials had declined to -2 MPa. Although Calycanthus flowers remain connected to the stem xylem and have high hydraulic capacitance, their inability to curtail transpiration leads to turgor loss. These results suggest that extreme climate events may cause flower failure, potentially preventing successful reproduction.

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“…Flower maintenance may require a considerable amount of water (Roddy and Dawson, 2012) and, under dry conditions, those plants can lose more water from their flowers than from the leaves (Lambrecht, 2013). Therefore, understanding the physiological mechanisms of floral water transport and water relations may provide new insights into the evolution of flowers (Galen, 2000; Chapotin et al, 2003; Feild et al, 2009a,b; Roddy et al, 2016). Even though water has an essential role throughout the floral lifespan, few studies have focused on water relations in flowers (Feild et al, 2009b; Lambrecht et al, 2011; Roddy et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, understanding the physiological mechanisms of floral water transport and water relations may provide new insights into the evolution of flowers (Galen, 2000; Chapotin et al, 2003; Feild et al, 2009a,b; Roddy et al, 2016). Even though water has an essential role throughout the floral lifespan, few studies have focused on water relations in flowers (Feild et al, 2009b; Lambrecht et al, 2011; Roddy et al, 2016). Contrasting results in different species have indicated that some flowers are phloem-hydrated (Trolinder et al, 1993; Chapotin et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

Floral Mass per Area and Water Maintenance Traits Are Correlated with Floral Longevity in Paphiopedilum (Orchidaceae)

Zhang

Yang

et al. 2017

Front. Plant Sci.

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Floral longevity (FL) determines the balance between pollination success and flower maintenance. While a longer floral duration enhances the ability of plants to attract pollinators, it can be detrimental if it negatively affects overall plant fitness. Longer-lived leaves display a positive correlation with their dry mass per unit area, which influences leaf construction costs and physiological functions. However, little is known about the association among FL and floral dry mass per unit area (FMA) and water maintenance traits. We investigated whether increased FL might incur similar costs. Our assessment of 11 species of Paphiopedilum (slipper orchids) considered the impact of FMA and flower water-maintenance characteristics on FL. We found a positive relationship between FL and FMA. Floral longevity showed significant correlations with osmotic potential at the turgor loss and bulk modulus of elasticity but not with FA. Neither the size nor the mass per area was correlated between leaves and flowers, indicating that flower and leaf economic traits evolved independently. Therefore, our findings demonstrate a clear relationship between FL and the capacity to maintain water status in the flower. These economic constraints also indicate that extending the flower life span can have a high physiological cost in Paphiopedilum.

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Hydraulic conductance and the maintenance of water balance in flowers

Cited by 66 publications

References 64 publications

Vapour pressure deficit control in relation to water transport and water productivity in greenhouse tomato production during summer

Vapour pressure deficit control in relation to water transport and water productivity in greenhouse tomato production during summer

Water relations of Calycanthus flowers: Hydraulic conductance, capacitance, and embolism resistance

Floral Mass per Area and Water Maintenance Traits Are Correlated with Floral Longevity in Paphiopedilum (Orchidaceae)

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