Variability and Plasticity in Cuticular Transpiration and Leaf Permeability Allow Differentiation of Eucalyptus Clones at an Early Age

Carignato, André; Vázquez‐Piqué, Javier; Tapias, R.; Ruiz, Federico; Fernández, Manuel

doi:10.3390/f11010009

Cited by 18 publications

(17 citation statements)

References 65 publications

(94 reference statements)

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“…This fact was demonstrably related to the leaf area. In a study by Carignato et al [15], the behavior pattern of cuticular transpiration did not differ significantly based on leaf area in terms of differentiation among clones. The reduction in cuticular transpiration mentioned above may be due to increased accumulation of cuticular wax on the leaf surface because the wax layer is a fundamental water transport-limiting barrier of the cuticle, especially when the stomata are fully closed under stress conditions [37].…”

Section: Discussionmentioning

confidence: 83%

“…Cuticle thickness, ultrastructure, and chemical composition can vary dramatically in a species-, organ-and tissue-specific manner [2,11]. Thus, as they develop their leaves, plants can resort to specific morphological alterations to regulate their water losses, such as changes in the palisade parenchyma thickness [12] or the epidermis and cuticle water tightness [13], the latter being essential to control water losses, especially during drought periods, through cuticular transpiration [14,15].…”

Section: Introductionmentioning

confidence: 99%

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Diversity of Leaf Cuticular Transpiration and Growth Traits in Field-Grown Wheat and Aegilops Genetic Resources

et al. 2021

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Plants are subjected to unregulated water loss from their surface by cuticular transpiration. Therefore, specific morphophysiological changes may occur during leaf development to eliminate water loss. This study aimed to examine the cuticular transpiration of 23 winter wheat genotypes and their wild-growing predecessors of the genus Aegilops, which were divided into three groups to demonstrate their diversity. The genotypes were sown in autumn and grown in regular field trials at the Research Institute of Plant Production in Piešťany, Slovakia. Cuticular transpiration and growth parameters were analyzed in the postanthesis growth stage. Gravimetric measurement of residual water loss was performed on detached leaves with a precisely measured leaf area. The lowest nonproductive transpiration values were observed in modern wheat genotypes, while higher cuticular transpiration was observed in a group of landraces. Aegilops species generally showed the highest cuticular transpiration with increased water loss, but the total water loss per plot was low due to the low leaf area of the wild wheat relatives. Some of the growth parameters showed a good correlation with cuticular transpiration (e.g., dry mass per plant), but direct relationships between leaf traits and cuticular transpiration were not observed. This study identified a high diversity in cuticular resistance to water loss in wheat and Aegilops accessions of different origins. The potential of identifying and exploiting genetic resources with favorable cuticular transpiration in crop breeding is discussed.

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Section: Discussionmentioning

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Diversity of Leaf Cuticular Transpiration and Growth Traits in Field-Grown Wheat and Aegilops Genetic Resources

et al. 2021

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“…Eucalyptus is characterized by rapid growth, high yield, stress resistance, barren tolerance, good stem form, and extensive use. In many countries of the world, Eucalyptus is promoted for large-scale afforestation and is one of the four fast-growing genera used for afforestation in the world [1] . The total area of Eucalyptus and Pinus plantations accounts for approximately 30% of the global plantation area [2] .…”

Section: Introductionmentioning

confidence: 99%

“…(3) a reduction in biological diversity (creation of ecological 'green deserts'); and (4) poor ecological stability [9][10][11][12] . The following questions address these concerns: (1) How can ecological problems related to Eucalyptus plantations be addressed while improving their cultivation patterns and achieving technological innovation? (2) How can the adverse effects of Eucalyptus afforestation in the environment be minimized in a way that allows Eucalyptus plantations to play a role in substituting natural forest harvesting?…”

Section: Introductionmentioning

confidence: 99%

Eucalyptus Productivity Increase in China Comes From Newly Afforested Plantations

Wei

Zheng

Dang

et al. 2020

Preprint

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Eucalyptus trees are a major fast-growing species in southern China. The ecological problems associated with constantly developing new Eucalyptus plantations have been the focus of extensive debate. In this study, we used spatial analysis and geostatistical methods along with four continuous national forest resource inventories and meteorological data to analyze dynamic changes in the distribution of Eucalyptus plantations in China. The productivity levels of Eucalyptus plantations were compared at different time periods by measuring annual mean productivity in permanent sample plots to provide baseline data related to the scientific management of Eucalyptus plantations. Results showed that the area of Eucalyptus plantations increased constantly in China from 1998 to 2013, expanding from 60.7 × 104 hm2 in 1998 to more than 445.5 × 104 hm2 in 2013. The productivity of Eucalyptus plantations was positively correlated with temperature and rainfall, but negatively correlated with elevation. However, these changes did not necessarily indicate an improvement in the management quality of Eucalyptus plantations, because they were mainly caused by an increased in the proportion of newly reclaimed areas for Eucalyptus afforestation and the constantly decreasing area of original Eucalyptus plantations, to which sufficient attention must be given.

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“…Several papers discuss the inheritance of trees and relationship between genotype and environment, which is important to understand for forest tree improvement. Carignato et al [7] report genetic variability in drought resistance among Eucalyptus clones and indicate the possibility of early selection in the nursery. Two papers evaluate selected P. thunbergii clones in terms of pine wood nematode resistance [8,9].…”

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confidence: 99%

Genetics and Improvement of Forest Trees

Ide

2021

Forests

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Variability and Plasticity in Cuticular Transpiration and Leaf Permeability Allow Differentiation of Eucalyptus Clones at an Early Age

Cited by 18 publications

References 65 publications

Diversity of Leaf Cuticular Transpiration and Growth Traits in Field-Grown Wheat and Aegilops Genetic Resources

Diversity of Leaf Cuticular Transpiration and Growth Traits in Field-Grown Wheat and Aegilops Genetic Resources

Eucalyptus Productivity Increase in China Comes From Newly Afforested Plantations

Genetics and Improvement of Forest Trees

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