Optimal leaf water status regulation of plants in drylands

Ratzmann, Gregor; Zakharova, Liubov; Tietjen, Britta

doi:10.1038/s41598-019-40448-2

Cited by 34 publications

(26 citation statements)

References 31 publications

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“…, Ratzmann et al. ), and most of these traits are as‐yet poorly known among savanna trees, particularly in African species. Characterizing this variability across species should be a priority, especially for predicting compositional and functional shifts under future increases in drought frequency and severity.…”

Section: Discussionmentioning

confidence: 99%

Severe drought limits trees in a semi‐arid savanna

Case

Coetsee

Nzima

et al. 2019

Ecology

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Increasingly frequent and severe droughts under climate change are expected to have major impacts on vegetation worldwide. However, research to date has focused on tree vulnerability to drought in forests. Less is known about trees and drought in savannas, where a sparse tree layer coexists with grass. These tree–grass interactions (often mediated by fire and herbivory) shape savanna tree ecology, and confound predictions of how strongly drought might affect trees. On the one hand, drought is physiologically stressful, which could harm trees and be exacerbated by herbivore impacts; on the other hand, trees adapted to semiarid savannas might be relatively drought tolerant, and the considerable impacts of drought on grass could even benefit trees via reduced grass competition and fire risk, especially in the year following a drought. Here, we sought to understand the net effects of severe drought on the savanna tree layer, and how fire and herbivory mediate these effects. We monitored tree growth, mortality, and community structure for 2 yr within existing long‐term fire and herbivory experiments across a drought‐severity contrast, following a major drought in Kruger National Park, South Africa. Overall, severe drought was a major stressor for trees. Tree mortality rates in most species increased by an order of magnitude in the year following drought, and slower growth rates for some persisted for 2 yr. At the community level, this translated into substantial decreases in tree densities. Herbivory and fire did little either to mitigate or exacerbate drought effects on trees, and overall, drought swamped effects of herbivory and fire that have otherwise been observed. However, species differed in their responses to drought, with some dominant encroaching species especially vulnerable. We suggest that increasing drought frequency and severity could drastically alter savanna vegetation by repeatedly killing off trees.

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Section: Discussionmentioning

confidence: 99%

Severe drought limits trees in a semi‐arid savanna

Case

Coetsee

Nzima

et al. 2019

Ecology

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“…The LWP plays an important role in stomatal conductance, CO 2 uptake, xylem functioning, water supply and the growth of cells. When plants uptake CO 2 , then they drop their LWP through transpiration to avoid a reduction in growth [ 61 ]. However, the LWP mean value ( Table 2 ) was found significantly lower than all plant types of the USA [ 62 ].…”

Section: Discussionmentioning

confidence: 99%

“…For plant life forms, desert shrubs accrued more C, N and K and showed more LWP than the herbs and subshrubs; and subshrubs showed higher concentration of P than the herbs and shrubs; while, the value of δ 13 C was found roughly similar for all life forms, such as herbs, shrubs and subshrubs ( Table 2 ). Leaves C, N and K are tightly coupled with main biological functions, like photosynthesis, respiration and water use [ 38 , 64 ]; while, leaf water potential depict the water status of the plant [ 65 ], the key process for ecosystem functioning [ 61 ], influenced plant productivity, photosynthesis and growth [ 66 ]; so, desert plants regulate optimal leaf water status for their survival which is a basic constituent of plant functioning [ 61 ]. This is the reason shrubs dominate most of the desert lands [ 67 ].…”

Section: Discussionmentioning

confidence: 99%

“…LWP mean value ( Table 2 ) was found significantly lower than all plant types of the USA [ 62 ]. Low LWP is common in arid areas [ 61 ] and in these areas, WUE can be enhanced by reducing H 2 O and CO 2 balance [ 63 ].…”

Section: Discussionmentioning

confidence: 99%

“…The elements of the first PCA axis were primarily necessary for plant structure, photosynthesis and protein synthesis [ 19 , 32 ]. The elements associated with the second and third PCA axis were essential for enzyme activity, stomatal conductance, regulation of transpiration and plant water supply [ 53 , 61 ].…”

Section: Discussionmentioning

confidence: 99%

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Convergent Variations in the Leaf Traits of Desert Plants

Akram

Wang

et al. 2020

Plants

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Convergence is commonly caused by environmental filtering, severe climatic conditions and local disturbance. The basic aim of the present study was to understand the pattern of leaf traits across diverse desert plant species in a common garden, in addition to determining the effect of plant life forms (PLF), such as herb, shrub and subshrub, phylogeny and soil properties on leaf traits. Six leaf traits, namely carbon (C), nitrogen (N), phosphorus (P), potassium (K), δ13C and leaf water potential (LWP) of 37 dominant desert plant species were investigated and analyzed. The C, N, K and δ13C concentrations in leaves of shrubs were found higher than herbs and subshrubs; however, P and LWP levels were higher in the leaves of subshrubs following herbs and shrubs. Moreover, leaf C showed a significant positive correlation with N and a negative correlation with δ13C. Leaf N exhibited a positive correlation with P. The relationship between soil and plant macro-elements was found generally insignificant but soil C and N exhibited a significant positive correlation with leaf P. Taxonomy showed a stronger effect on leaf C, N, P and δ13C than soil properties, explaining >50% of the total variability. C3 plants showed higher leaf C, N, P, K and LWP concentration than C4 plants, whereas C4 plants had higher δ13C than C3 plants. Legumes exhibited higher leaf C, N, K and LWP than nonlegumes, while nonlegumes had higher P and δ13C concentration than legumes. In all the species, significant phylogenetic signals (PS) were detected for C and N and nonsignificant PS for the rest of the leaf traits. In addition, these phylogenetic signals were found lower (K-value < 1), and the maximum K-value was noted for C (K = 0.35). The plants of common garden evolved and adapted themselves for their survival in the arid environment and showed convergent variations in their leaf traits. However, these variations were not phylogenetics-specific. Furthermore, marks of convergence found in leaf traits of the study area were most likely due to the environmental factors.

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