On the relationship between the composition, morphology and function of leaves

Roderick, Michael L.; Berry, Sandra L.; Saunders, A. M.; Noble, Ian

doi:10.1046/j.1365-2435.1999.00369.x

Cited by 79 publications

(89 citation statements)

References 19 publications

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“…2), indicating that the basic relationships are globally applicable (excluding succulent leaves such as those of CAM plants). The underlying basis of those relationships have been described by Roderick et al (1999b). At elevated [CO # ] the same trends are also apparent and interpretations based on the RSBS-model leaf indicate that a decline in Q is the most likely reason for the changes that have been observed.…”

Section: mentioning

confidence: 60%

The relationship between leaf composition and morphology at elevated CO₂ concentrations

1999

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The composition and morphology of leaves exposed to elevated [ . In the empirical model both the leaf dry mass and liquid mass per unit area are positively correlated with leaf thickness, whereas the mass of C per unit dry mass and the mass of N per unit liquid mass are constant. Consequently, both the N :C ratio and the surface area :volume ratio of leaves are positively correlated with the liquid content. Predictions from that model were consistent with measurements of leaf properties made at ambient [CO # ] from around the world. The changes induced by elevated [CO # ] follow the same overall trajectory. It is concluded that elevated [CO # ] enhances the rate at which dry matter is accumulated but the overall trajectory of leaf development is conserved.

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Section: mentioning

confidence: 60%

The relationship between leaf composition and morphology at elevated CO₂ concentrations

1999

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“…the volume per area) into that of the cells and airspace (Roderick et al, 1999). The "thickness" of the cells (T C,i ) and of intercellular airspace (T A,i ) at each level i of dehydration were calculated:…”

Section: Leaf Shrinkage Experiments: Testing Leaf Responses To Dehydrmentioning

confidence: 99%

Leaf Shrinkage with Dehydration: Coordination with Hydraulic Vulnerability and Drought Tolerance

et al. 2013

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Leaf shrinkage with dehydration has attracted attention for over 100 years, especially as it becomes visibly extreme during drought. However, little has been known of its correlation with physiology. Computer simulations of the leaf hydraulic system showed that a reduction of hydraulic conductance of the mesophyll pathways outside the xylem would cause a strong decline of leaf hydraulic conductance (K leaf ). For 14 diverse species, we tested the hypothesis that shrinkage during dehydration (i.e. in whole leaf, cell and airspace thickness, and leaf area) is associated with reduction in K leaf at declining leaf water potential (C leaf ). We tested hypotheses for the linkage of leaf shrinkage with structural and physiological water relations parameters, including modulus of elasticity, osmotic pressure at full turgor, turgor loss point (TLP), and cuticular conductance. Species originating from moist habitats showed substantial shrinkage during dehydration before reaching TLP, in contrast with species originating from dry habitats. Across species, the decline of K leaf with mild dehydration (i.e. the initial slope of the K leaf versus C leaf curve) correlated with the decline of leaf thickness (the slope of the leaf thickness versus C leaf curve), as expected based on predictions from computer simulations. Leaf thickness shrinkage before TLP correlated across species with lower modulus of elasticity and with less negative osmotic pressure at full turgor, as did leaf area shrinkage between full turgor and oven desiccation. These findings point to a role for leaf shrinkage in hydraulic decline during mild dehydration, with potential impacts on drought adaptation for cells and leaves, influencing plant ecological distributions.

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“…θ will normally be greater for herbaceous vegetation than for woody vegetation (Roderick et al, 1999a(Roderick et al, , 2000, therefore increases in VOD can mean an increase in total AGB, an increase of the fraction of herbaceous vegetation AGB, or both. Finally, the relationship between NDVI and VOD is influenced by the connection between AGB (m) and canopy cover (f ).…”

Section: Background Theorymentioning

confidence: 99%

Global changes in dryland vegetation dynamics (1988–2008) assessed by satellite remote sensing: comparing a new passive microwave vegetation density record with reflective greenness data

et al. 2013

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Abstract. Drylands, covering nearly 30 % of the global land surface, are characterized by high climate variability and sensitivity to land management. Here, two satellite-observed vegetation products were used to study the long-term vegetation changes of global drylands: the widely used reflective-based Normalized Difference Vegetation Index (NDVI) and the recently developed passive-microwavebased Vegetation Optical Depth (VOD). The NDVI is sensitive to the chlorophyll concentrations in the canopy and the canopy cover fraction, while the VOD is sensitive to vegetation water content of both leafy and woody components. Therefore it can be expected that using both products helps to better characterize vegetation dynamics, particularly over regions with mixed herbaceous and woody vegetation. Linear regression analysis was performed between antecedent precipitation and observed NDVI and VOD independently to distinguish the contribution of climatic and non-climatic drivers in vegetation variations. Where possible, the contributions of fire, grazing, agriculture and CO 2 level to vegetation trends were assessed. The results suggest that NDVI is more sensitive to fluctuations in herbaceous vegetation, which primarily uses shallow soil water, whereas VOD is more sensitive to woody vegetation, which additionally can exploit deeper water stores. Globally, evidence is found for woody encroachment over drylands. In the arid drylands, woody encroachment appears to be at the expense of herbaceous vegetation and a global driver is interpreted. Trends in semi-arid drylands vary widely between regions, suggesting that local rather than global drivers caused most of the vegetation response. In savannas, besides precipitation, fire regime plays an important role in shaping trends. Our results demonstrate that NDVI and VOD provide complementary information and allow new insights into dryland vegetation dynamics.

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On the relationship between the composition, morphology and function of leaves

Cited by 79 publications

References 19 publications

The relationship between leaf composition and morphology at elevated CO₂ concentrations

The relationship between leaf composition and morphology at elevated CO₂ concentrations

Leaf Shrinkage with Dehydration: Coordination with Hydraulic Vulnerability and Drought Tolerance

Global changes in dryland vegetation dynamics (1988–2008) assessed by satellite remote sensing: comparing a new passive microwave vegetation density record with reflective greenness data

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On the relationship between the composition, morphology and function of leaves

Cited by 79 publications

References 19 publications

The relationship between leaf composition and morphology at elevated CO2 concentrations

The relationship between leaf composition and morphology at elevated CO2 concentrations

Leaf Shrinkage with Dehydration: Coordination with Hydraulic Vulnerability and Drought Tolerance

Global changes in dryland vegetation dynamics (1988–2008) assessed by satellite remote sensing: comparing a new passive microwave vegetation density record with reflective greenness data

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The relationship between leaf composition and morphology at elevated CO₂ concentrations

The relationship between leaf composition and morphology at elevated CO₂ concentrations