Your search keyword '"Fleming, Andrew"' showing total 9 results

1. Altering arabinans increases Arabidopsis guard cell flexibility and stomatal opening.

Author

Carroll, Sarah, Amsbury, Sam, Durney, Clinton H., Smith, Richard S., Morris, Richard J., Gray, Julie E., and Fleming, Andrew J.

Subjects

*STOMATA, *ARABIDOPSIS

Published

2024

2. Stomatal Function Requires Pectin De-methyl-esterification of the Guard Cell Wall.

Author

Amsbury, Sam, Hunt, Lee, Elhaddad, Nagat, Baillie, Alice, Lundgren, Marjorie, Verhertbruggen, Yves, Scheller, Henrik V., Knox, J. Paul, Fleming, Andrew J., and Gray, Julie E.

Subjects

*PECTINS, *STOMATA, *GUARD cells (Plant anatomy), *ESTERIFICATION, *METHYL groups, *CELLULAR mechanics

Abstract

Summary Stomatal opening and closure depends on changes in turgor pressure acting within guard cells to alter cell shape [ 1 ]. The extent of these shape changes is limited by the mechanical properties of the cells, which will be largely dependent on the structure of the cell walls. Although it has long been observed that guard cells are anisotropic due to differential thickening and the orientation of cellulose microfibrils [ 2 ], our understanding of the composition of the cell wall that allows them to undergo repeated swelling and deflation remains surprisingly poor. Here, we show that the walls of guard cells are rich in un-esterified pectins. We identify a pectin methylesterase gene, PME6 , which is highly expressed in guard cells and required for stomatal function. pme6-1 mutant guard cells have walls enriched in methyl-esterified pectin and show a decreased dynamic range in response to triggers of stomatal opening/closure, including elevated osmoticum, suggesting that abrogation of stomatal function reflects a mechanical change in the guard cell wall. Altered stomatal function leads to increased conductance and evaporative cooling, as well as decreased plant growth. The growth defect of the pme6-1 mutant is rescued by maintaining the plants in elevated CO 2 , substantiating gas exchange analyses, indicating that the mutant stomata can bestow an improved assimilation rate. Restoration of PME6 rescues guard cell wall pectin methyl-esterification status, stomatal function, and plant growth. Our results establish a link between gene expression in guard cells and their cell wall properties, with a corresponding effect on stomatal function and plant physiology. [ABSTRACT FROM AUTHOR]

Published

2016

3. An ancestral stomatal patterning module revealed in the non-vascular land plant Physcomitrella patens.

Author

Caine, Robert S., Chater, Caspar C., Kamisugi, Yasuko, Cuming, Andrew C., Beerling, David J., Gray, Julie E., and Fleming, Andrew J.

Subjects

*STOMATA, *PLANT development, *PLANT evolution, *ARABIDOPSIS, *PHYSCOMITRELLA patens, *NONVASCULAR plants

Abstract

The patterning of stomata plays a vital role in plant development and has emerged as a paradigm for the role of peptide signals in the spatial control of cellular differentiation. Research in Arabidopsis has identified a series of epidermal patterning factors (EPFs), which interact with an array of membrane-localised receptors and associated proteins (encoded by ERECTA and TMM genes) to control stomatal density and distribution. However, although it is well-established that stomata arose very early in the evolution of land plants, until now it has been unclear whether the established angiosperm stomatal patterning system represented by the EPF/ TMM/ERECTA module reflects a conserved, universal mechanism in the plant kingdom. Here, we use molecular genetics to show that the moss Physcomitrella patens has conserved homologues of angiosperm EPF, TMM and at least one ERECTA gene that function together to permit the correct patterning of stomata and that, moreover, elements of the module retain function when transferred to Arabidopsis. Our data characterise the stomatal patterning system in an evolutionarily distinct branch of plants and support the hypothesis that the EPF/TMM/ERECTA module represents an ancient patterning system. [ABSTRACT FROM AUTHOR]

Published

2016

4. Auxin influx importers modulate serration along the leaf margin.

Author

Kasprzewska, Ania, Carter, Ross, Swarup, Ranjan, Bennett, Malcolm, Monk, Nick, Hobbs, Jamie K., and Fleming, Andrew

Subjects

*LEAF anatomy, *AUXIN, *PLANT embryology, *ARABIDOPSIS, *PLANT growth, *GENETIC transcription in plants

Abstract

Leaf shape in Arabidopsis is modulated by patterning events in the margin that utilize a PIN-based auxin exporter/CUC2 transcription factor system to define regions of promotion and retardation of growth, leading to morphogenesis. In addition to auxin exporters, leaves also express auxin importers, notably members of the AUX1/ LAX family. In contrast to their established roles in embryogenesis, lateral root and leaf initiation, the function of these transporters in leaf development is poorly understood. We report that three of these genes ( AUX1, LAX1 and LAX2) show specific and dynamic patterns of expression during early leaf development in Arabidopsis, and that loss of expression of all three genes is required for observation of a phenotype in which morphogenesis (serration) is decreased. We used these expression patterns and mutant phenotypes to develop a margin-patterning model that incorporates an AUX1/ LAX1/ LAX2 auxin import module that influences the extent of leaf serration. Testing of this model by margin-localized expression of axr3-1 ( AXR17) provides further insight into the role of auxin in leaf morphogenesis. [ABSTRACT FROM AUTHOR]

Published

2015

5. Altering arabinans increases Arabidopsis guard cell flexibility and stomatal opening.

Author

Carroll, Sarah, Amsbury, Sam, Durney, Clinton H., Smith, Richard S., Morris, Richard J., Gray, Julie E., and Fleming, Andrew J.

Subjects

*STOMATA, *CELLULAR mechanics, *ATOMIC force microscopy, *ARABIDOPSIS, *GAS exchange in plants, *PLANT-water relationships

Abstract

Stomata regulate plant water use and photosynthesis by controlling leaf gas exchange. They do this by reversibly opening the pore formed by two adjacent guard cells, with the limits of this movement ultimately set by the mechanical properties of the guard cell walls and surrounding epidermis. 1,2 A body of evidence demonstrates that the methylation status and cellular patterning of pectin wall polymers play a core role in setting the guard cell mechanical properties, with disruption of the system leading to poorer stomatal performance. 3–6 Here we present genetic and biochemical data showing that wall arabinans modulate guard cell flexibility and can be used to engineer stomata with improved performance. Specifically, we show that a short-chain linear arabinan epitope associated with the presence of rhamnogalacturonan I in the guard cell wall is required for full opening of the stomatal pore. Manipulations leading to the novel accumulation of longer-chain arabinan epitopes in guard cell walls led to an increase in the maximal pore aperture. Using computational modeling combined with atomic force microscopy, we show that this phenotype reflected a decrease in wall matrix stiffness and, consequently, increased flexing of the guard cells under turgor pressure, generating larger, rounder stomatal pores. Our results provide theoretical and experimental support for the conclusion that arabinan side chains of pectin modulate guard cell wall stiffness, setting the limits for cell flexing and, consequently, pore aperture, gas exchange, and photosynthetic assimilation. [Display omitted] • Cell walls in stomata have a distinct composition of arabinans • Increasing the level of a specific arabinan makes the walls more flexible • Stomata with more flexible walls can open wider • Under high CO 2 , more flexible, wider stomata increase carbon assimilation rate The degree of stomatal opening is set by the mechanical properties of the guard cell walls. Carroll et al. show that wall flexibility is set by the arabinan composition, and that by manipulating arabinan polymers it is possible to engineer stomata with increased opening under elevated CO 2 , leading to increased carbon assimilation. [ABSTRACT FROM AUTHOR]

Published

2022

6. Variable expansin expression in Arabidopsis leads to different growth responses.

Author

Goh, Hoe-Han, Sloan, Jennifer, Malinowski, Robert, and Fleming, Andrew

Subjects

*GENE expression in plants, *PLANT growth, *EXPANSINS, *PLANT cell walls, *GENETIC repressors, *ARABIDOPSIS

Abstract

Abstract: Expansins have long been implicated in the control of cell wall extensibility. However, despite ample evidence supporting a role for these proteins in the endogenous mechanism of plant growth, there are also examples in the literature where the outcome of altered expansin gene expression is difficult to reconcile with a simplistic causal linkage to growth promotion. To investigate this problem, we report on the analysis of transgenic Arabidopsis plants in which a heterologous cucumber expansin can be inducibly overexpressed. Our results indicate that the effects of expansin expression on growth depend on the degree of induction of expansin expression and the developmental pattern of organ growth. They support the role of expansin in directional cell expansion. They are also consistent with the idea that excess expansin might itself impede normal activities of cell wall modifications, culminating in both growth promotion and repression depending on the degree of expression. [Copyright &y& Elsevier]

Published

2014

7. leafprocessor: a new leaf phenotyping tool using contour bending energy and shape cluster analysis.

Author

Backhaus, Andreas, Kuwabara, Asuka, Bauch, Marion, Monk, Nick, Sanguinetti, Guido, and Fleming, Andrew

Subjects

*FOLIAR diagnosis, *LEAF anatomy, *PLANT anatomy, *PLANT chemical analysis, *PLANT nutrition, *PLANT growth, *CLUSTER analysis (Statistics), *MULTIVARIATE analysis, *SPATIAL analysis (Statistics)

Abstract

•Significant progress has been made in the identification of the genetic factors controlling leaf shape. However, no integrated solution for the quantification and categorization of leaf form has been developed. In particular, the analysis of local changes in margin growth, which define many of the differences in shape, remains problematical. •Here, we report on a software package (leafprocessor) which provides a semi-automatic and landmark-free method for the analysis of a range of leaf-shape parameters, combining both single metrics and principal component analysis. In particular, we explore the use of bending energy as a tool for the analysis of global and local leaf perimeter deformation. •As a test case for the implementation of theleafprocessor program, we show that this integrated analysis leads to deeper insights into the morphogenic changes underpinning a series of previously identified Arabidopsis leaf-shape mutants. Our analysis reveals that many of these mutants which, at first sight, show similar leaf morphology, can be distinguished via our shape analysis. •Theleafprocessor program provides a novel integrated tool for the analysis of leaf shape. [ABSTRACT FROM AUTHOR]

Published

2010

8. Investigating the microstructure of plant leaves in 3D with lab-based X-ray computed tomography.

Author

Mathers, Andrew W., Hepworth, Christopher, Baillie, Alice L., Sloan, Jen, Jones, Hannah, Lundgren, Marjorie, Fleming, Andrew J., Mooney, Sacha J., and Sturrock, Craig J.

Subjects

*LEAF anatomy, *COMPUTED tomography, *GAS exchange in plants, *PHOTOSYNTHESIS, *ARABIDOPSIS

Abstract

Background: Leaf cellular architecture plays an important role in setting limits for carbon assimilation and, thus, photosynthetic performance. However, the low density, fine structure, and sensitivity to desiccation of plant tissue has presented challenges to its quantification. Classical methods of tissue fixation and embedding prior to 2D microscopy of sections is both laborious and susceptible to artefacts that can skew the values obtained. Here we report an image analysis pipeline that provides quantitative descriptors of plant leaf intercellular airspace using lab-based X-ray computed tomography (microCT). We demonstrate successful visualisation and quantification of differences in leaf intercellular airspace in 3D for a range of species (including both dicots and monocots) and provide a comparison with a standard 2D analysis of leaf sections. Results: We used the microCT image pipeline to obtain estimates of leaf porosity and mesophyll exposed surface area (Smes) for three dicot species (Arabidopsis, tomato and pea) and three monocot grasses (barley, oat and rice). The imaging pipeline consisted of (1) a masking operation to remove the background airspace surrounding the leaf, (2) segmentation by an automated threshold in ImageJ and then (3) quantification of the extracted pores using the ImageJ 'Analyze Particles' tool. Arabidopsis had the highest porosity and lowest Smes for the dicot species whereas barley had the highest porosity and the highest Smes for the grass species. Comparison of porosity and Smes estimates from 3D microCT analysis and 2D analysis of sections indicates that both methods provide a comparable estimate of porosity but the 2D method may underestimate Smes by almost 50%. A deeper study of porosity revealed similarities and differences in the asymmetric distribution of airspace between the species analysed. Conclusions: Our results demonstrate the utility of high resolution imaging of leaf intercellular airspace networks by lab-based microCT and provide quantitative data on descriptors of leaf cellular architecture. They indicate there is a range of porosity and Smes values in different species and that there is not a simple relationship between these parameters, suggesting the importance of cell size, shape and packing in the determination of cellular parameters proposed to influence leaf photosynthetic performance. [ABSTRACT FROM AUTHOR]

Published

2018

9. Stomatal Opening Involves Polar, Not Radial, Stiffening Of Guard Cells.

Author

Carter, Ross, Woolfenden, Hugh, Baillie, Alice, Amsbury, Sam, Carroll, Sarah, Healicon, Eleanor, Sovatzoglou, Spyros, Braybrook, Sioban, Gray, Julie E., Hobbs, Jamie, Morris, Richard J., and Fleming, Andrew J.

Subjects

*GUARD cells (Plant anatomy), *STOMATA, *PLANT mechanics, *ARABIDOPSIS thaliana, *ATOMIC force microscopy

Abstract

Summary It has long been accepted that differential radial thickening of guard cells plays an important role in the turgor-driven shape changes required for stomatal pore opening to occur [ 1–4 ]. This textbook description derives from an original interpretation of structure rather than measurement of mechanical properties. Here we show, using atomic force microscopy, that although mature guard cells display a radial gradient of stiffness, this is not present in immature guard cells, yet young stomata show a normal opening response. Finite element modeling supports the experimental observation that radial stiffening plays a very limited role in stomatal opening. In addition, our analysis reveals an unexpected stiffening of the polar regions of the stomata complexes, both in Arabidopsis and other plants, suggesting a widespread occurrence. Combined experimental data (analysis of guard cell wall epitopes and treatment of tissue with cell wall digesting enzymes, coupled with bioassay of guard cell function) plus modeling lead us to propose that polar stiffening reflects a mechanical, pectin-based pinning down of the guard cell ends, which restricts increase of stomatal complex length during opening. This is predicted to lead to an improved response sensitivity of stomatal aperture movement with respect to change of turgor pressure. Our results provide new insight into the mechanics of stomatal function, both negating an established view of the importance of radial thickening and providing evidence for a significant role for polar stiffening. Improved stomatal performance via altered cell-wall-mediated mechanics is likely to be of evolutionary and agronomic significance. [ABSTRACT FROM AUTHOR]

Published

2017