Modeling branching in cereals

Evers, Jochem B.; Vos, J.

doi:10.3389/fpls.2013.00399

Cited by 23 publications

(21 citation statements)

References 49 publications

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“…However, it is still unclear to what extent such reduced levels of tillering plasticity in tin genotypes are mediated by light quality and especially R:FR signal transduction through the different phytochromes present in higher plants (Franklin and Whitelam, 2005 ). It will be interesting to further evaluate the tillering plasticity of tin genotypes in light and R:FR environments generated by the growing of plants on regular grids of different plant densities (Evers et al, 2006 ) or by manipulating light levels and/or R:FR artificially (Mandoli and Briggs, 1981 ; Casal et al, 1990 ) to explore the idea of a defined, genotype-specific R:FR threshold at which tillering ceases to be implemented in models of crop growth and development (Evers and Vos, 2013 ).…”

Section: Discussionmentioning

confidence: 99%

“…Thus, k is mainly useful to show that there are differences in optical properties but to dissect and further understand any sources of variation in k in NILs contrasting for tin requires a more integrated approach that explicitly takes into account the spatial distribution of plant organs. The most feasible approach for achieving this is arguably spatially-explicit modeling of plant architecture, growth, development and physiological functioning called functional-structural plant (FSP) modeling (Vos et al, 2010 ; Evers and Vos, 2013 ). Based on existing FSP models of wheat (Evers et al, 2005 ), contrasting seasonal time-courses of tiller production and mortality as well as leaf area expansion and arrangement could be simulated to explore (i) the relationship with cumulative radiation interception, which is important for potentially achieving high productivity (Monteith, 1977 ), and (ii) the possible consequences for the timing of transpirational water-use relative to anthesis and seed-filling, which is important for crop adaptation to water-limited environments (Passioura and Angus, 2010 ; Rebetzke et al, 2013 ).…”

Section: Discussionmentioning

confidence: 99%

“…The relationships were assessed in terms of leaf and tiller appearance, sizes of fully grown organs, and light quality and quantity. This study is a first step in the development of an architectural model (Vos et al, 2010 ; Evers and Vos, 2013 ) of tin phenotypes—a tool that could assist in the identification of desirable plant architectural traits for use in trait-based selection (Long et al, 2006 ; Richards et al, 2010 ; Rebetzke et al, 2013 ).…”

Section: Introductionmentioning

confidence: 99%

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Canopy architectural and physiological characterization of near-isogenic wheat lines differing in the tiller inhibition gene tin

2014

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Tillering is a core constituent of plant architecture, and influences light interception to affect plant and crop performance. Near-isogenic lines (NILs) varying for a tiller inhibition (tin) gene and representing two genetic backgrounds were investigated for tillering dynamics, organ size distribution, leaf area, light interception, red: far-red ratio, and chlorophyll content. Tillering ceased earlier in the tin lines to reduce the frequencies of later primary and secondary tillers compared to the free-tillering NILs, and demonstrated the genetically lower tillering plasticity of tin-containing lines. The distribution of organ sizes along shoots varied between NILs contrasting for tin. Internode elongation commenced at a lower phytomer, and the peduncle was shorter in the tin lines. The flag leaves of tin lines were larger, and the longest leaf blades were observed at higher phytomers in the tin than in free-tillering lines. Total leaf area was reduced in tin lines, and non-tin lines invested more leaf area at mid-canopy height. The tiller economy (ratio of seed-bearing shoots to numbers of shoots produced) was 10% greater in the tin lines (0.73–0.76) compared to the free-tillering sisters (0.62–0.63). At maximum tiller number, the red: far-red ratio (light quality stimulus that is thought to induce the cessation of tillering) at the plant-base was 0.18–0.22 in tin lines and 0.09–0.11 in free-tillering lines at levels of photosynthetic active radiation of 49–53% and 30–33%, respectively. The tin lines intercepted less radiation compared to their free-tillering sisters once genotypic differences in tiller numbers had established, and maintained green leaf area in the lower canopy later into the season. Greater light extinction coefficients (k) in tin lines prior to, but reduced k after, spike emergence indicated that differences in light interception between NILs contrasting in tin cannot be explained by leaf area alone but that geometric and optical canopy properties contributed. The careful characterization of specifically-developed NILs is refining the development of a physiology-based model for tillering to improve understanding of the value of architectural traits for use in cereal improvement.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Canopy architectural and physiological characterization of near-isogenic wheat lines differing in the tiller inhibition gene tin

2014

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“…To assess how plant growth and environment affect the levels of the various players near each bud of a given plant, one approach can be to develop a functional–structural plant model. This modeling approach consists in representing plant physiological functioning in a realistic plant botanical structure ( Prusinkiewicz and Lindenmayer, 1990 ; Evers et al, 2011 ; Evers and Vos, 2013 ). Each organ is individually represented and positioned in the plant, so that the hormonal, nutrient, or physical environments (e.g., light) can be estimated locally for each organ.…”

Section: Modeling Could Bring In a Better Understanding Of Shoot Branmentioning

confidence: 99%

Multiple pathways regulate shoot branching

et al. 2015

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Shoot branching patterns result from the spatio-temporal regulation of axillary bud outgrowth. Numerous endogenous, developmental and environmental factors are integrated at the bud and plant levels to determine numbers of growing shoots. Multiple pathways that converge to common integrators are most probably involved. We propose several pathways involving not only the classical hormones auxin, cytokinins and strigolactones, but also other signals with a strong influence on shoot branching such as gibberellins, sugars or molecular actors of plant phase transition. We also deal with recent findings about the molecular mechanisms and the pathway involved in the response to shade as an example of an environmental signal controlling branching. We propose the TEOSINTE BRANCHED1, CYCLOIDEA, PCF transcription factor TB1/BRC1 and the polar auxin transport stream in the stem as possible integrators of these pathways. We finally discuss how modeling can help to represent this highly dynamic system by articulating knowledges and hypothesis and calculating the phenotype properties they imply.

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“…FSP models can capture the complex dynamic feedback between the changing plant phenotype and the surrounding light environment by simulating plant phenotypic development and biomass growth over time in three dimensions at the organ level (Vos et al, 2010;Evers, 2016). In this model, the ability of plants to exhibit plastic responses is regarded by using response curves; dose-response relationships or step-wise relationships that relate organ trait change to a range of R:FR conditions (Gautier et al, 2000;Evers et al, 2007;Evers & Vos, 2013). By simulating the R:FR distribution as a function of the dynamic 3D plant phenotypes that are created by the interaction of resource acquisition and growth at the organ level, the plastic responses at the organ level are quantitatively linked to whole-plant performance during competition (Chapter 2; Bongers et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

How virtual shade sheds light on plant plasticity

Bongers¹

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Phenotypic plasticity is the ability of a genotype to express multiple phenotypes in accordance with different environments. Although variation in plasticity has been observed, there is limited knowledge on how this variation results from natural selection. This thesis analyses how variation in the level of plasticity influences light competition between plants and how this variation could result from selection, driven by light competition, in various environments. As an exemplary case of phenotypic plasticity, this thesis focusses on phenotypic responses of the annual rosette plant Arabidopsis thaliana (Brassicaceae) in response to the proximity of neighbour plants, as signalled through the red : far-red (R:FR) ratio, which are responses associated with the shade avoidance syndrome (SAS). Plant experiments were conducted to measure variation in these plastic responses and a functional-structural plant (FSP) model was created that simulates plant structures in 3D and includes these organ-level plastic responses while simulating explicitly a heterogeneous light environment. Simulating individual plants that explicitly compete for light, while their phenotype changes through plasticity, gave insights in the role of the level of phenotypic plasticity and site of signal perception on plant competitiveness. In addition, an analysis on how natural selection in different environments acts on the level of plasticity was performed by combining FSP simulations and evolutionary game theoretical (EGT) principles.

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Modeling branching in cereals

Cited by 23 publications

References 49 publications

Canopy architectural and physiological characterization of near-isogenic wheat lines differing in the tiller inhibition gene tin

Canopy architectural and physiological characterization of near-isogenic wheat lines differing in the tiller inhibition gene tin

Multiple pathways regulate shoot branching

How virtual shade sheds light on plant plasticity

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