Extent of genotypic variation for maize cell wall bioconversion traits across environments and among hybrid combinations

Torres, Andrés F.; Noordam-Boot, Cornelie M. M.; Dolstra, O.; Vlaswinkel, Louis; Visser, R.G.F.; Trindade, Luisa M.

doi:10.1007/s10681-015-1517-x

Cited by 3 publications

(2 citation statements)

References 23 publications

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“…Dealing with large genotype-by-environment interaction in breeding programs usually means that germplasm has to be trialed in multiple locations as selection based upon data from a single experiment might lead to wrong selection decisions. However, like for several forage crops such as silage maize (Dolstra et al, 1992; Cox et al, 1994; Argillier et al, 1997; Barrière et al, 2008; Torres et al, 2015), alfalfa (Sheaffer et al, 1998) and switchgrass (Hopkins et al, 1995), the variation attributed to the genotype-by-environment interaction effect is considerably smaller than the variation attributed to the genotype and environment main effects (Tables 4, 5). …”

Section: Resultsmentioning

confidence: 99%

Stability of Cell Wall Composition and Saccharification Efficiency in Miscanthus across Diverse Environments

et al. 2017

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To investigate the potential effects of differences between growth locations on the cell wall composition and saccharification efficiency of the bioenergy crop miscanthus, a diverse set of 15 accessions were evaluated in six locations across Europe for the first 3 years following establishment. High-throughput quantification of cellulose, hemicellulose and lignin contents, as well as cellulose and hemicellulose conversion rates was achieved by combining near-infrared reflectance spectroscopy (NIRS) and biochemical analysis. Prediction models were developed and found to predict biomass quality characteristics with high accuracy. Location significantly affected biomass quality characteristics in all three cultivation years, but location-based differences decreased toward the third year as the plants reached maturity and the effect of location-dependent differences in the rate of establishment reduced. In all locations extensive variation in accession performance was observed for quality traits. The performance of the different accessions in the second and third cultivation year was strongly correlated, while accession performance in the first cultivation year did not correlate well with performance in later years. Significant genotype-by-environment (G × E) interactions were observed for most traits, revealing differences between accessions in environmental sensitivity. Stability analysis of accession performance for calculated ethanol yields suggested that selection for good and stable performance is a viable approach. Environmental influence on biomass quality is substantial and should be taken into account in order to match genotype, location and end-use of miscanthus as a lignocellulose feedstock.

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Section: Resultsmentioning

confidence: 99%

Stability of Cell Wall Composition and Saccharification Efficiency in Miscanthus across Diverse Environments

et al. 2017

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“…The cellular morphology of plant organs is largely investigated in relation to other physical properties such as shape, size, growth, mechanical properties or chemical composition. In particular, crop species like maize (Zea mays L.) are of increasing interest for cattle feeding or for production of bioethanol and biomolecules [1][2][3][4][5][6]. Several mechanical, biochemical and/or enzymatic processes are involved to transform the raw material, mainly composed of the stem and the leaf cell walls, into energy or fuel.…”

Section: Introductionmentioning

confidence: 99%

Parametric mapping of cellular morphology in plant tissue sections by gray level granulometry

2020

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Background: The cellular morphology of plant organs is strongly related to other physical properties such as shape, size, growth, mechanical properties or chemical composition. Cell morphology often vary depending on the type of tissue, or on the distance to a specific tissue. A common challenge in quantitative plant histology is to quantify not only the cellular morphology, but also its variations within the image or the organ. Image texture analysis is a fundamental tool in many areas of image analysis, that was proven efficient for plant histology, but at the scale of the whole image. Results: This work presents a method that generates a parametric mapping of cellular morphology within images of plant tissues. It is based on gray level granulometry from mathematical morphology for extracting image texture features, and on Centroidal Voronoi Diagram for generating a partition of the image. Resulting granulometric curves can be interpreted either through multivariate data analysis or by using summary features corresponding to the local average cell size. The resulting parametric maps describe the variations of cellular morphology within the organ. Conclusions: We propose a methodology for the quantification of cellular morphology and of its variations within images of tissue sections. The results should help understanding how the cellular morphology is related to genotypic and / or environmental variations, and clarify the relationships between cellular morphology and chemical composition of cell walls.

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Quantitative trait loci mapping in hybrids between Dent and Flint maize multiparental populations reveals group-specific QTL for silage quality traits with variable pleiotropic effects on yield

et al. 2019

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Extent of genotypic variation for maize cell wall bioconversion traits across environments and among hybrid combinations

Cited by 3 publications

References 23 publications

Stability of Cell Wall Composition and Saccharification Efficiency in Miscanthus across Diverse Environments

Stability of Cell Wall Composition and Saccharification Efficiency in Miscanthus across Diverse Environments

Parametric mapping of cellular morphology in plant tissue sections by gray level granulometry

Quantitative trait loci mapping in hybrids between Dent and Flint maize multiparental populations reveals group-specific QTL for silage quality traits with variable pleiotropic effects on yield

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