| Literature DB >> 29238358 |
Elmien Heyneke1, Mutsumi Watanabe1, Alexander Erban1, Guangyou Duan1,2, Peter Buchner3, Dirk Walther1, Joachim Kopka1, Malcolm J Hawkesford3, Rainer Hoefgen1.
Abstract
Progress in improving crop growth is an absolute goal despite the influence multifactorial components have on crop yield and quality. An Avalon × Cadenza doubled-haploidEntities:
Keywords: development; nitrogen supply; post-anthesis; wheat leaf metabolism; yield
Year: 2017 PMID: 29238358 PMCID: PMC5712589 DOI: 10.3389/fpls.2017.02048
Source DB: PubMed Journal: Front Plant Sci ISSN: 1664-462X Impact factor: 5.753
Figure 1Grain yield (A) and straw yield (B) determined with the final harvest at the end of the season. Nitrogen concentration (%); LSD = 0.263 measured in the grain (C) and straw (D). Doubled haploid lines: line 100 (high NUtE) and line 116 (low NUtE), line 181 (early senescence) and line 112 (late senescence). The values are means (±SE) of three biological replicates. Means followed by different letters among treatments were significantly different according to ANOVA (P > 0.05) in Supplemental Table S1.
Figure 2Leaf Chlorophyll content expressed as relative SPAD values measured in the NUtE inbred lines (A) and the senescence inbred lines (B). Changes in total chlorophyll (μg/mg DW) content in the second leaf following anthesis. Data represent mean values of three biological replicates for each time point measured in the NUtE inbred lines (C) and the senescence inbred lines (D). Doubled haploid lines: line 100 (high NUtE) and line 116 (low NUtE), line 181 (early senescence) and line 112 (late senescence). The values are means (±SE) of three biological replicates. Means followed by different letters among treatments were significantly different according to ANOVA (P > 0.05) in Supplemental Table S1.
Figure 3Principal component analysis (PCA) of metabolite data. (A) PCA score plot of primary metabolite profiles differentiating the high and low NUtE lines. Circles indicate averages of biological replicates of wheat leaf material harvested at 0, 1, 2, 3, 4, and 5 weeks past anthesis, respectively. Open symbols represents line 100 (high NUtE) and solid symbols represents line 116 (low NUtE). The insert depicts the Euclidian distances between the PCA loadings of line 100 and line 116 at consecutive time points. (B) PCA loadings plot of all measured primary metabolite profiles for DH lines line 100 (high NUtE) and line 116 (low NUtE). The algorithm was applied to 108 annotated primary metabolites detected in leaf material. PC, principal component; NUtE, nutrient utilisation efficiency.
Figure 4Principal component analysis (PCA) of metabolite data. (A) PCA score plot of primary metabolite profiles differentiating timing of senescence. Circles indicate averages of biological replicates of wheat leaf material harvested at 0, 1, 2, 3, 4, and 5 weeks past anthesis, respectively. Open symbols represents line 112 (late senescence) and solid symbols represents line 181 (early senescence). The Insert depicts the Euclidian distance between the PCA loadings of line 112 and line 181 at consecutive time points. (B) PCA loadings plot of all measured primary metabolite profiles for DH lines line 112 and line 181. The algorithm was applied to 108 annotated primary metabolites detected in leaf material. PC, principal component.
Figure 5Boxplot of the FDR-corrected p-values obtained from a three-way ANOVA analysis performed for every metabolite available for analysis. For every metabolite, levels were scaled by dividing by its average value across all conditions with subsequent log-transformation to render data normally distributed.
Figure 6Principal component analysis (PCA). PCA score plot (A) and PCA loadings plot (B) of all measured primary metabolite profiles. The algorithm was applied to 108 annotated primary metabolites detected in leaf material. PC, Principal component; weeks post-anthesis are numbered: 0, 1, 2, 3, 4, and 5.
Figure 7Differentially abundant metabolites in wheat leaves. Hierarchical cluster analysis separated metabolites into different classes subject to their response pattern. Absolute values as recorded were averaged and normalized to the average of each metabolite. Log2-fold values are presented by the false color code. Hierarchical clustering analysis separated metabolites into seven distinct clusters: metabolites displaying a strong N dependency, but showing a biphasic response over the developmental period (A); metabolites decreasing with increasing N level, but then showing increased levels over the developmental period (B); those increasing over both increasing N level and developmental period (C); metabolites showing a biphasic pattern over both increasing N level and developmental period (D); those decreasing with increasing N level and developmental period (E); metabolites decreasing over increasing N level, and having a biphasic response over developmental period (F); and those increasing over increasing N level, while decreasing over developmental period (G).
Figure 8Clustered heatmap depicting correlations between each of the measured metabolites and the core physiological parameters; Total ChI, Nitrate, grain, and straw yield and %N. in the grain and the straw. The metabolites are placed in remote clusters using Pearson Correlation. The assigned color indicates the strength of a particular correlation between two parameters, blue for negative correlations, and red for positive correlations as depicted in the colour key (−1 < 0 < 1). The values were generated in R (http://rstudio.com/) and the heat map was constructed using the MultiExperimentalViewer software (http://www.tm4.org/). Hierarchical cluster analysis separated metabolites into different classes subject to their correlation to the core parameters: Cluster I depicts negative correlations to the core parameters, cluster II show a neutral or inconsistent correlations, and cluster III depicts positive correlations to the core parameters.
Figure 9Pathway map of the primary metabolism in wheat. The inserted graphs depict absolute values for amino acids (HPLC) and ions (IC) expressed as). l mol gDW−1. All other primary metabolites were determined by GC-MS analysis and are expressed as relative peak height gDW−1. The coloured frames correspond to clusters depicted in Figure 4.