10 Works
Additional file 3 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 3: Table S3. Descriptive statistics for the phenotypic traits measured in the QTL and FWK Pinus radiata populations in this study.
Additional file 17 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 17: Table S5. Matrix of Pearson’s phenotypic correlation coefficients between growth and wood property traits analysed in the Pinus radiata QTL population. Two tailed P-values *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.
Additional file 2 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 2: Table S2. SNP ranking criteria used for the Pinus radiata QTL and FWK mapping populations.
Additional file 4 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 4: Fig. S1. Frequency distributions for the phenotypic traits measured in the QTL and FWK Pinus radiata populations in this study. QTL population: (A) Ring area (mm2); (B) Density (kg/m3) Silviscan; (C) Radial cell diameter (μm); (D) Tangential cell diameter (μm); (E) Fibre coarseness (μm/m); (F) Cell wall thickness (μm); (G) Specific surface area (m2/kg); (H) Microfibril angle (degrees); (I) Modulus of elasticity (GPa); (J) Density prediction for first 5 mm core (maximum...
Additional file 17 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 17: Table S5. Matrix of Pearson’s phenotypic correlation coefficients between growth and wood property traits analysed in the Pinus radiata QTL population. Two tailed P-values *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.
Additional file 1 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 1: Table S1. SNP filtering summary for the Pinus radiata QTL and FWK mapping populations.
Additional file 3 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 3: Table S3. Descriptive statistics for the phenotypic traits measured in the QTL and FWK Pinus radiata populations in this study.
Additional file 1 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 1: Table S1. SNP filtering summary for the Pinus radiata QTL and FWK mapping populations.
Additional file 4 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 4: Fig. S1. Frequency distributions for the phenotypic traits measured in the QTL and FWK Pinus radiata populations in this study. QTL population: (A) Ring area (mm2); (B) Density (kg/m3) Silviscan; (C) Radial cell diameter (μm); (D) Tangential cell diameter (μm); (E) Fibre coarseness (μm/m); (F) Cell wall thickness (μm); (G) Specific surface area (m2/kg); (H) Microfibril angle (degrees); (I) Modulus of elasticity (GPa); (J) Density prediction for first 5 mm core (maximum...
Additional file 2 of High density linkage maps, genetic architecture, and genomic prediction of growth and wood properties in Pinus radiata
Jules S. Freeman, Gancho T. Slavov, Jakob B. Butler, Tancred Frickey, Natalie J. Graham, Jaroslav Klápště, John Lee, Emily J. Telfer, Phillip Wilcox & Heidi S. Dungey
Additional file 2: Table S2. SNP ranking criteria used for the Pinus radiata QTL and FWK mapping populations.