| A722-7 x Golden Delicious |
2 | 2 | integrated |
8 | 11.80 |
A722-7 x Golden Delicious | Gygax et al. Theor Appl Genet (2004) 109: 1702-1709 | |
| Apple Integrated Map |
12 | 12 | integrated |
123 | 74.20 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
11 | 11 | integrated |
105 | 77.70 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
6 | 6 | integrated |
68 | 76.00 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
7 | 7 | integrated |
71 | 59.20 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
8 | 8 | integrated |
98 | 73.50 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
5 | 5 | integrated |
106 | 92.00 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
10 | 10 | integrated |
89 | 94.60 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
2 | 2 | integrated |
140 | 85.40 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
13 | 13 | integrated |
103 | 77.50 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
17 | 17 | integrated |
90 | 75.30 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
9 | 9 | integrated |
118 | 73.30 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
15 | 15 | integrated |
173 | 99.99 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
16 | 16 | integrated |
78 | 58.30 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
14 | 14 | integrated |
88 | 77.10 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
1 | 1 | integrated |
95 | 89.60 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
4 | 4 | integrated |
91 | 65.60 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Apple Integrated Map |
3 | 3 | integrated |
114 | 89.10 |
Apple Integrated Map | Velasco et al. (2010) Nature Genetics 42: 822-839 | The genetic maps that were used to develop the integrated map for metacontig anchoring were derived from six F1 populations totaling 720 individuals: 270 plants from the cross between 'Golden Delicious' and 'Scarlet', grown at FEM-IASMA (San Michele, TN, Italy), 88 plants from 'Golden Delicious' x 'Braeburn', IASMA; 91 plants from 'Golden Delicious' x 'McIntosh-Wijick', IASMA; 89 plants from 'Disc |
| Discovery x TN10-8 |
10 | 10 | integrated |
23 | 87.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
12 | 12 | integrated |
9 | 70.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
16 | 16 | integrated |
14 | 89.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
2 | 2 | integrated |
28 | 94.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
8 | 8 | integrated |
17 | 63.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
1 | 1 | integrated |
9 | 57.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
11 | 11 | integrated |
9 | 61.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
15 | 15 | integrated |
11 | 62.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
17 | 17 | integrated |
18 | 75.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Discovery x TN10-8 |
5 | 5 | integrated |
14 | 98.00 |
Discovery x TN10-8 | Calenge et al (2005) Theor Appl Genet 110:4 660-668 | |
| Fiesta x A871-14 |
12 | 12 | integrated |
8 | 48.00 |
Fiesta x A871-14 | | |
| Fiesta x Discovery |
13 | 13 | integrated |
22 | 85.00 |
Fiesta x Discovery | Calenge et al (2005) Theor Appl Genet 111:1 128-135 | |
| Fiesta x Discovery |
7 | 7 | integrated |
18 | 59.00 |
Fiesta x Discovery | Calenge et al (2005) Theor Appl Genet 111:1 128-135 | |
| Fiesta x Discovery |
12 | 12 | integrated |
19 | 73.00 |
Fiesta x Discovery | Calenge et al (2005) Theor Appl Genet 111:1 128-135 | |
| Fiesta x Discovery |
3 | 3 | integrated |
14 | 59.00 |
Fiesta x Discovery | Calenge et al (2005) Theor Appl Genet 111:1 128-135 | |
| Fiesta x Totem |
1 | 1 | integrated |
11 | 69.50 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
3 | 3 | integrated |
13 | 85.65 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
5 | 5 | integrated |
13 | 75.03 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
7 | 7 | integrated |
8 | 71.61 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
9 | 9 | integrated |
16 | 77.35 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
11 | 11 | integrated |
24 | 87.45 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
13 | 13 | integrated |
14 | 78.20 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
15 | 15 | integrated |
24 | 99.34 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
17 | 17 | integrated |
21 | 68.26 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
2 | 2 | integrated |
11 | 73.49 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
4 | 4 | integrated |
11 | 31.23 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
6 | 6 | integrated |
9 | 42.41 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
8 | 8 | integrated |
12 | 64.30 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
10 | 10 | integrated |
24 | 94.02 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
12 | 12 | integrated |
17 | 59.65 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
14 | 14 | integrated |
18 | 46.53 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| Fiesta x Totem |
16 | 16 | integrated |
17 | 86.72 |
Fiesta x Totem | Fernandez-Fernandez F. et al (2008). Tree Genetics & Genomes | |
| M.27 x M.116 |
2 | 2 | integrated |
15 | 87.65 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
4 | 4 | integrated |
12 | 75.51 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
6 | 6 | integrated |
12 | 72.98 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
8 | 8 | integrated |
12 | 54.00 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
10 | 10 | integrated |
26 | 89.51 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
12 | 12 | integrated |
18 | 62.57 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
14 | 14 | integrated |
13 | 30.31 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
16 | 16 | integrated |
21 | 83.51 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
1 | 1 | integrated |
14 | 68.10 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
3 | 3 | integrated |
16 | 64.84 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
5 | 5 | integrated |
26 | 68.48 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
7 | 7 | integrated |
16 | 75.67 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
9 | 9 | integrated |
25 | 63.00 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
11 | 11 | integrated |
28 | 94.34 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
13 | 13 | integrated |
16 | 56.89 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
15 | 15 | integrated |
27 | 99.99 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| M.27 x M.116 |
17 | 17 | integrated |
27 | 69.86 |
M432 mapping population | Fernández-Fernández F. et al (2012) Tree Genetics & Genomes 8(5) 991-1002 | A genetic linkage map of the M432 mapping progeny derived from the cross ‘M.27’?×?‘M.116’. The map contains a total of 324 molecular loci, 323 SSR markers, and the S locus. The map spans 17 linkage groups (LG1–LG17) and covers a total genetic distance of 1,229.5 cM. |
| Prima x Fiesta |
3 | 3 | integrated |
18 | 64.00 |
Prima x Fiesta | Calenge et al (2005) Theor Appl Genet 111:1 128-135 | |
| Prima x Fiesta |
7 | 7 | integrated |
16 | 52.00 |
Prima x Fiesta | Calenge et al (2005) Theor Appl Genet 111:1 128-135 | |
| Regia x Piflora |
2 | 2 | integrated |
18 | 41.00 |
02/206 | Boudichevskaia et al. (2006) Tree Genetics & Genomes 2(4): 186-195 | 80 individuals |
| Regia x Pingo |
2 | 2 | integrated |
9 | 32.00 |
02/223 | Boudichevskaia et al. (2006) Tree Genetics & Genomes 2(4): 186-195 | 80 individuals |
| Spur-Fuji x Telamon |
10 | 10 | integrated |
13 | 54.60 |
Spur-Fuji x Telamon | Tian et al. (2005) Euphytica 145: 181-188 | 106 individuals |
| 91.136 B6-77 |
9 | 9 | single parent |
7 | 45.00 |
A194 (Sciros x 91.136 B6-77) | Chagné et al. BMC Genomics (2007) 8:212 | |
| Aotea |
8 | 8 | single parent |
6 | 24.10 |
M.9 x Aotea 1 | Bus et al. (2008) Tree Genetics & Genomes 4:233-236 | |
| Braeburn |
14 | 0 | single parent |
17 | 71.20 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
16 | 4 | single parent |
17 | 79.00 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
2 | 17 | single parent |
19 | 88.30 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
4 | 7 | single parent |
8 | 96.60 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
6 | 2 | single parent |
23 | 78.90 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
8 | 13 | single parent |
14 | 74.20 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
10 | 12 | single parent |
15 | 70.60 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
12 | 1 | single parent |
3 | 4.90 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
15 | 10 | single parent |
26 | 92.30 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
17 | 0 | single parent |
10 | 75.30 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
3 | 0 | single parent |
14 | 72.40 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
5 | 15 | single parent |
12 | 91.90 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
7 | 6 | single parent |
14 | 66.10 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
9 | 0 | single parent |
29 | 99.99 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
1 | 14 | single parent |
11 | 54.00 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
11 | 8 | single parent |
12 | 40.90 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Braeburn |
13 | 11 | single parent |
20 | 88.00 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Discovery |
10 | 10 | single parent |
6 | 35.10 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
2 | 2 | single parent |
12 | 51.60 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
4 | 4 | single parent |
5 | 23.60 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
7 | 7 | single parent |
8 | 36.70 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
2 | 2 | single parent |
24 | 67.30 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
3 | 3 | single parent |
15 | 64.80 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
5 | 5 | single parent |
55 | 99.99 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
7 | 7 | single parent |
24 | 54.20 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
9 | 9 | single parent |
25 | 72.50 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
11 | 11 | single parent |
44 | 87.90 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
9 | 9 | single parent |
14 | 66.40 |
Fiesta x Discovery | Gao et al (2005) Theor. Appl. Genet. 111:1087-1097 | |
| Discovery |
13 | 13 | single parent |
41 | 90.60 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
14 | 14 | single parent |
4 | 3.00 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
16 | 16 | single parent |
46 | 82.10 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
8 | 8 | single parent |
13 | 71.80 |
Discovery x TN10-8 | Bus et al. (2008) Tree Genetics & Genomes 4:233-236 | |
| Discovery |
1 | 1 | single parent |
6 | 75.90 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
11 | 11 | single parent |
6 | 41.60 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
3 | 3 | single parent |
4 | 13.90 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
5 | 5 | single parent |
5 | 22.50 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
9 | 9 | single parent |
5 | 31.00 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Discovery |
1 | 1 | single parent |
22 | 77.40 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
3 | 3 | single parent |
7 | 43.30 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
4 | 4 | single parent |
48 | 79.20 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
6 | 6 | single parent |
19 | 82.90 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
8 | 8 | single parent |
29 | 69.70 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
10 | 10 | single parent |
28 | 97.20 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
12 | 12 | single parent |
38 | 89.30 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
14 | 14 | single parent |
21 | 34.50 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
15 | 15 | single parent |
40 | 99.99 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Discovery |
17 | 17 | single parent |
25 | 99.80 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
15 | 15 | single parent |
5 | 10.00 |
Prima x Fiesta | Costa et al. Euphytica (2005) 141: 181-190 | |
| Fiesta |
7 | 7 | single parent |
27 | 66.80 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
9 | 9 | single parent |
23 | 53.20 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
11 | 11 | single parent |
33 | 71.50 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
13 | 13 | single parent |
17 | 24.00 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
15 | 15 | single parent |
31 | 99.99 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
17 | 17 | single parent |
41 | 67.90 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
1 | 1 | single parent |
10 | 42.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
2 | 2 | single parent |
10 | 67.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
8 | 8 | single parent |
8 | 60.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
13 | 13 | single parent |
6 | 43.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
12 | 12 | single parent |
8 | 45.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
15 | 15 | single parent |
5 | 11.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
4 | 4 | single parent |
6 | 63.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
7 | 7 | single parent |
11 | 47.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
10 | 10 | single parent |
8 | 32.10 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Fiesta |
3 | 3 | single parent |
4 | 25.70 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Fiesta |
8 | 8 | single parent |
4 | 17.30 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Fiesta |
8 | 8 | single parent |
17 | 55.30 |
Prima x Fiesta | Gao et al (2005) Theor. Appl. Genet. 111:1087-1097 | |
| Fiesta |
1 | 1 | single parent |
18 | 73.60 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
3 | 3 | single parent |
24 | 65.70 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
5 | 5 | single parent |
38 | 65.30 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
16 | 16 | single parent |
10 | 62.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
17 | 17 | single parent |
10 | 76.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
10 | 10 | single parent |
27 | 82.00 |
Fiesta x Mondial Gala | Costa et al. Euphytica (2005) 141: 181-190 | |
| Fiesta |
6 | 6 | single parent |
34 | 68.60 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
8 | 8 | single parent |
33 | 66.00 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
10 | 10 | single parent |
59 | 75.00 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
12 | 12 | single parent |
26 | 77.00 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
14 | 14 | single parent |
35 | 48.20 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
16 | 16 | single parent |
33 | 66.50 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
5 | 5 | single parent |
16 | 98.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
11 | 11 | single parent |
21 | 57.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
10 | 10 | single parent |
22 | 88.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
14 | 14 | single parent |
9 | 42.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
3 | 3 | single parent |
11 | 77.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
6 | 6 | single parent |
8 | 55.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
9 | 9 | single parent |
7 | 55.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Fiesta |
17 | 17 | single parent |
6 | 70.10 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Fiesta |
6 | 6 | single parent |
6 | 26.20 |
Fiesta x Discovery | Baldi et al. (2004) Theor Appl Genet 109:231-239 | |
| Fiesta |
2 | 2 | single parent |
18 | 71.10 |
Prima x Fiesta | Gao et al (2005) Theor. Appl. Genet. 111:1087-1097 | |
| Fiesta |
9 | 9 | single parent |
18 | 69.10 |
Prima x Fiesta | Gao et al (2005) Theor. Appl. Genet. 111:1087-1097 | |
| Fiesta |
2 | 2 | single parent |
41 | 77.60 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Fiesta |
4 | 4 | single parent |
21 | 69.10 |
Fiesta x Discovery | Silfverberg-Dilworth et al. (2006) Tree Genetics & Genomes 2(4) 202-224 | HiDRAS reference map |
| Malling9 |
10 | 10 | single parent |
14 | 69.70 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
12 | 12 | single parent |
13 | 76.90 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
14 | 14 | single parent |
6 | 51.00 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
16 | 16 | single parent |
6 | 62.80 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
11 | 11 | single parent |
15 | 86.40 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
13 | 13 | single parent |
9 | 52.30 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
15 | 15 | single parent |
12 | 99.99 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
17 | 17 | single parent |
10 | 92.10 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
5 | 5 | single parent |
25 | 73.50 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
4 | 4 | single parent |
7 | 29.60 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
6 | 6 | single parent |
3 | 17.60 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
7 | 7 | single parent |
6 | 66.10 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
8 | 8 | single parent |
17 | 84.20 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
9 | 9 | single parent |
14 | 56.50 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
1 | 1 | single parent |
6 | 40.70 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
2 | 2 | single parent |
23 | 84.80 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Malling9 |
3 | 3 | single parent |
10 | 99.99 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Mondial Gala |
10 | 10 | single parent |
8 | 74.00 |
Fiesta x Mondial Gala | Costa et al. Euphytica (2005) 141: 181-190 | |
| Northern Spy |
8 | 8 | single parent |
8 | 45.80 |
Sciglo x Northern Spy | Bus et al. (2008) Tree Genetics & Genomes 4:233-236 | |
| PI 613988 |
1 | 1 | single parent |
16 | 72.80 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
11 | 11 | single parent |
9 | 97.86 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
13 | 13 | single parent |
11 | 79.91 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
15 | 15 | single parent |
11 | 99.99 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
17 | 17 | single parent |
12 | 98.06 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
3 | 3 | single parent |
5 | 19.52 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
5 | 5 | single parent |
11 | 72.99 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
7 | 7 | single parent |
13 | 63.99 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
9 | 9 | single parent |
10 | 63.64 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
10 | 10 | single parent |
19 | 99.99 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
12 | 12 | single parent |
9 | 96.96 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
14 | 14 | single parent |
6 | 70.33 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
16 | 16 | single parent |
14 | 86.64 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
2 | 2 | single parent |
10 | 89.95 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
4 | 4 | single parent |
9 | 51.04 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
6 | 6 | single parent |
6 | 91.88 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| PI 613988 |
8 | 8 | single parent |
9 | 69.64 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Prima |
17 | 17 | single parent |
5 | 34.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
13 | 13 | single parent |
11 | 48.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
5 | 5 | single parent |
18 | 67.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
11 | 11 | single parent |
6 | 31.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
10 | 10 | single parent |
14 | 56.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
14 | 14 | single parent |
5 | 42.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
3 | 3 | single parent |
12 | 61.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
6 | 6 | single parent |
11 | 55.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
2 | 2 | single parent |
16 | 49.30 |
Prima x Fiesta | Gao et al (2005) Theor. Appl. Genet. 111:1087-1097 | |
| Prima |
9 | 9 | single parent |
41 | 65.40 |
Jonathan x Prima | Gao et al (2005) Theor. Appl. Genet. 111:1087-1097 | |
| Prima |
15 | 15 | single parent |
11 | 60.00 |
Prima x Fiesta | Costa et al. Euphytica (2005) 141: 181-190 | |
| Prima |
1 | 1 | single parent |
25 | 54.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
2 | 2 | single parent |
8 | 47.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
8 | 8 | single parent |
12 | 46.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
9 | 9 | single parent |
9 | 47.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
16 | 16 | single parent |
17 | 55.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
12 | 12 | single parent |
10 | 61.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
15 | 15 | single parent |
8 | 58.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
4 | 4 | single parent |
13 | 49.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
7 | 7 | single parent |
13 | 32.00 |
Prima x Fiesta | Maliepaard et al. Theor Appl Genet (1998) 97: 60-73 | EU project: EAGMAP |
| Prima |
8 | 8 | single parent |
23 | 46.00 |
Prima x Fiesta | Gao et al (2005) Theor. Appl. Genet. 111:1087-1097 | |
| Robusta5 |
3 | 3 | single parent |
11 | 73.90 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
10 | 10 | single parent |
11 | 84.40 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
12 | 12 | single parent |
14 | 76.60 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
14 | 14 | single parent |
12 | 65.20 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
16 | 16 | single parent |
14 | 65.40 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
17 | 17 | single parent |
8 | 65.60 |
Malling 9 x Robusta 5 | Bus et al. (2008) Tree Genetics & Genomes 4:233-236 | |
| Robusta5 |
5 | 5 | single parent |
20 | 69.20 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
4 | 4 | single parent |
11 | 45.70 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
6 | 6 | single parent |
12 | 61.80 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
7 | 7 | single parent |
5 | 51.00 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
8 | 8 | single parent |
11 | 56.80 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
9 | 9 | single parent |
10 | 59.50 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
1 | 1 | single parent |
8 | 33.10 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
2 | 2 | single parent |
21 | 61.80 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
11 | 11 | single parent |
19 | 71.70 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
13 | 13 | single parent |
10 | 52.20 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
15 | 15 | single parent |
12 | 93.50 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Robusta5 |
17 | 17 | single parent |
6 | 64.90 |
Malling 9 x Robusta 5 | Celton et al.(2009) Tree Genetics & Genomes | |
| Royal Gala |
11 | 11 | single parent |
14 | 75.08 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
13 | 13 | single parent |
6 | 72.75 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
15 | 15 | single parent |
19 | 99.99 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
17 | 17 | single parent |
18 | 79.15 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
3 | 3 | single parent |
11 | 93.70 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
5 | 5 | single parent |
19 | 63.01 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
7 | 7 | single parent |
8 | 69.25 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
9 | 9 | single parent |
15 | 87.68 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
1 | 1 | single parent |
9 | 72.40 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
10 | 10 | single parent |
9 | 90.19 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
12 | 12 | single parent |
11 | 86.93 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
14 | 14 | single parent |
9 | 42.64 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
16 | 16 | single parent |
8 | 83.53 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
2 | 2 | single parent |
9 | 47.40 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
4 | 4 | single parent |
8 | 55.86 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
6 | 6 | single parent |
9 | 70.94 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Royal Gala |
8 | 8 | single parent |
8 | 84.07 |
GMAL 4595 from Royal Gala x PI 613988 | Wang et al. (2012) Molecular Breeding | PI 613988 is an apple scab resistant accession of M. sieversii |
| Telamon |
3 | 3 | single parent |
20 | 62.40 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
10 | 12 | single parent |
16 | 74.40 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
12 | 1 | single parent |
16 | 62.00 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
14 | 0 | single parent |
10 | 43.90 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
16 | 4 | single parent |
9 | 42.10 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
2 | 17 | single parent |
18 | 69.90 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
5 | 15 | single parent |
29 | 89.00 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
7 | 6 | single parent |
13 | 52.50 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
9 | 0 | single parent |
18 | 66.10 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
1 | 14 | single parent |
21 | 64.90 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
11 | 8 | single parent |
15 | 42.90 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
13 | 11 | single parent |
14 | 72.30 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
15 | 10 | single parent |
10 | 70.20 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
17 | 0 | single parent |
9 | 54.20 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
4 | 7 | single parent |
14 | 62.20 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
6 | 2 | single parent |
22 | 70.30 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| Telamon |
8 | 0 | single parent |
5 | 39.80 |
Telamon x Braeburn | Kenis & Keulemans. Molecular Breeding (2005) 15: 205-219 | |
| TN10-8 |
17 | 17 | single parent |
16 | 85.20 |
Discovery x TN10-8 | Bus et al. (2008) Tree Genetics & Genomes 4:233-236 | |