| Adenine Component Index |
 | 2'-deoxyadenosine-5'-phosphate |
| Model constructed for 2'-deoxyadenosine-5'-phosphate from subcomponents for base, sugar and phosphate. The sugar is deoxyribose in the C2'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | 2'-deoxyadenosine-5'-phosphate |
| Model constructed for 2'-deoxyadenosine-5'-phosphate from subcomponents for base, sugar and phosphate. The sugar is deoxyribose in the C3'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | protonated 2'-deoxyadenosine-5'-phosphate |
| Model constructed for protonated 2'-deoxyadenosine-5'-phosphate from subcomponents for protonated base, sugar and phosphate. The sugar is deoxyribose in the C2'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | protonated 2'-deoxyadenosine-5'-phosphate |
| Model constructed for protonated 2'-deoxyadenosine-5'-phosphate from subcomponents for protonated base, sugar and phosphate. The sugar is deoxyribose in the C3'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | 2'-deoxyadenosine |
| Model constructed for 2'-deoxyadenosine from subcomponents for base and sugar. The sugar is deoxyribose in the C2'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | 2'-deoxyadenosine |
| Model constructed for 2'-deoxyadenosine from subcomponents for base and sugar. The sugar is deoxyribose in the C3'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | protonated 2'-deoxyadenosine |
| Model constructed for protonated 2'-deoxyadenosine from subcomponents for protonated base and sugar. The sugar is deoxyribose in the C2'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | protonated 2'-deoxyadenosine |
| Model constructed for protonated 2'-deoxyadenosine from subcomponents for protonated base and sugar. The sugar is deoxyribose in the C3'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | adenosine-5'-phosphate |
| Model constructed for adenosine-5'-phosphate from subcomponents for base, sugar and phosphate. The sugar is ribose in the C2'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | adenosine-5'-phosphate |
| Model constructed for adenosine-5'-phosphate from subcomponents for base, sugar and phosphate. The sugar is ribose in the C3'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | protonated adenosine-5'-phosphate |
| Model constructed for protonated adenosine-5'-phosphate from subcomponents for protonated base, sugar and phosphate. The sugar is ribose in the C2'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | protonated adenosine-5'-phosphate |
| Model constructed for protonated adenosine-5'-phosphate from subcomponents for protonated base, sugar and phosphate. The sugar is ribose in the C3'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | adenosine |
| Model constructed for adenosine from subcomponents for base and sugar. The sugar is ribose in the C2'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | adenosine |
| Model constructed for adenosine from subcomponents for base and sugar. The sugar is ribose in the C3'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | protonated adenosine |
| Model constructed for protonated adenosine from subcomponents for protonated base and sugar. The sugar is ribose in the C2'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | protonated adenosine |
| Model constructed for protonated adenosine from subcomponents for protonated base and sugar. The sugar is ribose in the C3'-endo conformation, and geometries for the gamma torsion angle (synclinal), the chi torsion angle (antiperiplanar), and the C3*-O3* and C5*-O5* bonds are inserted from other models. |
 | neutral adenine |
| Model constructed for neutral adenine with an N9-glycosidic linkage. |
 | protonated adenine |
| Model constructed for protonated adenine with an N9-glycosidic linkage. |
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