54
|
146
|
3wtgB |
Crystal structure of emu (dromaius novaehollandiae) hemoglobin at 2.3 angstrom resolution |
57
|
140
|
3whmA |
Structure of hemoglobin complex with 18-crown-6 |
57
|
147
|
3wcwD |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: mg bound form |
74
|
192
|
3zjiA |
Tyr(61)b10ala mutation of m.acetivorans protoglobin in complex with cyanide |
60
|
144
|
3wctB |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: oxygenated form |
56
|
141
|
3wr1A |
Crystal structure of cormorant (phalacrocorax carbo) hemoglobin |
58
|
150
|
3wcvC |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: ca bound form |
72
|
190
|
3zjoA |
M.acetivorans protoglobin in complex with azide |
59
|
141
|
3wcpA |
Deoxyhemoglobin sh-drug complex |
50
|
138
|
3wtgA |
Crystal structure of emu (dromaius novaehollandiae) hemoglobin at 2.3 angstrom resolution |
61
|
153
|
3wftA |
Crystal structure of horse heart myoglobin reconstituted with cobalt(ii) tetradehydrocorrin |
60
|
146
|
3wcwA |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: mg bound form |
60
|
144
|
3wcvB |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: ca bound form |
57
|
147
|
3wctD |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: oxygenated form |
67
|
176
|
3zh0A |
Functional and structural role of the n-terminal extension in methanosarcina acetivorans protoglobin |
55
|
143
|
3whmB |
Structure of hemoglobin complex with 18-crown-6 |
53
|
150
|
3wcwC |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: mg bound form |
75
|
191
|
3zjpA |
M.acetivorans protoglobin in complex with imidazole |
58
|
150
|
3wctC |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: oxygenated form |
73
|
191
|
3zjlA |
Leu(142)g4ala mutation of m.acetivorans protoglobin in complex with cyanide |
75
|
190
|
3zjjA |
Phe(93)e11leu mutation of m.acetivorans protoglobin in complex with cyanide |
60
|
151
|
3wi8A |
Crystal structure of horse heart myoglobin reconstituted with manganese porphycene |
51
|
149
|
3wcuD |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: deoxygenated form |
76
|
191
|
3zjsA |
M.acetivorans protoglobin in complex with azide and xenon |
63
|
146
|
3wcvA |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: ca bound form |
54
|
136
|
3wfxA |
Crystal structure of the imidazole-bound form of the hgbrl's globin domain |
74
|
191
|
3zjmA |
Ile(149)g11phe mutation of m.acetivorans protoglobin in complex with cyanide |
59
|
154
|
3zhwA |
X-ray crystallographic structural characteristics of arabidopsis hemoglobin i and their functional implications |
59
|
152
|
3wfuA |
Crystal structure of horse heart myoglobin reconstituted with cobalt(i) tetradehydrocorrin |
52
|
150
|
3wcuC |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: deoxygenated form |
61
|
146
|
3wctA |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: oxygenated form |
73
|
190
|
3zjnA |
M.acetivorans protoglobin in complex with cyanide |
54
|
144
|
3wcuB |
The structure of a deoxygenated 400 kda hemoglobin provides a more accurate description of the cooperative mechanism of giant hemoglobins: deoxygenated form |
63
|
190
|
3zjrA |
M.acetivorans protoglobin in complex with cyanide and xenon |
59
|
145
|
3w4uB |
Human zeta-2 beta-2-s hemoglobin |
53
|
141
|
3w4uA |
Human zeta-2 beta-2-s hemoglobin |
57
|
146
|
3vrgB |
The crystal structure of hemoglobin from woolly mammoth in the met form |
58
|
141
|
3vrfA |
The crystal structure of hemoglobin from woolly mammoth in the carbonmonoxy forms |
57
|
141
|
3vreA |
The crystal structure of hemoglobin from woolly mammoth in the deoxy form |
59
|
146
|
3vrfB |
The crystal structure of hemoglobin from woolly mammoth in the carbonmonoxy forms |
48
|
148
|
3vncA |
Crystal structure of tip-alpha n25 from helicobacter pylori in its natural dimeric form |
58
|
146
|
3vreB |
The crystal structure of hemoglobin from woolly mammoth in the deoxy form |
57
|
141
|
3vrgA |
The crystal structure of hemoglobin from woolly mammoth in the met form |
59
|
151
|
3vauA |
Myoglobin nitrite structure: nitriheme modified |
69
|
177
|
3v58B |
Crystal structure of the b-phycoerythrin from the red algae porphyridium cruentum at ph5 |
59
|
152
|
3v2vA |
Nitrite bound chlorin substituted myoglobin- method 1 |
51
|
144
|
3vhbA |
Imidazole adduct of the bacterial hemoglobin from vitreoscilla sp. |
70
|
164
|
3v57A |
Crystal structure of the b-phycoerythrin from the red algae porphyridium cruentum at ph8 |
66
|
164
|
3v58A |
Crystal structure of the b-phycoerythrin from the red algae porphyridium cruentum at ph5 |
60
|
152
|
3v2zA |
Nitrite bound chlorin substituted myoglobin- method 2 |