1bz0
From Proteopedia
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| - | [[Image:1bz0.gif|left|200px]]<br /> | + | [[Image:1bz0.gif|left|200px]]<br /><applet load="1bz0" size="350" color="white" frame="true" align="right" spinBox="true" |
| - | <applet load="1bz0" size=" | + | |
caption="1bz0, resolution 1.50Å" /> | caption="1bz0, resolution 1.50Å" /> | ||
'''HEMOGLOBIN A (HUMAN, DEOXY, HIGH SALT)'''<br /> | '''HEMOGLOBIN A (HUMAN, DEOXY, HIGH SALT)'''<br /> | ||
==Overview== | ==Overview== | ||
| - | Hemoglobin Catonsville is a mutation of human hemoglobin (an alpha 2 beta | + | Hemoglobin Catonsville is a mutation of human hemoglobin (an alpha 2 beta 2 tetramer) in which a glutamate residue is inserted into the first turn of a highly conserved 3(10) helix (the C helix) of each alpha subunit. In theory, amino acid insertions (or deletions) in protein helices can be accommodated via two distinct mechanisms. One, termed the register shift mechanism, preserves the geometry of the helix while requiring all of the residues on one flank of the insertion site to rotate by 100 degrees in the case of an alpha helix or by 120 degrees in the case of a 3(10) helix. The other, termed the bulge (or indentation) mechanism, distorts the local geometry of the helix but does not alter the helix register. High-resolution X-ray diffraction analysis of deoxyhemoglobin Catonsville shows that the inserted residue is accommodated as a bulge, demonstrating that this is a viable mechanism. (In contrast, no such evidence is yet available for the register shift mechanism.) More specifically, the insertion converts one turn of the C helix from 3(10) geometry to alpha helix-like geometry, raising the possibility that a common mechanism for accommodating insertions and deletions within helices may involve localized interconversions between 3(10), alpha, and pi helical structures. |
==Disease== | ==Disease== | ||
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==About this Structure== | ==About this Structure== | ||
| - | 1BZ0 is a [http://en.wikipedia.org/wiki/Protein_complex Protein complex] structure of sequences from [http://en.wikipedia.org/wiki/Homo_sapiens Homo sapiens] with HEM as [http://en.wikipedia.org/wiki/ligand ligand]. Full crystallographic information is available from [http:// | + | 1BZ0 is a [http://en.wikipedia.org/wiki/Protein_complex Protein complex] structure of sequences from [http://en.wikipedia.org/wiki/Homo_sapiens Homo sapiens] with <scene name='pdbligand=HEM:'>HEM</scene> as [http://en.wikipedia.org/wiki/ligand ligand]. Full crystallographic information is available from [http://oca.weizmann.ac.il/oca-bin/ocashort?id=1BZ0 OCA]. |
==Reference== | ==Reference== | ||
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[[Category: Protein complex]] | [[Category: Protein complex]] | ||
[[Category: Arnone, A.]] | [[Category: Arnone, A.]] | ||
| - | [[Category: Kavanaugh, J | + | [[Category: Kavanaugh, J S.]] |
[[Category: HEM]] | [[Category: HEM]] | ||
[[Category: oxygen transport]] | [[Category: oxygen transport]] | ||
| - | ''Page seeded by [http:// | + | ''Page seeded by [http://oca.weizmann.ac.il/oca OCA ] on Thu Feb 21 12:00:39 2008'' |
Revision as of 10:00, 21 February 2008
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HEMOGLOBIN A (HUMAN, DEOXY, HIGH SALT)
Contents |
Overview
Hemoglobin Catonsville is a mutation of human hemoglobin (an alpha 2 beta 2 tetramer) in which a glutamate residue is inserted into the first turn of a highly conserved 3(10) helix (the C helix) of each alpha subunit. In theory, amino acid insertions (or deletions) in protein helices can be accommodated via two distinct mechanisms. One, termed the register shift mechanism, preserves the geometry of the helix while requiring all of the residues on one flank of the insertion site to rotate by 100 degrees in the case of an alpha helix or by 120 degrees in the case of a 3(10) helix. The other, termed the bulge (or indentation) mechanism, distorts the local geometry of the helix but does not alter the helix register. High-resolution X-ray diffraction analysis of deoxyhemoglobin Catonsville shows that the inserted residue is accommodated as a bulge, demonstrating that this is a viable mechanism. (In contrast, no such evidence is yet available for the register shift mechanism.) More specifically, the insertion converts one turn of the C helix from 3(10) geometry to alpha helix-like geometry, raising the possibility that a common mechanism for accommodating insertions and deletions within helices may involve localized interconversions between 3(10), alpha, and pi helical structures.
Disease
Known diseases associated with this structure: Erythremias, alpha- OMIM:[141800], Erythremias, beta- OMIM:[141900], Erythrocytosis OMIM:[141850], HPFH, deletion type OMIM:[141900], Heinz body anemia OMIM:[141850], Heinz body anemias, alpha- OMIM:[141800], Heinz body anemias, beta- OMIM:[141900], Hemoglobin H disease OMIM:[141850], Hypochromic microcytic anemia OMIM:[141850], Methemoglobinemias, alpha- OMIM:[141800], Methemoglobinemias, beta- OMIM:[141900], Sickle cell anemia OMIM:[141900], Thalassemia, alpha- OMIM:[141850], Thalassemia-beta, dominant inclusion-body OMIM:[141900], Thalassemias, alpha- OMIM:[141800], Thalassemias, beta- OMIM:[141900]
About this Structure
1BZ0 is a Protein complex structure of sequences from Homo sapiens with as ligand. Full crystallographic information is available from OCA.
Reference
Accommodation of insertions in helices: the mutation in hemoglobin Catonsville (Pro 37 alpha-Glu-Thr 38 alpha) generates a 3(10)-->alpha bulge., Kavanaugh JS, Moo-Penn WF, Arnone A, Biochemistry. 1993 Mar 16;32(10):2509-13. PMID:8448109
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