Water-mediated variability in the structure of relaxed-state haemoglobinKaushal, P.S., Sankaranarayanan, R., Vijayan, M.
(2008) Acta Crystallogr.,Sect.F 64: 463-469
- PubMed: 18540052
- DOI: 10.1107/S1744309108013109
- Primary Citation of Related Structures:
- PubMed Abstract:
- Structure of human methaemoglobin: The variation of a theme
Biswal, B.K.,Vijayan, M.
(2001) Curr.Sci. 81: 1100
- The structure of hemoglobin III: Direct determination of the molecular transform
(1954) Proc.R.Soc.Lond A Math.Phys.Sci. 225: 264
- Discontinuous lattice changes in hemoglobin crystal
Huxley, H.E.,Kendrew, J.C.
(1953) Acta Crystallogr. 6: 76
- A new relaxed state in horse methemoglobin characterized by crystallographic studies
Sankaranarayanan, R.,Biswal, B.K.,Vijayan, M.
(2005) Proteins 60: 547
- Structures of human oxy- and deoxyhaemoglobin at different levels of humidity: variability in the T state
Biswal, B.K.,Vijayan, M.
(2002) Acta Crystallogr.,Sect.D 58: 1155
The crystal structure of high-salt horse methaemoglobin has been determined at environmental relative humidities (r.h.) of 88, 79, 75 and 66%. The molecule is in the R state in the native and the r.h. 88% crystals. At r.h. 79%, the water content of t ...
The crystal structure of high-salt horse methaemoglobin has been determined at environmental relative humidities (r.h.) of 88, 79, 75 and 66%. The molecule is in the R state in the native and the r.h. 88% crystals. At r.h. 79%, the water content of the crystal is reduced and the molecule appears to move towards the R2 state. The crystals undergo a water-mediated transformation involving a doubling of one of the unit-cell parameters and an increase in water content when the environmental humidity is further reduced to r.h. 75%. The water content is now similar to that in the native crystals and the molecules are in the R state. The crystal structure at r.h. 66% is similar, but not identical, to that at r.h. 75%, but the solvent content is substantially reduced and the molecules have a quaternary structure that is in between those corresponding to the R and R2 states. Thus, variation in hydration leads to variation in the quaternary structure. Furthermore, partial dehydration appears to shift the structure from the R state to the R2 state. This observation is in agreement with the earlier conclusion that the changes in protein structure that accompany partial dehydration are similar to those that occur during protein action.
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560 012, India.