Properties of proteins: Difference between revisions
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== Ideal metal bond distances == | == Ideal metal bond distances == | ||
* classic paper: Harding, M. (1999) [http://journals.iucr.org/d/issues/1999/08/00/ad0073/index.html The geometry of metal-ligand interactions relevant to proteins] | * classic paper: Harding, M. (1999) [http://journals.iucr.org/d/issues/1999/08/00/ad0073/index.html The geometry of metal-ligand interactions relevant to proteins] | ||
* webservice (2006) http://tanna.bch.ed.ac.uk | * webservice (2006) http://tanna.bch.ed.ac.uk | ||
* database (2008) http://eduliss.bch.ed.ac.uk/MESPEUS/ | * database (2008) http://eduliss.bch.ed.ac.uk/MESPEUS/ | ||
Revision as of 21:22, 14 December 2011
Ideal metal bond distances
- classic paper: Harding, M. (1999) The geometry of metal-ligand interactions relevant to proteins
- webservice (2006) http://tanna.bch.ed.ac.uk
- database (2008) http://eduliss.bch.ed.ac.uk/MESPEUS/
Distinguishing ions from waters
A paper exists about the bond valence method (Acta Cryst. 2003 D59 32-37). Subsequent experience has shown that although this method works well for identifying ions such as Mg2+ and Ca2+ with good resolution data, it is not reliable in other cases such as Na+.
Whereas Cl- can often be seen in anom maps, Na+ has a lower f".
There are however some tentative indicators for Na+. The bond valence sum (the sum of the 'bond orders' to the surrounding atoms estimated from the distances) tends to be higher than for Cl- or H2O. Tetrahedral coordination is more likely to be water or Cl-, Na+ prefers 5 or 6 neighbors. And of course two cations (or two anions) that are close to each other should not have an occupancy sum greater than unity.
Melting point
Thermofluor is a fluorescence-based thermal stability assay. From [1]: The experiment is easy to perform and requires no prior knowledge of the protein properties. Every standard real‐time PCR machine – available in many research labs – is suitable to perform this high‐throughput experiment in a short time (1‐2 hours). Only relatively little protein (500 µl of protein at 1‐2 mg/ml for a 96‐well experiment) and a dye (e.g. SYPRO® Orange, Invitrogen) are required. Proteins containing prosthetic groups (e.g. FAD) may not even require an external fluorophore if the intrinsic signal can be used during the Thermofluor experiment. For FAD‐containing proteins this method has been termed ThermoFAD.
Ku T, Lu P, Chan C, Wang T, Lai S, Lyu P, Hsiao N. (2009) Predicting melting temperature directly from protein sequences. Comput Biol Chem. 33, 445-450 at [2]. They have a list of 35 different proteins with their Tms with the references from where they obtained their data, and their Tm Index program is available at [3].
A specific case which shows that Tm does not need to be high: the protein with PDB-ID 1ofc had a melting temperature of 37°C (from CD), which was supported by the fact that it did not express in E.coli at that temperature. At 20°C it expressed to about 60mg / (liter LB), could be concentrated to more than 100mg/ml, crystallised at room temperature and diffracted to 1.9A. The initial purification steps were done at 4°C.