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Egg Shell Formation

Researchers apply computing power to crack egg shell problem.

 

Image below: Growing a good egg: Metadynamics simulations show that the eggshell protein ovocleidin-17 induces the formation of calcite crystals from amorphous calcium carbonate nanoparticles. Multiple spontaneous crystallization and amorphization events were simulated; these simulations suggest a catalytic cycle that explains the role of ovocleidin-17 in the first stages of eggshell formation (the picture shows one intermediate of this cycle). [Credit: University of Warwick/Angewandte Chemie]
OC-17 binding to calcium carbonate

Researchers at the University of Warwick and the University of Sheffield have applied computing power to crack a problem in egg shell formation. The work may also give a partial answer to the age old question "what came first the chicken or the egg?"

The answer to the question in this context is "chicken" or - at least a particular chicken protein. There is however a further twist in that this particular chicken protein turns out to come both first and last. That neat trick it performs provides new insights into control of crystal growth which is key to egg shell production.

Researchers had long known that a chicken eggshell protein called ovocledidin-17 (OC-17) must play some role in egg shell formation. The protein is found only in the mineral region of the egg (the hard part of the shell) and lab bench results showed that it appeared to influence the transformation of (CaCO3) into calcite crystals. The mechanism of this control remained unclear.

How this process could be used to form an actual eggshell remained unclear.

University of Warwick researchers Mark Rodger and David Quigley, in collaboration with colleagues at the University of Sheffield, have now been able to apply a powerfulcomputing tool called metadynamicsand the UK national supercomputer in Edinburgh to crack this egg problem.

Dr David Quigley from the Department of Physics and Centre for Scientific Computing, University of Warwick, said: "Metadynamics extends conventional molecular dynamics (MD) simulations and is particularly good at sampling transitions between disordered and ordered states of matter."

Using these tools The Warwick and Sheffield researchers were able to create simulations that showed exactly how the protein bound to amorphous calcium carbonate surface using two clusters of "arginine residues", located on two loops of the protein and creating a literal chemical "clamp" to nano sized particles of calcium carbonate.

While clamped in this way, the OC-17 encourages the nanoparticles of calcium carbonate to transform into "calcite crystallites" that form the tiny of nucleus of crystals that can continue to grow on their own. But they also noticed that sometimes this chemical clamp didn't work. The OC-17 just seemed to detatch from the nanoparticle or "be desorbed".

Professor Mark Rodger from Department of Chemistry and Centre for Scientific Computing, University of Warwick, said "With the larger nanoparticles we examined we found that the binding sites for this chemical clamp were the same as the smaller nanoparticlesbut the binding was much weaker. In the simulations we performed, the protein never desorbed from the smaller nanoparticle, but always fell off or desorbed from the larger one. However in each case, desorption occurred at or after nucleation of calcite."

The researchers had therefore uncovered an incredibly elegant process allowing highly efficient recycling of the OC-17 protein. Effectively it acts as a catalyst, clamping on to calcium carbonate particles to kickstart crystal formation and then dropping off when the crystal nucleus is sufficiently large to grow under its own steam. This frees up the OC-17 to promote more yet more crystallisation, facilitating the speedy, literally overnight creation of an egg shell.

The researchers believe that this new insight into the elegant and highly efficient methods of promoting and controlling crystallisation in nature will be of great benefit to anyone exploring how to promote and control artificial forms of crystallisation.


Further Information:

Colin L. Freeman, John H. Harding, David Quigley, Prof. P. Mark Rodger:
Structural Control of Crystal Nuclei by an Eggshell Protein.
In: Angewandte Chemie; Volume 49 Issue 30, Pages 5135 - 5137, published online: 10 Jun 2010, DOI 10.1002/anie.201000679

Source: University of Warwick, UK

 


Last update: 11.07.2010



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