The “speed limit” for macromolecular crystal growth

The “speed limit” for macromolecular crystal growth

A simple “diffusion‐to‐capture” model is used to estimate the upper limit to the growth rate of macromolecular crystals under conditions when the rate limiting process is the mass transfer of sample from solution to the crystal. Under diffusion‐limited crystal growth conditions, this model predicts...

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Veröffentlicht in:Protein science 2018-10, Vol.27 (10), p.1837-1841
Hauptverfasser: Arias, Renee J., Kaiser, Jens T., Rees, Douglas C.
Format: Artikel
Sprache:eng
Schlagworte:
Crystal growth
Crystallization
Crystals
Diffraction patterns
Diffusion
Diffusion rate
Electron diffraction
enzyme mechanism
For the Record
Free electron lasers
Growth conditions
Growth rate
Humans
Lasers
Lysozyme
Macromolecular Substances - analysis
Macromolecular Substances - chemical synthesis
Macromolecular Substances - metabolism
Macromolecules
Mass transfer
Mathematical models
micro‐electron diffraction
Muramidase - analysis
Muramidase - chemical synthesis
Muramidase - metabolism
protein crystallization
protein nanocrystals
Turnover time
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Zusammenfassung:A simple “diffusion‐to‐capture” model is used to estimate the upper limit to the growth rate of macromolecular crystals under conditions when the rate limiting process is the mass transfer of sample from solution to the crystal. Under diffusion‐limited crystal growth conditions, this model predicts that the cross‐sectional area of a crystal will increase linearly with time; this prediction is validated by monitoring the growth rate of lysozyme crystals. A consequence of this analysis is that when crystal growth is diffusion‐limited, micron‐sized crystals can be produced in ~1 s, which would be compatible with the turnover time of many enzymes. Consequently, the ability to record diffraction patterns from sub‐micron sized crystals by X‐ray Free Electron Lasers and micro‐electron diffraction technologies opens the possibility of trapping intermediate enzyme states by crystallization.
ISSN:0961-8368
1469-896X
DOI:10.1002/pro.3491