Removal of sample background buffering ions and myoglobin enrichment via a pH junction created by discontinuous buffers in capillary electrophoresis

Removal of sample background buffering ions and myoglobin enrichment via a pH junction created by discontinuous buffers in capillary electrophoresis

Traditional CE sample stacking is ineffective for samples containing a high concentration of salt and/or buffer. We recently reported the use of a discontinuous buffer system for protein enrichment that was applicable to samples containing millimolar concentrations of salt. In this paper, the techni...

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Bibliographic Details
Published in:Journal of Chromatography A Vol. 1218; no. 33; pp. 5705 - 5711
Main Authors: Booker, Christina J., Sun, Samuel, Woolsey, Sarah, Mejia, Jose S., Yeung, Ken K.-C.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 19-08-2011
Elsevier
Subjects:
Analytical, structural and metabolic biochemistry
Biological and medical sciences
Buffering salt removal
Buffers
capillary electrophoresis
Charge
chromatography
Electrophoresis, Capillary - instrumentation
Electrophoresis, Capillary - methods
Enrichment
Fundamental and applied biological sciences. Psychology
Hemoproteins
Hydrogen-Ion Concentration
ionic strength
ions
Mathematical models
Metalloproteins
Myoglobin
Myoglobin - analysis
Myoglobin - isolation & purification
Neutralization reaction boundary
pH boundary
Phosphates
Protein enrichment
Proteins
salt concentration
Sample desalting
sodium phosphate
Transient reaction boundary
PP
Protein enrichment
Sample desalting
Neutralization reaction boundary
Buffering salt removal
MES
pH boundary
TRIS
Transient reaction boundary
Myoglobin
Discontinuous
Hemoprotein
Capillary electrophoresis
Chemical enrichment
Separation method
Desalting
pH
Neutralization
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Summary:Traditional CE sample stacking is ineffective for samples containing a high concentration of salt and/or buffer. We recently reported the use of a discontinuous buffer system for protein enrichment that was applicable to samples containing millimolar concentrations of salt. In this paper, the technique was investigated for samples containing unwanted buffering ions, including TRIS, MES, and phosphate, which are commonly used in biological sample preparation. Using myoglobin as a model protein, the results demonstrated that background buffering ions can be effectively removed or separated from the enriched protein. The key is to use either the acid or the base of the discontinuous buffers to adjust the pH of the sample, such that the net charge of the unwanted buffering ions is near-zero. The successful isolation and enrichment of myoglobin from up to 100 mM TRIS and 50 mM MES was demonstrated. The enrichment factors remained at approximately 200. Removal of phosphate was more challenging because its net charge was anionic in both the acid and the base of the discontinuous buffers. The enrichment was only achievable up to 30 mM of sodium phosphate, the enrichment factors observed were significantly lower, below 50, and the process was delayed due to the higher ionic strength resulted from phosphate. The migration of phosphate during enrichment was studied using a UV-absorbing analogue, phenyl phosphate. In addition, Simul 5.0 was used to simulate the discontinuous buffers in the absence and presence of TRIS and phosphate. The stimulated TRIS and phosphate concentration profiles were generally in agreement with the experimental results. The simulation also provided a better understanding on the effect of phosphate on the formation of the pH junction.
Bibliography:http://dx.doi.org/10.1016/j.chroma.2011.06.054
ObjectType-Article-1
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ISSN:0021-9673
1873-3778
DOI:10.1016/j.chroma.2011.06.054