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PDBsum entry 2htx
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References listed in PDB file
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Key reference
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Title
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Elucidation of the mechanism and end products of glutaraldehyde crosslinking reaction by X-Ray structure analysis.
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Authors
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Y.Wine,
N.Cohen-Hadar,
A.Freeman,
F.Frolow.
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Ref.
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Biotechnol Bioeng, 2007,
98,
711-718.
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PubMed id
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Abstract
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Glutaraldehyde has been used for several decades as an effective crosslinking
agent for many applications including sample fixation for microscopy, enzyme and
cell immobilization, and stabilization of protein crystals. Despite of its
common use as a crosslinking agent, the mechanism and chemistry involved in
glutaraldehyde crosslinking reaction is not yet fully understood. Here we
describe feasibility study and results obtained from a new approach to
investigate the process of protein crystals stabilization by glutaraldehyde
crosslinking. It involves exposure of a model protein crystal (Lysozyme) to
glutaraldehyde in alkaline or acidic pH for different incubation periods and
reaction arrest by medium exchange with crystallization medium to remove unbound
glutaraldehyde. The crystals were subsequently incubated in diluted buffer
affecting dissolution of un-crosslinked crystals. Samples from the resulting
solution were subjected to protein composition analysis by gel electrophoresis
and mass spectroscopy while crosslinked, dissolution resistant crystals were
subjected to high resolution X-ray structural analysis. Data from gel
electrophoresis indicated that the crosslinking process starts at specific
preferable crosslinking site by lysozyme dimer formation, for both acidic and
alkaline pH values. These dimer formations were followed by trimer and tetramer
formations leading eventually to dissolution resistant crystals. The
crosslinking initiation site and the end products obtained from glutaraldehyde
crosslinking in both pH ranges resulted from reactions between lysine residues
of neighboring protein molecules and the polymeric form of glutaraldehyde.
Reaction rate was much faster at alkaline pH. Different reaction end products,
indicating different reaction mechanisms, were identified for crosslinking
taking place under alkaline or acidic conditions.
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