Structural Changes in Confined Lysozyme

Eduardo Reátegui; Alptekin Aksan

Source: Journal of Biomechanical Engineering:;2009:;volume( 131 ):;issue: 007::page 74520

Author:

Eduardo Reátegui

Alptekin Aksan

DOI: 10.1115/1.3171565

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: Proteins and enzymes can be encapsulated in nanoporous gels to develop novel technologies for biosensing, biocatalysis, and biosynthesis. When encapsulated, certain macromolecules retain high levels of activity and functionality and are more resistant to denaturation when exposed to extremes of pH and temperature. We have utilized intrinsic fluorescence and Fourier transform infrared spectroscopy to determine the structural transitions of encapsulated lysozyme in the range of −120°C<T<100°C. At cryogenic temperatures encapsulated lysozyme did not show cold denaturation, instead became more structured. However, at high temperatures, the onset of heat denaturation of confined lysozyme was reduced by 15°C when compared with lysozyme in solution. Altered dynamics of the solvent and pore size distribution of the nanopores in the matrix appear to be key factors influencing the decrease in the denaturation temperature.

keyword(s): Temperature , Fourier transform infrared spectroscopy , Proteins , Water , High temperature , Fluorescence , Dynamics (Mechanics) , Low temperature , Enzymes , Macromolecules , Heat AND Nanopores ,

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Structural Changes in Confined Lysozyme

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contributor author	Eduardo Reátegui
contributor author	Alptekin Aksan
date accessioned	2017-05-09T00:31:39Z
date available	2017-05-09T00:31:39Z
date copyright	July, 2009
date issued	2009
identifier issn	0148-0731
identifier other	JBENDY-26987#074520_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/139916
description abstract	Proteins and enzymes can be encapsulated in nanoporous gels to develop novel technologies for biosensing, biocatalysis, and biosynthesis. When encapsulated, certain macromolecules retain high levels of activity and functionality and are more resistant to denaturation when exposed to extremes of pH and temperature. We have utilized intrinsic fluorescence and Fourier transform infrared spectroscopy to determine the structural transitions of encapsulated lysozyme in the range of −120°C<T<100°C. At cryogenic temperatures encapsulated lysozyme did not show cold denaturation, instead became more structured. However, at high temperatures, the onset of heat denaturation of confined lysozyme was reduced by 15°C when compared with lysozyme in solution. Altered dynamics of the solvent and pore size distribution of the nanopores in the matrix appear to be key factors influencing the decrease in the denaturation temperature.
publisher	The American Society of Mechanical Engineers (ASME)
title	Structural Changes in Confined Lysozyme
type	Journal Paper
journal volume	131
journal issue	7
journal title	Journal of Biomechanical Engineering
identifier doi	10.1115/1.3171565
journal fristpage	74520
identifier eissn	1528-8951
keywords	Temperature
keywords	Fourier transform infrared spectroscopy
keywords	Proteins
keywords	Water
keywords	High temperature
keywords	Fluorescence
keywords	Dynamics (Mechanics)
keywords	Low temperature
keywords	Enzymes
keywords	Macromolecules
keywords	Heat AND Nanopores
tree	Journal of Biomechanical Engineering:;2009:;volume( 131 ):;issue: 007
contenttype	Fulltext

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