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Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches

The properties of alkylated lipase are successfully explored through experimental and molecular modelling methods. Alkylation was done using aldehydes with different degree of modification to represent different levels of hydrophobicity which is important for enzymes to work in nonaqueous environme...

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Main Author: Tejo, Bimo Ario
Format: Thesis
Language:English
Published: 2004
Subjects:
Alkylation
Candida rugosa
Online Access:http://psasir.upm.edu.my/id/eprint/4819/1/FBSB_2004_3%20IR.pdf
http://psasir.upm.edu.my/id/eprint/4819/
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spelling my.upm.eprints.48192021-12-22T07:30:10Z http://psasir.upm.edu.my/id/eprint/4819/ Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches Tejo, Bimo Ario The properties of alkylated lipase are successfully explored through experimental and molecular modelling methods. Alkylation was done using aldehydes with different degree of modification to represent different levels of hydrophobicity which is important for enzymes to work in nonaqueous environment. Far ultraviolet circular dichroism (CD) spectroscopy of the lipase in aqueous solvent shows that increasing the degree of modification from 49% to 86% resulted in loss in secondary structure which is attributed to the enzyme unfolding. The secondary structure elements of the CD spectra of native and modified lipase were analysed using the CDPro software and the K2D program. Both methods yield the same results in that the ratio of α-helical structure is lost. This result explains why alkylated lipases have much lower activity in an aqueous environment. Molecular modelling simulations were performed to study the structural and dynamical changes of the lipase upon different levels of modification. Simulations were run for 1 ns (300 K) with five different initial velocities to obtain better conformational sampling. Two solvent systems were used: TIP3P water model and carbon tetrachloride (CCl4) solvent model in periodic boundary condition (PBC). Generally, lipases simulated in water are less deviated in term of root mean square deviations (rmsd) compared to lipases simulated in CCl4. Lid movements are essential for lipase function, both in water and waterlipid environments. Analyses of lid dynamics were done using timecorrelation function and second-order Legendre polynomial function. Lipase in water and CCl4 shows different properties of dynamics. Without alkylation, the time correlation function of lipase in water shows one slow exponential decay with a correlation time of τ = 92.8 ps. In contrast, for simulations in CCl4 the lid has a more complex dynamics. Exponential fit of open CRL in CCl4 results in two different τ values: a fast motion τ1 = 5.6 ps and a slow motion τ2 = 163.8 ps.Upon alkylation, different levels of modification show different properties of lid motions. In CCl4, lid region is highly stabilised upon 95% alkylation with slow motion mode of τ1 = 4.1 ps and τ2 = 577.8 ps. Slow motion effect of lid region is also observed at 63% with τ1 = 2.9 ps and τ2 = 209.2 ps and 43% modification with τ1 = 3.4 ps and τ2 = 117.9 ps. In water, 43% and 95% modification show similar motion with unmodified lipase, with one slow exponential decay of τ = 142.8 ps and 133.6 ps, respectively. However, 63% modification shows more complex dynamics with different τ values which mimics the dynamics properties in CCl4. A novel lid-locking mechanism which stabilises the opening form of lid region has been observed during simulations of unmodified CRL in CCl4, i.e. a salt bridge between Lys85 and Asp284. This salt bridge is highly stabilised on unmodified lipase with a distance of 3.3 Å compared with lipase simulated in water with a distance of 15.25 Å. Alkylation at 43% causes the salt bridge to be deformed in CCl4 with a distance of 6.03 Å; however, 63% modification stabilises the salt bridge with a distance of 3.88 and 95% modification shows the most stabilising effect with a distance of 3.19 Å. 2004-09 Thesis NonPeerReviewed text en http://psasir.upm.edu.my/id/eprint/4819/1/FBSB_2004_3%20IR.pdf Tejo, Bimo Ario (2004) Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches. Doctoral thesis, Universiti Putra Malaysia. Alkylation Candida rugosa
institution Universiti Putra Malaysia
building UPM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Putra Malaysia
content_source UPM Institutional Repository
url_provider http://psasir.upm.edu.my/
language English
topic Alkylation
Candida rugosa
spellingShingle Alkylation
Candida rugosa
Tejo, Bimo Ario
Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches
description The properties of alkylated lipase are successfully explored through experimental and molecular modelling methods. Alkylation was done using aldehydes with different degree of modification to represent different levels of hydrophobicity which is important for enzymes to work in nonaqueous environment. Far ultraviolet circular dichroism (CD) spectroscopy of the lipase in aqueous solvent shows that increasing the degree of modification from 49% to 86% resulted in loss in secondary structure which is attributed to the enzyme unfolding. The secondary structure elements of the CD spectra of native and modified lipase were analysed using the CDPro software and the K2D program. Both methods yield the same results in that the ratio of α-helical structure is lost. This result explains why alkylated lipases have much lower activity in an aqueous environment. Molecular modelling simulations were performed to study the structural and dynamical changes of the lipase upon different levels of modification. Simulations were run for 1 ns (300 K) with five different initial velocities to obtain better conformational sampling. Two solvent systems were used: TIP3P water model and carbon tetrachloride (CCl4) solvent model in periodic boundary condition (PBC). Generally, lipases simulated in water are less deviated in term of root mean square deviations (rmsd) compared to lipases simulated in CCl4. Lid movements are essential for lipase function, both in water and waterlipid environments. Analyses of lid dynamics were done using timecorrelation function and second-order Legendre polynomial function. Lipase in water and CCl4 shows different properties of dynamics. Without alkylation, the time correlation function of lipase in water shows one slow exponential decay with a correlation time of τ = 92.8 ps. In contrast, for simulations in CCl4 the lid has a more complex dynamics. Exponential fit of open CRL in CCl4 results in two different τ values: a fast motion τ1 = 5.6 ps and a slow motion τ2 = 163.8 ps.Upon alkylation, different levels of modification show different properties of lid motions. In CCl4, lid region is highly stabilised upon 95% alkylation with slow motion mode of τ1 = 4.1 ps and τ2 = 577.8 ps. Slow motion effect of lid region is also observed at 63% with τ1 = 2.9 ps and τ2 = 209.2 ps and 43% modification with τ1 = 3.4 ps and τ2 = 117.9 ps. In water, 43% and 95% modification show similar motion with unmodified lipase, with one slow exponential decay of τ = 142.8 ps and 133.6 ps, respectively. However, 63% modification shows more complex dynamics with different τ values which mimics the dynamics properties in CCl4. A novel lid-locking mechanism which stabilises the opening form of lid region has been observed during simulations of unmodified CRL in CCl4, i.e. a salt bridge between Lys85 and Asp284. This salt bridge is highly stabilised on unmodified lipase with a distance of 3.3 Å compared with lipase simulated in water with a distance of 15.25 Å. Alkylation at 43% causes the salt bridge to be deformed in CCl4 with a distance of 6.03 Å; however, 63% modification stabilises the salt bridge with a distance of 3.88 and 95% modification shows the most stabilising effect with a distance of 3.19 Å.
format Thesis
author Tejo, Bimo Ario
author_facet Tejo, Bimo Ario
author_sort Tejo, Bimo Ario
title Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches
title_short Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches
title_full Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches
title_fullStr Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches
title_full_unstemmed Reductive Alkylation of Candida Rugosa Lipase: Structural Approaches
title_sort reductive alkylation of candida rugosa lipase: structural approaches
publishDate 2004
url http://psasir.upm.edu.my/id/eprint/4819/1/FBSB_2004_3%20IR.pdf
http://psasir.upm.edu.my/id/eprint/4819/
_version_ 1720438443711922176
score 13.160551

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