The Role of Arg157Ser in Improving the Compactness and Stability of ARM Lipase

Salleh, Abu Bakar

doi:10.4172/jcsb.1000088

Cited by 22 publications

(9 citation statements)

References 39 publications

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“…In addition, the cold-adapted organic solvent tolerant AT2 lipase and a mutant demonstrated high RMSf values in the N-terminal and C-terminal moieties in water simulations at 25 and 45 °C [49]. The same trend was found for the thermostable ARM lipase and a mutant, indicating high mobility in the N-terminal region at high temperature [50]. For enzymes simulated in an organic solvent alone, more fluctuations were observed compared to in the reverse micelles.…”

Section: Stability and Flexibility Analysis Of Ams8 In Triton X-100/tsupporting

confidence: 55%

Optimization and in Silico Analysis of a Cold-Adapted Lipase from an Antarctic Pseudomonas sp. Strain AMS8 Reaction in Triton X-100 Reverse Micelles

et al. 2018

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A moderate yield of a purified enzyme can be achieved by using the simple technique of reverse micellar extraction (RME). RME is a liquid-liquid extraction method that uses a surfactant and an organic solvent to extract biomolecules. Instead of traditional chromatographic purification methods, which are tedious and expensive, RME using the nonionic surfactant Triton X-100 and toluene is used as an alternative purification technique to purify a recombinant cold-adapted lipase, AMS8. Various process parameters were optimized to maximize the activity recovery of the AMS8 lipase. The optimal conditions were found to be 50 mM sodium phosphate buffer, pH 7, 0.125 M NaCl, and 0.07 M Triton X-100 in toluene at 10 • C. Approximately 56% of the lipase activity was successfully recovered. Structural analysis of the lipase in a reverse micelle (RM) was performed using an in silico approach. The predicted model of AMS8 lipase was simulated in the Triton X-100/toluene reverse micelles from 5 to 40 • C. The lid 2 was slightly opened at 10 • C. However, the secondary structure of AMS8 was most affected in the non-catalytic domain compared to the catalytic domain, with an increased coil conformation. These results suggest that an AMS8 lipase can be extracted using Triton X-100/water/toluene micelles at low temperature. This RME approach will be an important tool for the downstream processing of recombinant cold-adapted lipases.2 of 15 absence of co-factors [6][7][8][9]. Cold-active lipases cover a broad spectrum of biotechnological applications, such as additives in detergents (cold washing), an additive in food industries (fermentation, cheese manufacture, bakery, meat tenderizing), bioremediations (Digesters, composting, oil, or xenobiotic biology applications), and molecular biology applications [10][11][12].Several conventional purification methods for cold-adapted lipases have been applied for many years in industrial and laboratory procedures [13,14]. For example, the lipase KE38 from Pseudomonas fluorescens KE38 was successfully purified using (NH 4 ) 2 SO 4 precipitation, Sephadex G-100 and, lastly, ultrafiltration with a recovery of 54.99% and a 41.13-fold purification [15]. Likewise, three purification steps were used to purify extracellular LipP from Pseudomonas sp. strain BII-I by using 20-65% (NH 4 ) 2 SO 4 precipitation followed by a diethylaminoethyl (DEAE)-cellulose and graphite column with 38-fold purification and a recovery of 17% of the lipase activity [13]. Although a good yield of purified enzyme was obtained from these chromatographic techniques, the production and purification of large amounts of enzyme are often laborious and expensive, which hinders applications for these enzymes [16]. Therefore, a standard method that enables the purification of large amounts of highly pure, active, and stable enzymes is urgently needed. Reverse micellar extraction is one of the alternative purification methods under consideration for continuous downstream processing of bulk enzymes.A reverse micelle (RM) is a surfactant...

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Section: Stability and Flexibility Analysis Of Ams8 In Triton X-100/tsupporting

confidence: 55%

Optimization and in Silico Analysis of a Cold-Adapted Lipase from an Antarctic Pseudomonas sp. Strain AMS8 Reaction in Triton X-100 Reverse Micelles

et al. 2018

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“…In general, the result is proportional to the deviation of the enzyme structure, as indicated in Figure 3. While SASA indicates the transfer of free energy required to move a protein from aqueous to nonpolar solvent [29], as exhibited in Figure 7, the SASA scores at 5°C and 0°C show the fluctuation pattern, which is maintained throughout the 12 ns of simulation. Compared to 25°C, the figure increases, which indicates unfolding of enzyme within the simulation period.…”

Section: Resultsmentioning

confidence: 99%

Structural Adaptation of Cold-Active RTX Lipase fromPseudomonassp. Strain AMS8 Revealed via Homology and Molecular Dynamics Simulation Approaches

Ali

Fuzi

Ganasen

et al. 2013

BioMed Research International

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The psychrophilic enzyme is an interesting subject to study due to its special ability to adapt to extreme temperatures, unlike typical enzymes. Utilizing computer-aided software, the predicted structure and function of the enzyme lipase AMS8 (LipAMS8) (isolated from the psychrophilic Pseudomonas sp., obtained from the Antarctic soil) are studied. The enzyme shows significant sequence similarities with lipases from Pseudomonas sp. MIS38 and Serratia marcescens. These similarities aid in the prediction of the 3D molecular structure of the enzyme. In this study, 12 ns MD simulation is performed at different temperatures for structural flexibility and stability analysis. The results show that the enzyme is most stable at 0°C and 5°C. In terms of stability and flexibility, the catalytic domain (N-terminus) maintained its stability more than the noncatalytic domain (C-terminus), but the non-catalytic domain showed higher flexibility than the catalytic domain. The analysis of the structure and function of LipAMS8 provides new insights into the structural adaptation of this protein at low temperatures. The information obtained could be a useful tool for low temperature industrial applications and molecular engineering purposes, in the near future.

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“…The solvent accessible surface area (SASA) was also used to study the solvent-accessible surface area of AMS8 lipase. SASA indicates the transfer of free energy required to move a protein from aqueous to a non-polar solvent [25]. Based on the SASA graph in Figure 4, the AMS8 lipase structure without the Ca2, Ca4, Ca5, and Ca6 fluctuation pattern maintained and did not fluctuate more than 21.4 Å 2 within the simulation period.…”

Section: Solvent Accessible Surface Area (Sasa) Analysismentioning

confidence: 98%

The Influence of Calcium toward Order/Disorder Conformation of Repeat-in-Toxin (RTX) Structure of Family I.3 Lipase from Pseudomonas fluorescens AMS8

Ali

Salleh

Leow

et al. 2020

Toxins

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Calcium-binding plays a decisive role in the folding and stabilization of many RTX proteins, especially for the RTX domain. Although many studies have been conducted to prove the contribution of Ca2+ ion toward the folding and stabilization of RTX proteins, its functional dynamics and conformational structural changes remain elusive. Here, molecular docking and molecular dynamics (MD) simulations were performed to analyze the contribution of Ca2+ ion toward the folding and stabilization of the RTX lipase (AMS8 lipase) structure. AMS8 lipase contains six Ca2+ ions (Ca1–Ca6). Three Ca2+ ions (Ca3, Ca4, and Ca5) were bound to the RTX parallel β-roll motif repeat structure (RTX domain). The metal ion (Ca2+) docking analysis gives a high binding energy, especially for Ca4 and Ca5 which are tightly bound to the RTX domain. The function of each Ca2+ ion is further analyzed using the MD simulation. The removal of Ca3, Ca4, and Ca5 caused the AMS8 lipase structure to become unstable and unfolded. The results suggested that Ca3, Ca4, and Ca5 stabilized the RTX domain. In conclusion, Ca3, Ca4, and Ca5 play a crucial role in the folding and stabilization of the RTX domain, which sustain the integrity of the overall AMS8 lipase structure.

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The Role of Arg157Ser in Improving the Compactness and Stability of ARM Lipase

Cited by 22 publications

References 39 publications

Optimization and in Silico Analysis of a Cold-Adapted Lipase from an Antarctic Pseudomonas sp. Strain AMS8 Reaction in Triton X-100 Reverse Micelles

Optimization and in Silico Analysis of a Cold-Adapted Lipase from an Antarctic Pseudomonas sp. Strain AMS8 Reaction in Triton X-100 Reverse Micelles

Structural Adaptation of Cold-Active RTX Lipase fromPseudomonassp. Strain AMS8 Revealed via Homology and Molecular Dynamics Simulation Approaches

The Influence of Calcium toward Order/Disorder Conformation of Repeat-in-Toxin (RTX) Structure of Family I.3 Lipase from Pseudomonas fluorescens AMS8

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