Extraction of intracellular protein from Escherichia coli is traditionally achieved by mechanical disruption. A chemical treatment that destroys the integrity of the bacterial cell wall and could provide an alternative technique is examined in this study. Treatment with a combination of the chelating agent ethylenediaminetet-raacetate (EDTA) (greater than 0.3 mM) and the chaotropic agent urea (6 M) is highly effective at releasing protein from uninduced E. coli. The 6 M urea in the presence of 3 mM EDTA can release cytoplasmic protein from both logarithmic-phase and stationary-phase E. coli cells at levels equivalent to mechanical disruption. The concentrations of the two chemical agents were the major variables affecting the maximum levels of protein release. Several minor variables and interactions were also identified. The kinetics of protein release is first order. For 2, 4, and 6 M urea with 3 mM EDTA, the time constant is approximately 2.5 min independent of urea concentration. Kinetics for 3 mM EDTA without urea is considerably slower, with a time constant of 12.3 min. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 53: 453-458, 1997

Bailey

Binks

Bochner

Ibister

Jones

Kaplan

Kinouchi

Kitts

McCormick

Osmon

Soli

Biotechnology and Bioengineering

We have developed a methodology based on experimental design, to optimize a polyacrylamide gel as the support for enzyme immobilization, taking advantage of all the properties which this type of gel has. Monomer and crosslinking agent proportions are responsible for both the porous structure and pore size of the gel. A correct selection of those variables and suitable synthesis conditions leads to an increase in the activity retained by the gel. The path of steepest ascent method was used to obtain the relative maximum activity. The maximum retained activity was chosen with a central composite design in terms of the gel composition. The retained activity in the network, loss activity in the wash water, and loss activity due to steric impediment or blockage was modeled in terms of the variables responsible for the gel structure.We have developed a methodology based on experimental design, to optimize a polyacrylamide gel as the support for enzyme immobilization, taking advantage of all the properties which this type of gel has. Monomer and crosslinking agent proportions are responsible for both the porous structure and pore size of the gel. A correct selection of those variables and suitable synthesis conditions leads to an increase in the activity retained by the gel. The path of steepest ascent method was used to obtain the relative maximum activity. The maximum retained activity was chosen with a central composite design in terms of the gel composition. The retained activity in the network, loss activity in the wash water, and loss activity due to steric impediment or blockage was modeled in terms of the variables responsible for the gel structure

Pizarro, C.

Fernández-Torroba, M.A.

Benito, C.

González-Sáiz, J.M.

Repositorio de Universidad de La Rioja

English

Optimizacion by experimental design of polyacrylamide gel composition as support for enzyme immobilization by entrapment

The kinetics of bacterial oxidation of ferrous iron in the presence of Thiobacillus ferrooxidans cells were studied using an initial-rate method. Measurements of the redox potential of the solution during the oxidation of ferrous iron were used to assess the initial rate of the reaction. Effects on the rate of reaction were determined for ferrous iron concentration in the range 0.25 to 30 kg m-3, bacterial concentration in the range 3.25 x 107 to 4.47 x 108 cells mL-1, and temperature in the range 20 to 35°C. Using these experimental results and an approach based on Michaelis-Menten kinetics, a model for biological oxidation of ferrous iron was developed. The model, which incorporates terms for the effect of temperature and substrate and cell inhibition, was successfully used to simulate the full range of experimental data obtained

Nemati, M.

Webb, C.

The University of Manchester - Institutional Repository

A kinetic model for biological oxidation of ferrous iron by Thiobacillus ferrooxidans

Extraction of intracellular protein from Escherichia coli is traditionally achieved by mechanical disruption. A chemical treatment that destroys the integrity of the bacterial cell wall and could provide an alternative technique is examined in this study. Treatment with a combination of the chelating agent ethylenediaminetetraacetate (EDTA) (greater than 0.3 mM) and the chaotropic agent urea (6 M) is highly effective at releasing protein from uninduced E. coli. The 6 M urea in the presence of 3 mM EDTA can release cytoplasmic protein from both logarithmic-phase and stationary-phase E. coli cells at levels equivalent to mechanical disruption. The concentrations of the two chemical agents were the major variables affecting the maximum levels of protein release. Several minor variables and interactions were also identified. The kinetics of protein release is first order. For 2, 4, and 6 M urea with 3 mM EDTA, the time constant is approximately 2.5 min independent of urea concentration. Kinetics for 3 mM EDTA without urea is considerably slower, with a time constant of 12.3 min. (C) 1997 John Wiley & Sons, Inc

Falconer, RJ

ONeill, BK

Middelberg, APJ

University of Queensland eSpace