Your search keyword '"Magni, Paolo"' showing total 6 results

1. Characterization of a synthetic bacterial self-destruction device for programmed cell death and for recombinant proteins release

Author

Lupotto Manuel, Zucca Susanna, Pasotti Lorenzo, Cusella De Angelis Maria, and Magni Paolo

Subjects

Biology (General), QH301-705.5

Abstract

Abstract Background Bacterial cell lysis is a widely studied mechanism that can be achieved through the intracellular expression of phage native lytic proteins. This mechanism can be exploited for programmed cell death and for gentle cell disruption to release recombinant proteins when in vivo secretion is not feasible. Several genetic parts for cell lysis have been developed and their quantitative characterization is an essential step to enable the engineering of synthetic lytic systems with predictable behavior. Results Here, a BioBrick™ lysis device present in the Registry of Standard Biological Parts has been quantitatively characterized. Its activity has been measured in E. coli by assembling the device under the control of a well characterized N-3-oxohexanoyl-L-homoserine lactone (HSL) -inducible promoter and the transfer function, lysis dynamics, protein release capability and genotypic and phenotypic stability of the device have been evaluated. Finally, its modularity was tested by assembling the device to a different inducible promoter, which can be triggered by heat induction. Conclusions The studied device is suitable for recombinant protein release as 96% of the total amount of the intracellular proteins was successfully released into the medium. Furthermore, it has been shown that the device can be assembled to different input devices to trigger cell lysis in response to a user-defined signal. For this reason, this lysis device can be a useful tool for the rational design and construction of complex synthetic biological systems composed by biological parts with known and well characterized function. Conversely, the onset of mutants makes this device unsuitable for the programmed cell death of a bacterial population.

Published

2011

2. Re-using biological devices: a model-aided analysis of interconnected transcriptional cascades designed from the bottom-up

Author

Pasotti, Lorenzo, primary, Bellato, Massimo, additional, Casanova, Michela, additional, Zucca, Susanna, additional, Cusella De Angelis, Maria Gabriella, additional, and Magni, Paolo, additional

Published

2017

3. Half-life measurements of chemical inducers for recombinant gene expression

Author

Politi, Nicolo’, primary, Pasotti, Lorenzo, additional, Zucca, Susanna, additional, Casanova, Michela, additional, Micoli, Giuseppina, additional, Cusella De Angelis, Maria Gabriella, additional, and Magni, Paolo, additional

Published

2014

4. A standard vector for the chromosomal integration and characterization of BioBrick™ parts in Escherichia coli

Author

Zucca, Susanna, primary, Pasotti, Lorenzo, additional, Politi, Nicolò, additional, Cusella De Angelis, Maria Gabriella, additional, and Magni, Paolo, additional

Published

2013

5. Characterization of a synthetic bacterial self-destruction device for programmed cell death and for recombinant proteins release

Author

Pasotti, Lorenzo, primary, Zucca, Susanna, additional, Lupotto, Manuel, additional, Cusella De Angelis, Maria Gabriella, additional, and Magni, Paolo, additional

Published

2011

6. Characterization of a synthetic bacterial selfdestruction device for programmed cell death and for recombinant proteins release.

Author

Pasotti, Lorenzo, Zucca, Susanna, Lupotto, Manuel, De Angelis, Maria Gabriella Cusella, and Magni, Paolo

Subjects

ESCHERICHIA coli, CELL death, CYSTATHIONINE gamma-lyase, LACTONES, FOODBORNE diseases

Abstract

Background: Bacterial cell lysis is a widely studied mechanism that can be achieved through the intracellular expression of phage native lytic proteins. This mechanism can be exploited for programmed cell death and for gentle cell disruption to release recombinant proteins when in vivo secretion is not feasible. Several genetic parts for cell lysis have been developed and their quantitative characterization is an essential step to enable the engineering of synthetic lytic systems with predictable behavior. Results: Here, a BioBrick™ lysis device present in the Registry of Standard Biological Parts has been quantitatively characterized. Its activity has been measured in E. coli by assembling the device under the control of a well characterized N-3-oxohexanoyl-L-homoserine lactone (HSL) -inducible promoter and the transfer function, lysis dynamics, protein release capability and genotypic and phenotypic stability of the device have been evaluated. Finally, its modularity was tested by assembling the device to a different inducible promoter, which can be triggered by heat induction. Conclusions: The studied device is suitable for recombinant protein release as 96% of the total amount of the intracellular proteins was successfully released into the medium. Furthermore, it has been shown that the device can be assembled to different input devices to trigger cell lysis in response to a user-defined signal. For this reason, this lysis device can be a useful tool for the rational design and construction of complex synthetic biological systems composed by biological parts with known and well characterized function. Conversely, the onset of mutants makes this device unsuitable for the programmed cell death of a bacterial population. [ABSTRACT FROM AUTHOR]

Published

2011