Your search keyword '"XlnR regulon"' showing total 3 results

1. Quantitative modeling and analytic assessment of the transcription dynamics of the XlnR regulon in Aspergillus niger.

Author

Omony, Jimmy, Mach-Aigner, Astrid R., van Straten, Gerrit, and van Boxtel, Anton J. B.

Subjects

*DYNAMIC models, *PARAMETER estimation, *REGULONS, *ASPERGILLUS niger, *MONOSACCHARIDES

Abstract

Background: Transcription of genes coding for xylanolytic and cellulolytic enzymes in Aspergillus niger is controlled by the transactivator XlnR. In this work we analyse and model the transcription dynamics in the XlnR regulon from time-course data of the messenger RNA levels for some XlnR target genes, obtained by reverse transcription quantitative PCR (RT-qPCR). Induction of transcription was achieved using low (1 mM) and high (50 mM) concentrations of D-xylose (Xyl). We investigated the wild type strain (Wt) and a mutant strain with partial loss-of-function of the carbon catabolite repressor CreA (Mt). Results: An improved kinetic differential equation model based on two antagonistic Hill functions was proposed, and fitted to the time-course RT-qPCR data from the Wt and the Mt by numerical optimization of the parameters. We show that perturbing the XlnR regulon with Xyl in low and high concentrations results in different expression levels and transcription dynamics of the target genes. At least four distinct transcription profiles were observed, particularly for the usage of 50 mM Xyl. Higher transcript levels were observed for some genes after induction with 1 mM rather than 50 mM Xyl, especially in the Mt. Grouping the expression profiles of the investigated genes has improved our understanding of induction by Xyl and the according regulatory role of CreA. Conclusions: The model explains for the higher expression levels at 1 mM versus 50 mM in both Wt and Mt. It does not yet fully encapsulate the effect of partial loss-of-function of CreA in the Mt. Themodel describes the dynamics in most of the data and elucidates the time-dynamics of the two major regulatory mechanisms: i) the activation by XlnR, and ii) the carbon catabolite repression by CreA. [ABSTRACT FROM AUTHOR]

Published

2016

2. Evaluation of Design Strategies for Time Course Experiments in Genetic Networks: Case Study of the XlnR Regulon in Aspergillus niger.

Author

Omony, Jimmy, Mach-Aigner, Astrid R., de Graaff, Leo H., van Straten, Gerrit, and van Boxtel, Anton J.B.

Abstract

One of the challenges in genetic network reconstruction is finding experimental designs that maximize the information content in a data set. In this paper, the information value of mRNA transcription time course experiments was used to compare experimental designs. The study concerns the dynamic response of genes in the XlnR regulon of Aspergillus niger, with the goal to find the best moment in time to administer an extra pulse of inducing D-xylose. Low and high D-xylose pulses were used to perturb the XlnR regulon. Evaluation of the experimental methods was based on simulation of the regulon. Models that govern the regulation of the target genes in this regulon were used for the simulations. Parameter sensitivity analysis, the Fisher Information Matrix (FIM) and the modified E-criterion were used to assess the design performances. The results show that the best time to give a second D-xylose pulse is when the D-xylose concentration from the first pulse has not yet completely faded away. Due to the presence of a repression effect the strength of the second pulse must be optimized, rather than maximized. The results suggest that the modified E-criterion is a better metric than the sum of integrals of absolute sensitivity for comparing alternative designs. [ABSTRACT FROM PUBLISHER]

Published

2012

3. Evaluation of design strategies for time course experiments in genetic networks: the XlnR regulon in Aspergillus niger

Author

Gerrit van Straten, Leo H. de Graaff, Anton J.B. van Boxtel, Jimmy Omony, and Astrid R. Mach-Aigner

Subjects

experimental design, Rank (linear algebra), trigger experiments, Microbiology, symbols.namesake, Control theory, Microbiologie, time course data, Sensitivity (control systems), Fisher information, Simulation, Mathematics, VLAG, Pulse (signal processing), Estimation theory, Design of experiments, genetic network, Leerstoelgroep Meet-, regel- en systeemtechniek, XlnR regulon, Moment (mathematics), Regulon, Systems and Control Group, regel- en systeemtechniek, symbols, A. niger, parameter estimation, Leerstoelgroep Meet

Abstract

One of the challenges in the reconstruction of genetic network is to find experimental designs that maximize the information content in the data. In this work the information value of time course experiments (TCEs) is used to rank experimental designs. The study concerns the dynamic response of genes in the XlnR regulon of Aspergillus niger, whereby it was the goal to find the best moment to administer an extra pulse of inducing D-xylose. Low and high trigger concentrations are considered. The models that govern the regulation of the target genes in this regulon are used for simulation. Parameter sensitivity analysis, Fisher Information Matrix (FIM) and the E-modified criterion are used for the design performance assessment. The results show that the best time to give a second pulse of a low concentration trigger of D-xylose is when the D-xylose concentration from the first pulse is not yet completed reduced. Secondly, pulses with high trigger concentrations were simulated, parameter sensitivities computed, and the experimental designs evaluated. Overall, after the first pulse of 1 mM D-xylose, using a second pulse of 5 (or 10) mM D-xylose yields the best experimental design - leading to improved parameter estimates.

Published

2011