Your search keyword '"Finkenstädt, Bärbel"' showing total 5 results

1. QUANTIFYING INTRINSIC AND EXTRINSIC NOISE IN GENE TRANSCRIPTION USING THE LINEAR NOISE APPROXIMATION: AN APPLICATION TO SINGLE CELL DATA

Author

Finkenstädt, Bärbel, Woodcock, Dan J., Komorowski, Michal, Harper, Claire V., Davis, Julian R. E., White, Mike R. H., and Rand, David A.

Published

2013

2. Disentangling juxtacrine from paracrine signalling in dynamic tissue.

Author

Momiji, Hiroshi, Hassall, Kirsty L., Featherstone, Karen, McNamara, Anne V., Patist, Amanda L., Spiller, David G., Christian, Helen C., White, Michael R. H., Davis, Julian R. E., Finkenstädt, Bärbel F., and Rand, David A.

Subjects

PROLACTIN, PITUITARY gland, PEPTIDE hormones, GENE expression, PHYSICAL sciences, CYTOLOGY, TIME series analysis

Abstract

Prolactin is a major hormone product of the pituitary gland, the central endocrine regulator. Despite its physiological importance, the cell-level mechanisms of prolactin production are not well understood. Having significantly improved the resolution of real-time-single-cell-GFP-imaging, the authors recently revealed that prolactin gene transcription is highly dynamic and stochastic yet shows space-time coordination in an intact tissue slice. However, it still remains an open question as to what kind of cellular communication mediates the observed space-time organization. To determine the type of interaction between cells we developed a statistical model. The degree of similarity between two expression time series was studied in terms of two distance measures, Euclidean and geodesic, the latter being a network-theoretic distance defined to be the minimal number of edges between nodes, and this was used to discriminate between juxtacrine from paracrine signalling. The analysis presented here suggests that juxtacrine signalling dominates. To further determine whether the coupling is coordinating transcription or post-transcriptional activities we used stochastic switch modelling to infer the transcriptional profiles of cells and estimated their similarity measures to deduce that their spatial cellular coordination involves coupling of transcription via juxtacrine signalling. We developed a computational model that involves an inter-cell juxtacrine coupling, yielding simulation results that show space-time coordination in the transcription level that is in agreement with the above analysis. The developed model is expected to serve as the prototype for the further study of tissue-level organised gene expression for epigenetically regulated genes, such as prolactin. [ABSTRACT FROM AUTHOR]

Published

2019

3. A hierarchical model of transcriptional dynamics allows robust estimation of transcription rates in populations of single cells with variable gene copy number.

Author

Woodcock, Dan J., Vance, Keith W., Komorowski, Michał, Koentges, Georgy, Finkenstädt, Bärbel, and Rand, David A.

Subjects

CELL populations, NUCLEOTIDE sequence, GENE expression, MESSENGER RNA, PROMOTERS (Genetics), BAYESIAN analysis

Abstract

Motivation: cis-regulatory DNA sequence elements, such as enhancers and silencers, function to control the spatial and temporal expression of their target genes. Although the overall levels of gene expression in large cell populations seem to be precisely controlled, transcription of individual genes in single cells is extremely variable in real time. It is, therefore, important to understand how these cis-regulatory elements function to dynamically control transcription at single-cell resolution. Recently, statistical methods have been proposed to back calculate the rates involved in mRNA transcription using parameter estimation of a mathematical model of transcription and translation. However, a major complication in these approaches is that some of the parameters, particularly those corresponding to the gene copy number and transcription rate, cannot be distinguished; therefore, these methods cannot be used when the copy number is unknown.Results: Here, we develop a hierarchical Bayesian model to estimate biokinetic parameters from live cell enhancer–promoter reporter measurements performed on a population of single cells. This allows us to investigate transcriptional dynamics when the copy number is variable across the population. We validate our method using synthetic data and then apply it to quantify the function of two known developmental enhancers in real time and in single cells.Availability: Supporting information is submitted with the article.Contact: d.j.woodcock@warwick.ac.ukSupplementary information: Supplementary data are available at Bioinformatics online. [ABSTRACT FROM PUBLISHER]

Published

2013

4. A temporal switch model for estimating transcriptional activity in gene expression.

Author

Jenkins, Dafyd J., Finkenstädt, Bärbel, and Rand, David A.

Subjects

*GENETIC transcription, *GENE expression, *TIME series analysis, *MICROARRAY technology, *POLYMERASE chain reaction, *NUCLEOTIDE sequence, *MESSENGER RNA

Abstract

Motivation: The analysis and mechanistic modelling of time series gene expression data provided by techniques such as microarrays, NanoString, reverse transcription–polymerase chain reaction and advanced sequencing are invaluable for developing an understanding of the variation in key biological processes. We address this by proposing the estimation of a flexible dynamic model, which decouples temporal synthesis and degradation of mRNA and, hence, allows for transcriptional activity to switch between different states.Results: The model is flexible enough to capture a variety of observed transcriptional dynamics, including oscillatory behaviour, in a way that is compatible with the demands imposed by the quality, time-resolution and quantity of the data. We show that the timing and number of switch events in transcriptional activity can be estimated alongside individual gene mRNA stability with the help of a Bayesian reversible jump Markov chain Monte Carlo algorithm. To demonstrate the methodology, we focus on modelling the wild-type behaviour of a selection of 200 circadian genes of the model plant Arabidopsis thaliana. The results support the idea that using a mechanistic model to identify transcriptional switch points is likely to strongly contribute to efforts in elucidating and understanding key biological processes, such as transcription and degradation.Contact: B.F.Finkenstadt@Warwick.ac.ukSupplementary information: Supplementary data are available at Bioinformatics online. [ABSTRACT FROM AUTHOR]

Published

2013

5. Bayesian inference on stochastic gene transcription from flow cytometry data.

Author

Tiberi, Simone, Walsh, Mark, Cavallaro, Massimo, Hebenstreit, Daniel, and Finkenstädt, Bärbel

Subjects

BAYESIAN analysis, MESSENGER RNA, GENETIC transcription, FLOW cytometry, MOLECULAR dynamics

Abstract

Motivation Transcription in single cells is an inherently stochastic process as mRNA levels vary greatly between cells, even for genetically identical cells under the same experimental and environmental conditions. We present a stochastic two-state switch model for the population of mRNA molecules in single cells where genes stochastically alternate between a more active ON state and a less active OFF state. We prove that the stationary solution of such a model can be written as a mixture of a Poisson and a Poisson-beta probability distribution. This finding facilitates inference for single cell expression data, observed at a single time point, from flow cytometry experiments such as FACS or fluorescence in situ hybridization (FISH) as it allows one to sample directly from the equilibrium distribution of the mRNA population. We hence propose a Bayesian inferential methodology using a pseudo-marginal approach and a recent approximation to integrate over unobserved states associated with measurement error. Results We provide a general inferential framework which can be widely used to study transcription in single cells from the kind of data arising in flow cytometry experiments. The approach allows us to separate between the intrinsic stochasticity of the molecular dynamics and the measurement noise. The methodology is tested in simulation studies and results are obtained for experimental multiple single cell expression data from FISH flow cytometry experiments. Availability and implementation All analyses were implemented in R. Source code and the experimental data are available at https://github.com/SimoneTiberi/Bayesian-inference-on-stochastic-gene-transcription-from-flow-cytometry-data. Supplementary information Supplementary data are available at Bioinformatics online. [ABSTRACT FROM AUTHOR]

Published

2018