Your search keyword '"Ramkrishna, Doraiswami"' showing total 4 results

1. Role of Intracellular Stochasticity in Biofilm Growth. Insights from Population Balance Modeling.

Author

Shu, Che-Chi, Chatterjee, Anushree, Hu, Wei-Shou, and Ramkrishna, Doraiswami

Subjects

STOCHASTIC analysis, BIOFILMS, GENETIC regulation, STREPTOCOCCACEAE, ENTEROCOCCUS, GENE expression

Abstract

There is increasing recognition that stochasticity involved in gene regulatory processes may help cells enhance the signal or synchronize expression for a group of genes. Thus the validity of the traditional deterministic approach to modeling the foregoing processes cannot be without exception. In this study, we identify a frequently encountered situation, i.e., the biofilm, which has in the past been persistently investigated with intracellular deterministic models in the literature. We show in this paper circumstances in which use of the intracellular deterministic model appears distinctly inappropriate. In Enterococcus faecalis, the horizontal gene transfer of plasmid spreads drug resistance. The induction of conjugation in planktonic and biofilm circumstances is examined here with stochastic as well as deterministic models. The stochastic model is formulated with the Chemical Master Equation (CME) for planktonic cells and Reaction-Diffusion Master Equation (RDME) for biofilm. The results show that although the deterministic model works well for the perfectly-mixed planktonic circumstance, it fails to predict the averaged behavior in the biofilm, a behavior that has come to be known as stochastic focusing. A notable finding from this work is that the interception of antagonistic feedback loops to signaling, accentuates stochastic focusing. Moreover, interestingly, increasing particle number of a control variable could lead to an even larger deviation. Intracellular stochasticity plays an important role in biofilm and we surmise by implications from the model, that cell populations may use it to minimize the influence from environmental fluctuation. [ABSTRACT FROM AUTHOR]

Published

2013

2. Bistability versus Bimodal Distributions in Gene Regulatory Processes from Population Balance.

Author

Che-Chi Shu, Chatterjee, Anushree, Dunny, Gary, Wei-Shou Hu, and Ramkrishna, Doraiswami

Subjects

STOCHASTIC approximation, GENETIC regulation, GENETICS, MATHEMATICAL models, FOKKER-Planck equation, INFORMATION modeling

Abstract

In recent times, stochastic treatments of gene regulatory processes have appeared in the literature in which a cell exposed to a signaling molecule in its environment triggers the synthesis of a specific protein through a network of intracellular reactions. The stochastic nature of this process leads to a distribution of protein levels in a population of cells as determined by a Fokker-Planck equation. Often instability occurs as a consequence of two (stable) steady state protein levels, one at the low end representing the "off" state, and the other at the high end representing the "on" state for a given concentration of the signaling molecule within a suitable range. A consequence of such bistability has been the appearance of bimodal distributions indicating two different populations, one in the "off" state and the other in the "on" state. The bimodal distribution can come about from stochastic analysis of a single cell. However, the concerted action of the population altering the extracellular concentration in the environment of individual cells and hence their behavior can only be accomplished by an appropriate population balance model which accounts for the reciprocal effects of interaction between the population and its environment. In this study, we show how to formulate a population balance model in which stochastic gene expression in individual cells is incorporated. Interestingly, the simulation of the model shows that bistability is neither sufficient nor necessary for bimodal distributions in a population. The original notion of linking bistability with bimodal distribution from single cell stochastic model is therefore only a special consequence of a population balance model. [ABSTRACT FROM AUTHOR]

Published

2011

3. Convergent transcription confers a bistable switch in Enterococcus faecalis conjugation.

Author

Chatterjee, Anushree, Johnson, Christopher M., Che-Chi Shu, Kaznessis, Yiannis N., Ramkrishna, Doraiswami, Dunny, Gary M., and Wei-Shou Hu

Subjects

ENTEROCOCCUS faecalis, GENES, GENOMES, GENETIC regulation, RNA polymerases, GENE expression

Abstract

Convergent gene pairs with head-to-head configurations are widespread in both eukaryotic and prokaryotic genomes and are speculated to be involved in gene regulation. Here we present a unique mechanism of gene regulation due to convergent transcription from the antagonistic prgX/prgQ operon in Enterococcus faecalis controlling conjugative transfer of the antibiotic resistance plasmid pCF10 from donor cells to recipient cells. Using mathematical modeling and experimentation, we demonstrate that convergent transcription in the prgX/prgQ operon endows the system with the properties of a robust genetic switch through premature termination of elongating transcripts due to collisions between RNA polymerases (RNAPs) transcribing from opposite directions and antisense regulation between complementary counter-transcripts. Evidence is provided for the presence of truncated RNAs resulting from convergent transcription from both the promoters that are capable of sense-antisense interactions. A mathematical model predicts that both RNAP collision and antisense regulation are essential for a robust bistable switch behavior in the control of conjugation initiation by prgX/prgQ operons. Moreover, given that convergent transcription is conserved across species, the mechanism of coupling RNAP collision and antisense interaction is likely to have a significant regulatory role in gene expression. [ABSTRACT FROM AUTHOR]

Published

2011

4. Modeling of gene regulatory processes by population-mediated signaling: New applications of population balances

Author

Shu, Che-Chi, Chatterjee, Anushree, Hu, Wei-Shou, and Ramkrishna, Doraiswami

Subjects

*GENETIC models, *CELL populations, *GENETIC regulation, *STOCHASTIC differential equations, *BACTERIAL cells, *DRUG resistance

Abstract

Abstract: Population balance modeling is considered for cell populations in gene regulatory processes in which one or more intracellular variables undergo stochastic dynamics as determined by Ito stochastic differential equations. This paper addresses formulation and computational issues with sample applications to the spread of drug resistance among bacterial cells. It is shown that predictions from population balances can display qualitative differences from those made with single cell models which are usually encountered in the literature. Such differences are deemed to be important. [Copyright &y& Elsevier]

Published

2012