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Cell Cycle Volume 12, 2013 - Issue 19
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Measurement and modeling of transcriptional noise in the cell cycle regulatory network

David Ball Virginia Bioinformatics Institute; Virginia Tech; Blacksburg, VA USA
,
Neil Adames Virginia Bioinformatics Institute; Virginia Tech; Blacksburg, VA USA
,
Nadine Reischmann Virginia Bioinformatics Institute; Virginia Tech; Blacksburg, VA USA
,
Debashis Barik Department of Biological Sciences; Virginia Tech; Blacksburg, VA USA
,
Christopher Franck Virginia Bioinformatics Institute; Virginia Tech; Blacksburg, VA USA; Department of Statistics; Virginia Tech; Blacksburg, VA USA
,
John J. Tyson Virginia Bioinformatics Institute; Virginia Tech; Blacksburg, VA USA; Department of Biological Sciences; Virginia Tech; Blacksburg, VA USA
&
Jean Peccoud Virginia Bioinformatics Institute; Virginia Tech; Blacksburg, VA USA; ICTAS Center for Systems Biology of Engineered Tissues; Virginia Tech; Blacksburg, VA USACorrespondence[email protected]
 show all
Pages 3392-3407 | Received 25 Apr 2013, Accepted 23 Aug 2013, Published online: 04 Sep 2013
 
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Abstract

Fifty years of genetic and molecular experiments have revealed a wealth of molecular interactions involved in the control of cell division. In light of the complexity of this control system, mathematical modeling has proved useful in analyzing biochemical hypotheses that can be tested experimentally. Stochastic modeling has been especially useful in understanding the intrinsic variability of cell cycle events, but stochastic modeling has been hampered by a lack of reliable data on the absolute numbers of mRNA molecules per cell for cell cycle control genes. To fill this void, we used fluorescence in situ hybridization (FISH) to collect single molecule mRNA data for 16 cell cycle regulators in budding yeast, Saccharomyces cerevisiae. From statistical distributions of single-cell mRNA counts, we are able to extract the periodicity, timing, and magnitude of transcript abundance during the cell cycle. We used these parameters to improve a stochastic model of the cell cycle to better reflect the variability of molecular and phenotypic data on cell cycle progression in budding yeast.

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