%0 Journal Article %1 rateitschak_intracellular_2007 %A Rateitschak, Katja %A Wolkenhauer, Olaf %D 2007 %J Mathematical Biosciences %K Algorithms, Animals, B, Basic Chemokines, Expression Factors, Feedback, Gene Genetic, Homeodomain Humans, Messenger, Models, Periodicity, Phosphorylation, Physiological, Protein Proteins, Regulation, Repressor Rostock SBI Suppressor Time Transcription Transcription, Tumor p53 {CXC,} {Helix-Loop-Helix} {NF-kappa} {RNA,} %N 2 %P 163--179 %R 10.1016/j.mbs.2006.08.010 %T Intracellular delay limits cyclic changes in gene expression %U http://www.ncbi.nlm.nih.gov/pubmed/17027040 %V 205 %X Based on previously published experimental observations and mathematical models for Hes1, p53 and NF-kappaB gene expression, we improve these models through a distributed delay formulation of the time lag between transcription factor binding and mRNA production. This description of natural variability for delays introduces a transition from a stable steady state to limit cycle oscillations and then a second transition back to a stable steady state which has not been observed in previously published models. We demonstrate our approach for two models. The first model describes Hes1 autorepression with equations for Hes1 mRNA production and Hes1 protein translation. The second model describes Hes1 repression by the protein complex Gro/TLE1/Hes1, where Gro/TLE1 is activated by Hes1 phosphorylation. Finally, we discuss our analytical and numerical results in relation to experimental data.

@article{rateitschak_intracellular_2007, abstract = {Based on previously published experimental observations and mathematical models for Hes1, p53 and {NF-kappaB} gene expression, we improve these models through a distributed delay formulation of the time lag between transcription factor binding and {mRNA} production. This description of natural variability for delays introduces a transition from a stable steady state to limit cycle oscillations and then a second transition back to a stable steady state which has not been observed in previously published models. We demonstrate our approach for two models. The first model describes Hes1 autorepression with equations for Hes1 {mRNA} production and Hes1 protein translation. The second model describes Hes1 repression by the protein complex {Gro/TLE1/Hes1,} where {Gro/TLE1} is activated by Hes1 phosphorylation. Finally, we discuss our analytical and numerical results in relation to experimental data.}, added-at = {2010-09-17T16:55:15.000+0200}, author = {Rateitschak, Katja and Wolkenhauer, Olaf}, biburl = {https://www.bibsonomy.org/bibtex/2e4f69c2db4551bbd6202b9cbe01a2fb6/ra1602}, doi = {10.1016/j.mbs.2006.08.010}, interhash = {d01bd1f45024471eccfa8b29c9bc9999}, intrahash = {e4f69c2db4551bbd6202b9cbe01a2fb6}, issn = {0025-5564}, journal = {Mathematical Biosciences}, keywords = {Algorithms, Animals, B, Basic Chemokines, Expression Factors, Feedback, Gene Genetic, Homeodomain Humans, Messenger, Models, Periodicity, Phosphorylation, Physiological, Protein Proteins, Regulation, Repressor Rostock SBI Suppressor Time Transcription Transcription, Tumor p53 {CXC,} {Helix-Loop-Helix} {NF-kappa} {RNA,}}, month = feb, note = {{PMID:} 17027040}, number = 2, pages = {163--179}, timestamp = {2010-09-17T16:55:23.000+0200}, title = {Intracellular delay limits cyclic changes in gene expression}, url = {http://www.ncbi.nlm.nih.gov/pubmed/17027040}, volume = 205, year = 2007 }