Your search keyword '"Ala Trusina"' showing total 3 results

1. Modeling the NF-κB mediated inflammatory response predicts cytokine waves in tissue

Author

Benedicte Mengel, Ala Trusina, Sandeep Krishna, Pernille Yde, and Mogens H. Jensen

Subjects

medicine.medical_treatment, Systems biology, Inflammation, Models, Biological, chemistry.chemical_compound, Recurrence, Structural Biology, Modelling and Simulation, medicine, lcsh:QH301-705.5, Molecular Biology, Feedback, Physiological, biology, Applied Mathematics, NF-kappa B, Chemotaxis, NF-κB, biology.organism_classification, NFKB1, Dictyostelium, Computer Science Applications, Cell biology, Cytokine, lcsh:Biology (General), chemistry, Modeling and Simulation, Acute Disease, Chronic Disease, Immunology, Cytokines, Signal transduction, medicine.symptom, Research Article, Half-Life, Signal Transduction

Abstract

Background Waves propagating in "excitable media" is a reliable way to transmit signals in space. A fascinating example where living cells comprise such a medium is Dictyostelium D. which propagates waves of chemoattractant to attract distant cells. While neutrophils chemotax in a similar fashion as Dictyostelium D., it is unclear if chemoattractant waves exist in mammalian tissues and what mechanisms could propagate them. Results We propose that chemoattractant cytokine waves may naturally develop as a result of NF-κ B response. Using a heuristic mathematical model of NF-κ B-like circuits coupled in space we show that the known characteristics of NF-κ B response favor cytokine waves. Conclusions While the propagating wave of cytokines is generally beneficial for inflammation resolution, our model predicts that there exist special conditions that can cause chronic inflammation and re-occurrence of acute inflammatory response.

Published

2011

2. Stress induced telomere shortening: longer life with less mutations?

Author

Ala Trusina

Subjects

*TELOMERES, *GENETIC mutation, *DNA damage, *DNA repair, *APOPTOSIS, *CELLULAR aging

Abstract

Background Mutations accumulate as a result of DNA damage and imperfect DNA repair machinery. In higher eukaryotes the accumulation and spread of mutations is limited in two primary ways: through p53-mediated programmed cell death and cellular senescence mediated by telomeres. Telomeres shorten at every cell division and cell stops dividing once the shortest telomere reaches a critical length. It has been shown that the rate of telomere attrition is accelerated when cells are exposed to DNA damaging agents. However the implications of this mechanism are not fully understood. Results With the help of in silico model we investigate the effect of genotoxic stress on telomere attrition and apoptosis in a population of non-identical replicating cells. When comparing the populations of cells with constant vs. stress-induced rate of telomere shortening we find that stress induced telomere shortening (SITS) increases longevity while reducing mutation rate. Interestingly, however, the effect takes place only when genotoxic stresses (e.g. reactive oxygen species due to metabolic activity) are distributed non-equally among cells. Conclusions Our results for the first time show how non-equal distribution of metabolic load (and associated genotoxic stresses) combined with stress induced telomere shortening can delay aging and minimize mutations. [ABSTRACT FROM AUTHOR]

Published

2014

3. Stress induced telomere shortening: longer life with less mutations?

Author

Ala Trusina

Subjects

Programmed cell death, Mutation rate, Cell division, DNA damage, DNA repair, Population, Longevity, Genotoxic Stress, Biology, Telomere shortening, Mathematical model, Mutation Rate, Structural Biology, Genotoxic stress, Modelling and Simulation, education, Molecular Biology, Telomere Shortening, Genetics, education.field_of_study, Models, Genetic, Applied Mathematics, Computer Science Applications, Cell biology, Telomere, Reactive Oxygen Species (ROS), Modeling and Simulation, Cell-to-cell heterogeneity, DNA Damage, Research Article

Abstract

Background Mutations accumulate as a result of DNA damage and imperfect DNA repair machinery. In higher eukaryotes the accumulation and spread of mutations is limited in two primary ways: through p53-mediated programmed cell death and cellular senescence mediated by telomeres. Telomeres shorten at every cell division and cell stops dividing once the shortest telomere reaches a critical length. It has been shown that the rate of telomere attrition is accelerated when cells are exposed to DNA damaging agents. However the implications of this mechanism are not fully understood. Results With the help of in silico model we investigate the effect of genotoxic stress on telomere attrition and apoptosis in a population of non-identical replicating cells. When comparing the populations of cells with constant vs. stress-induced rate of telomere shortening we find that stress induced telomere shortening (SITS) increases longevity while reducing mutation rate. Interestingly, however, the effect takes place only when genotoxic stresses (e.g. reactive oxygen species due to metabolic activity) are distributed non-equally among cells. Conclusions Our results for the first time show how non-equal distribution of metabolic load (and associated genotoxic stresses) combined with stress induced telomere shortening can delay aging and minimize mutations.