In organisms ranging from single-celled yeasts to mammals, genetically identical cells exhibit variable cell division cycle times even when growing in the same environment. The sources and benefits of variability in a process such as the cell cycle that is wired for accuracy are unknown. In particular, it is not understood whether cell cycle timing variability is purely stochastic or whether it may be regulated as part of the design of cell cycle circuits. Variability in other cell processes has been shown to be beneficial, so cell cycle variability may in fact be an adaptive trait. The multinucleate, filamentous fungus, Ashbya gossypii, is a unique model system to study cell cycle timing variability because nuclei divide asynchronously within a common cytoplasm. Such asynchrony in a syncytium requires variable timing and nuclear autonomy in cell cycle signaling. As all proteins are translated in a common cytoplasm, it is mysterious how multiple, out of sync, cell cycle oscillators can coexist. We are taking advantage of the asynchronous division cycle in this model system to discover whether variability is programmed into the cell cycle and to learn how nuclear autonomy can be established. Knowledge of the molecular basis for variability is necessary for a complete understanding of cell cycle control and the pathologies influenced by a misregulated cell cycle. Population level variability in cell cycle decisions can impact processes as diverse as fungal pathogenesis and tumor cell behavior, and may be a factor influencing the efficacy of pharmacological treatments. While some cell-to-cell variability can be attributed to molecular noise in transcription, it is certain that other, as yet unidentified, cellular reservoirs of non-genetic individuality exist. In this proposal, we combine live cell imaging with computational and molecular genetic approaches to identify sources of variability in the cell cycle and determine how nuclear autonomy is established. With this model fungal system, we are well positioned to identify conserved sources of cell cycle variability and learn how cell signaling processes can be insulated within a common cytoplasm.
The specific aims of the project are: 1) To determine whether variability in G1 duration is stochastic or regulated. 2) To test the hypothesis that nuclear size controls cell cycle timing and variability. 3) To test the hypothesis that spatially restricted protein movement creates nuclear autonomy. Timing variability exists in nearly all cell division cycles and knowing the basis of heterogeneity is essential for a complete understanding of the cell cycle. In this project, we will determine if timing variability is programmed in the cell division cycle, learn how nuclear size controls timing and how the cytoplasm can be functionally compartmentalized to maintain asynchrony.

Public Health Relevance

In organisms ranging from single-celled yeasts to mammals, genetically identical cells take different amounts of time to divide even when growing in the same environment. This cell-to-cell variability in division timing can impact processes as diverse as fungal pathogenesis and tumor cell growth, and may be a factor influencing the efficacy of pharmacological treatments. In this work we will identify molecular sources of timing variability that will have relevance to the diverse diseases influenced by a misregulated cell division cycle.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM081506-04
Application #
8500356
Study Section
Nuclear and Cytoplasmic Structure/Function and Dynamics Study Section (NCSD)
Program Officer
Hamlet, Michelle R
Project Start
2010-08-01
Project End
2015-07-31
Budget Start
2013-08-01
Budget End
2014-07-31
Support Year
4
Fiscal Year
2013
Total Cost
$269,807
Indirect Cost
$89,263
Name
Dartmouth College
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
041027822
City
Hanover
State
NH
Country
United States
Zip Code
03755
Fadero, Tanner C; Gerbich, Therese M; Rana, Kishan et al. (2018) LITE microscopy: Tilted light-sheet excitation of model organisms offers high resolution and low photobleaching. J Cell Biol 217:1869-1882
Langdon, Erin M; Qiu, Yupeng; Ghanbari Niaki, Amirhossein et al. (2018) mRNA structure determines specificity of a polyQ-driven phase separation. Science 360:922-927
Smith, Jean A; Gladfelter, Amy S (2017) Lessons from Yeast on How to Avoid Stress Eating. Dev Cell 43:3-5
Cannon, Kevin S; Woods, Benjamin L; Gladfelter, Amy S (2017) The Unsolved Problem of How Cells Sense Micron-Scale Curvature. Trends Biochem Sci 42:961-976
Gladfelter, Amy S; Peifer, Mark (2017) What your PI forgot to tell you: why you actually might want a job running a research lab. Mol Biol Cell 28:1724-1727
Dundon, Samantha E R; Chang, Shyr-Shea; Kumar, Abhishek et al. (2016) Clustered nuclei maintain autonomy and nucleocytoplasmic ratio control in a syncytium. Mol Biol Cell 27:2000-7
Lee, ChangHwan; Roberts, Samantha E; Gladfelter, Amy S (2016) Quantitative spatial analysis of transcripts in multinucleate cells using single-molecule FISH. Methods 98:124-133
Roberts, Samantha E; Gladfelter, Amy S (2015) Nuclear autonomy in multinucleate fungi. Curr Opin Microbiol 28:60-5
Roper, Marcus; Lee, ChangHwan; Hickey, Patrick C et al. (2015) Life as a moving fluid: fate of cytoplasmic macromolecules in dynamic fungal syncytia. Curr Opin Microbiol 26:116-22
Anderson, Cori A; Roberts, Samantha; Zhang, Huaiying et al. (2015) Ploidy variation in multinucleate cells changes under stress. Mol Biol Cell 26:1129-40

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