Your search keyword '"Stephan Y"' showing total 7 results

1. Metabolic cycling in single yeast cells from unsynchronized steady-state populations limited on glucose or phosphate

Author

Silverman, Sanford J., Petti, Allegra A., Slavov, Nikolai, Parsons, Lance, Briehof, Ryan, Thiberge, Stephan Y., Zenklusen, Daniel, Gandhi, Saumil J., Larson, Daniel R., Singer, Robert H., and Botstein, David

Subjects

Dextrose -- Physiological aspects, Glucose -- Physiological aspects, Phosphates -- Physiological aspects, Yeast fungi -- Physiological aspects, Yeast fungi -- Genetic aspects, Cell cycle -- Research, Science and technology

Abstract

Oscillations in patterns of expression of a large fraction of yeast genes are associated with the 'metabolic cycle,' usually seen only in prestarved, continuous cultures of yeast. We used FISH of mRNA in individual cells to test the hypothesis that these oscillations happen m single cells drawn from unsynchronized cultures growing exponentially in chemostats. Gene-expression data from synchronized cultures were used to predict coincident appearance of mRNAs from pairs of genes in the unsynchronized cells. Quantitative analysis of the FISH results shows that individual unsynchronized cells growing slowly because of glucose limitation or phosphate limitation show the predicted oscillations. We conclude that the yeast metabolic cycle is an intrinsic property of yeast metabolism and does not depend on either synchronization or external limitation of growth by the carbon source. chemostat | fluorescence in situ hybridization | mRNA | single cells doi/ 10.1073/pnas.1002422107

Published

2010

2. Correction for Silverman et al., Metabolic cycling in single yeast cells from unsynchronized steady-state populations limited on glucose or phosphate

Author

Nikolai Slavov, Saumil J. Gandhi, David Botstein, Lance Parsons, Ryan Briehof, Allegra A. Petti, Daniel R. Larson, Robert H. Singer, Sanford J. Silverman, Daniel Zenklusen, and Stephan Y. Thiberge

Subjects

chemistry.chemical_compound, Multidisciplinary, Biochemistry, chemistry, Steady state (chemistry), Biology, Cycling, Phosphate, Corrections, Yeast

Published

2011

3. Spatiotemporal control of gene expression with pulse-generating networks

Author

Stephan Y. Thiberge, Rishabh Mehreja, Ming Tang Chen, Subhayu Basu, and Ron Weiss

Subjects

Regulation of gene expression, Multidisciplinary, Pulse generator, Feed forward, Biology, Biological Sciences, Green fluorescent protein, Cell biology, Synthetic biology, Biochemistry, Gene Expression Regulation, Gene expression, Inducer, Cell-cell signaling

Abstract

One of the important challenges in the emerging field of synthetic biology is designing artificial networks that achieve coordinated behavior in cell communities. Here we present a synthetic multicellular bacterial system where receiver cells exhibit transient gene expression in response to a long-lasting signal from neighboring sender cells. The engineered sender cells synthesize an inducer, an acyl-homoserine lactone (AHL), which freely diffuses to spatially proximate receiver cells. The receiver cells contain a pulse-generator circuit that incorporates a feed-forward regulatory motif. The circuit responds to a long-lasting increase in the level of AHL by transiently activating, and then repressing, the expression of a GFP. Based on simulation models, we engineered variants of the pulse-generator circuit that exhibit different quantitative responses such as increased duration and intensity of the pulse. As shown by our models and experiments, the maximum amplitude and timing of the pulse depend not only on the final inducer concentration, but also on its rate of increase. The ability to differentiate between various rates of increase in inducer concentrations affords the system a unique spatiotemporal behavior for cells grown on solid media. Specifically, receiver cells can respond to communication from nearby sender cells while completely ignoring communication from senders cells further away, despite the fact that AHL concentrations eventually reach high levels everywhere. Because of the resemblance to naturally occurring feed-forward motifs, the pulse generator can serve as a model to improve our understanding of such systems.

Published

2004

4. Volume conservation principle involved in cell lengthening and nucleus movement during tissue morphogenesis

Author

Massachusetts Institute of Technology. Department of Biology, Martin, Adam C., Gelbart, Michael A., He, Bing, Thiberge, Stephan Y., Wieschaus, Eric F., Kaschube, Matthias, Martin, Adam C, Massachusetts Institute of Technology. Department of Biology, Martin, Adam C., Gelbart, Michael A., He, Bing, Thiberge, Stephan Y., Wieschaus, Eric F., Kaschube, Matthias, and Martin, Adam C

Abstract

Tissue morphogenesis is the process in which coordinated movements and shape changes of large numbers of cells form tissues, organs, and the internal body structure. Understanding morphogenetic movements requires precise measurements of whole-cell shape changes over time. Tissue folding and invagination are thought to be facilitated by apical constriction, but the mechanism by which changes near the apical cell surface affect changes along the entire apical–basal axis of the cell remains elusive. Here, we developed Embryo Development Geometry Explorer, an approach for quantifying rapid whole-cell shape changes over time, and we combined it with deep-tissue time-lapse imaging based on fast two-photon microscopy to study Drosophila ventral furrow formation. We found that both the cell lengthening along the apical–basal axis and the movement of the nucleus to the basal side proceeded stepwise and were correlated with apical constriction. Moreover, cell volume lost apically due to constriction largely balanced the volume gained basally by cell lengthening. The volume above the nucleus was conserved during its basal movement. Both apical volume loss and cell lengthening were absent in mutants showing deficits in the contractile cytoskeleton underlying apical constriction. We conclude that a single mechanical mechanism involving volume conservation and apical constriction-induced basal movement of cytoplasm accounts quantitatively for the cell shape changes and the nucleus movement in Drosophila ventral furrow formation. Our study provides a comprehensive quantitative analysis of the fast dynamics of whole-cell shape changes during tissue folding and points to a simplified model for Drosophila gastrulation.

Published

2013

5. Remodeling nuclear architecture allows efficient transport of herpesvirus capsids by diffusion.

Author

Bosse, Jens B., Hogue, Ian B., Feric, Marina, Thiberge, Stephan Y., Sodeik, Beate, Brangwynne, Clifford P., and Enquist, Lynn W.

Subjects

CHROMATIN, MACROMOLECULES, HERPESVIRUS diseases, CAPSIDS, BATRACHOCHYTRIUM dendrobatidis

Abstract

The nuclear chromatin structure confines the movement of large macromolecular complexes to interchromatin corrals. Herpesvirus capsids of approximately 125 nm assemble in the nucleoplasm and must reach the nuclear membranes for egress. Previous studies concluded that nuclear herpesvirus capsid motility is active, directed, and based on nuclear filamentous actin, suggesting that large nuclear complexes need metabolic energy to escape nuclear entrapment. However, this hypothesis has recently been challenged. Commonly used microscopy techniques do not allow the imaging of rapid nuclear particle motility with sufficient spatiotemporal resolution. Here, we use a rotating, oblique light sheet, which we dubbed a ring-sheet, to image and track viral capsids with high temporal and spatial resolution. We do not find any evidence for directed transport. Instead, infection with different herpesviruses induced an enlargement of interchromatin domains and allowed particles to diffuse unrestricted over longer distances, thereby facilitating nuclear egress for a larger fraction of capsids. [ABSTRACT FROM AUTHOR]

Published

2015

6. Volume conservation principle involved in cell lengthening and nucleus movement during tissue morphogenesis.

Author

Gelbart, Michael A., Bing He, Martin, Adam C., Thiberge, Stephan Y., Wieschaus, Eric F., and Kaschube, Matthias

Subjects

CELL nuclei, CELL motility, TISSUES, MORPHOGENESIS, CYTOPLASM, CYTOSKELETON, CELL morphology

Abstract

Tissue morphogenesis is the process in which coordinated movements and shape changes of large numbers of cells form tissues, organs, and the internal body structure. Understanding morphogenetic movements requires precise measurements of whole-cell shape changes over time. Tissue folding and invagination are thought to be facilitated by apical constriction, but the mechanism by which changes near the apical cell surface affect changes along the entire apical-basal axis of the cell remains elusive. Here, we developed Embryo Development Geometry Explorer, an approach for quantifying rapid whole-cell shape changes over time, and we combined it with deep-tissue time-lapse imaging based on fast two-photon microscopy to study Drosophila ventral furrow formation. We found that both the cell lengthening along the apical-basal axis and the movement of the nucleus to the basal side proceeded stepwise and were correlated with apical constriction. Moreover, cell volume lost apically due to constriction largely balanced the volume gained basally by cell lengthening. The volume above the nucleus was conserved during its basal movement. Both apical volume loss and cell lengthening were absent in mutants showing deficits in the contractile cytoskeleton underlying apical constriction. We conclude that a single mechanical mechanism involving volume conservation and apical constriction-induced basal movement of cytoplasm accounts quantitatively for the cell shape changes and the nucleus movement in Drosophila ventral furrow formation. Our study provides a comprehensive quantitative analysis of the fast dynamics of whole-cell shape changes during tissue folding and points to a simplified model for Drosophila gastrulation. [ABSTRACT FROM AUTHOR]

Published

2012

7. In vivo imaging of alphaherpesvirus infection reveals synchronized activity dependent on axonal sorting of viral proteins.

Author

Granstedt, Andrea E., Bosse, Jens B., Thiberge, Stephan Y., and Enquist, Lynn W.

Subjects

AUJESZKY'S disease virus, AXONS, VIRAL proteins

Abstract

The article offers information on the study regarding the in vivo imaging of pseudorabies virus (PRV) infections by Andrea E. Grandstedt and colleagues which reveals that PRV causes synchronous neural activity that depends on axonal sorting of viral fusion protein.

Published

2013