Your search keyword '"Kasza KE"' showing total 4 results

1. Anisotropy links cell shapes to tissue flow during convergent extension.

Author

Wang X, Merkel M, Sutter LB, Erdemci-Tandogan G, Manning ML, and Kasza KE

Subjects

Animals, Anisotropy, Drosophila cytology, Drosophila genetics, Drosophila metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Epithelium metabolism, Myosin Type II genetics, Myosin Type II metabolism, Cell Shape, Drosophila growth & development

Abstract

Within developing embryos, tissues flow and reorganize dramatically on timescales as short as minutes. This includes epithelial tissues, which often narrow and elongate in convergent extension movements due to anisotropies in external forces or in internal cell-generated forces. However, the mechanisms that allow or prevent tissue reorganization, especially in the presence of strongly anisotropic forces, remain unclear. We study this question in the converging and extending Drosophila germband epithelium, which displays planar-polarized myosin II and experiences anisotropic forces from neighboring tissues. We show that, in contrast to isotropic tissues, cell shape alone is not sufficient to predict the onset of rapid cell rearrangement. From theoretical considerations and vertex model simulations, we predict that in anisotropic tissues, two experimentally accessible metrics of cell patterns-the cell shape index and a cell alignment index-are required to determine whether an anisotropic tissue is in a solid-like or fluid-like state. We show that changes in cell shape and alignment over time in the Drosophila germband predict the onset of rapid cell rearrangement in both wild-type and snail twist mutant embryos, where our theoretical prediction is further improved when we also account for cell packing disorder. These findings suggest that convergent extension is associated with a transition to more fluid-like tissue behavior, which may help accommodate tissue-shape changes during rapid developmental events., Competing Interests: The authors declare no competing interest.

Published

2020

2. Cellular defects resulting from disease-related myosin II mutations in Drosophila .

Author

Kasza KE, Supriyatno S, and Zallen JA

Subjects

Animals, Drosophila Proteins chemistry, Drosophila Proteins metabolism, Drosophila melanogaster, Epithelium growth & development, Epithelium metabolism, Membrane Proteins chemistry, Membrane Proteins metabolism, Myosin Heavy Chains chemistry, Myosin Heavy Chains metabolism, Protein Domains, Thrombocytopenia genetics, Drosophila Proteins genetics, Hearing Loss, Sensorineural genetics, Membrane Proteins genetics, Morphogenesis, Mutation, Missense, Myosin Heavy Chains genetics, Thrombocytopenia congenital

Abstract

The nonmuscle myosin II motor protein produces forces that are essential to driving the cell movements and cell shape changes that generate tissue structure. Mutations in myosin II that are associated with human diseases are predicted to disrupt critical aspects of myosin function, but the mechanisms that translate altered myosin activity into specific changes in tissue organization and physiology are not well understood. Here we use the Drosophila embryo to model human disease mutations that affect myosin motor activity. Using in vivo imaging and biophysical analysis, we show that engineering human MYH9 -related disease mutations into Drosophila myosin II produces motors with altered organization and dynamics that fail to drive rapid cell movements, resulting in defects in epithelial morphogenesis. In embryos that express the Drosophila myosin motor variants R707C or N98K and have reduced levels of wild-type myosin, myosin motors are correctly planar polarized and generate anisotropic contractile tension in the tissue. However, expression of these motor variants is associated with a cellular-scale reduction in the speed of cell intercalation, resulting in a failure to promote full elongation of the body axis. In addition, these myosin motor variants display slowed turnover and aberrant aggregation at the cell cortex, indicating that mutations in the motor domain influence mesoscale properties of myosin organization and dynamics. These results demonstrate that disease-associated mutations in the myosin II motor domain disrupt specific aspects of myosin localization and activity during cell intercalation, linking molecular changes in myosin activity to defects in tissue morphogenesis., Competing Interests: The authors declare no competing interest.

Published

2019

3. Cell volume change through water efflux impacts cell stiffness and stem cell fate.

Author

Guo M, Pegoraro AF, Mao A, Zhou EH, Arany PR, Han Y, Burnette DT, Jensen MH, Kasza KE, Moore JR, Mackintosh FC, Fredberg JJ, Mooney DJ, Lippincott-Schwartz J, and Weitz DA

Subjects

Animals, Cell Lineage, Cells, Cultured, Mesenchymal Stem Cells cytology, Mice, Mice, Inbred BALB C, Cell Differentiation, Cell Physiological Phenomena, Cell Size, Mesenchymal Stem Cells physiology, Water metabolism

Abstract

Cells alter their mechanical properties in response to their local microenvironment; this plays a role in determining cell function and can even influence stem cell fate. Here, we identify a robust and unified relationship between cell stiffness and cell volume. As a cell spreads on a substrate, its volume decreases, while its stiffness concomitantly increases. We find that both cortical and cytoplasmic cell stiffness scale with volume for numerous perturbations, including varying substrate stiffness, cell spread area, and external osmotic pressure. The reduction of cell volume is a result of water efflux, which leads to a corresponding increase in intracellular molecular crowding. Furthermore, we find that changes in cell volume, and hence stiffness, alter stem-cell differentiation, regardless of the method by which these are induced. These observations reveal a surprising, previously unidentified relationship between cell stiffness and cell volume that strongly influences cell biology., Competing Interests: The authors declare no conflict of interest.

Published

2017

4. Spatiotemporal control of epithelial remodeling by regulated myosin phosphorylation.

Author

Kasza KE, Farrell DL, and Zallen JA

Subjects

Actins metabolism, Amino Acid Substitution, Animals, Animals, Genetically Modified, Body Patterning physiology, Drosophila genetics, Drosophila Proteins genetics, Epithelium growth & development, Epithelium metabolism, Female, Male, Morphogenesis, Myosin Light Chains genetics, Myosin Type II genetics, Myosin Type II metabolism, Phosphorylation, Drosophila growth & development, Drosophila metabolism, Drosophila Proteins metabolism, Myosin Light Chains metabolism

Abstract

Spatiotemporally regulated actomyosin contractility generates the forces that drive epithelial cell rearrangements and tissue remodeling. Phosphorylation of the myosin II regulatory light chain (RLC) promotes the assembly of myosin monomers into active contractile filaments and is an essential mechanism regulating the level of myosin activity. However, the effects of phosphorylation on myosin localization, dynamics, and function during epithelial remodeling are not well understood. In Drosophila, planar polarized myosin contractility is required for oriented cell rearrangements during elongation of the body axis. We show that regulated myosin phosphorylation influences spatial and temporal properties of contractile behavior at molecular, cellular, and tissue length scales. Expression of myosin RLC variants that prevent or mimic phosphorylation both disrupt axis elongation, but have distinct effects at the molecular and cellular levels. Unphosphorylatable RLC produces fewer, slower cell rearrangements, whereas phosphomimetic RLC accelerates rearrangement and promotes higher-order cell interactions. Quantitative live imaging and biophysical approaches reveal that both phosphovariants reduce myosin planar polarity and mechanical anisotropy, altering the orientation of cell rearrangements during axis elongation. Moreover, the localized myosin activator Rho-kinase is required for spatially regulated myosin activity, even when the requirement for phosphorylation is bypassed by the expression of phosphomimetic myosin RLC. These results indicate that myosin phosphorylation influences both the level and the spatiotemporal regulation of myosin activity, linking molecular properties of myosin activity to tissue morphogenesis.

Published

2014