scholarly journals Uniaxial loading induces a scalable switch in cortical actomyosin flow polarization and reveals mechanosensitive regulation of cytokinesis

2019 ◽  
Author(s):  
Deepika Singh ◽  
Devang Odedra ◽  
Christian Pohl
Keyword(s):  
Cell Division ◽  
Stress Response ◽  
Mechanical Stress ◽  
Rotational Flow ◽  
Mechanical Forces ◽  
Longitudinal Flow ◽  
Contractile Ring ◽  
Animal Development ◽  
C Elegans ◽  
Cortical Fibers

AbstractDuring animal development, it is crucial that cells can sense and adapt to mechanical forces from their environment. Ultimately, these forces are transduced through the actomyosin cortex. How the cortex can simultaneously respond to and create forces during cytokinesis is not well understood. Here we show that under mechanical stress, cortical actomyosin flow switches its polarization during cytokinesis in the C. elegans embryo. In unstressed embryos, longitudinal cortical flows contribute to contractile ring formation, while rotational cortical flow is additionally induced in uniaxially loaded embryos. Rotational cortical flow is required for the redistribution of the actomyosin cortex in loaded embryos. Rupture of longitudinally aligned cortical fibers during cortex rotation releases tension, initiates orthogonal longitudinal flow and thereby contributes to furrowing in loaded embryos. A targeted screen for factors required for rotational flow revealed that actomyosin regulators involved in RhoA regulation, cortical polarity and chirality are all required for rotational flow and become essential for cytokinesis under mechanical stress. In sum, our findings extend the current framework of mechanical stress response during cell division and show scaling of orthogonal cortical flows to the amount of mechanical stress.

scholarly journals Mechanical stress compromises multicomponent efflux complexes in bacteria

2019 ◽  
Vol 116 (51) ◽  
pp. 25462-25467 ◽  
Author(s):  
Lauren A. Genova ◽  
Melanie F. Roberts ◽  
Yu-Chern Wong ◽  
Christine E. Harper ◽  
Ace George Santiago ◽  
...  
Keyword(s):  
Cell Division ◽  
Mechanical Stress ◽  
Single Molecule ◽  
Protein Complexes ◽  
Hydrostatic Stress ◽  
Cell Envelope ◽  
Mechanical Forces ◽  
Bacterial Survival ◽  
Physical Forces ◽  
Membrane Components

Physical forces have a profound effect on growth, morphology, locomotion, and survival of organisms. At the level of individual cells, the role of mechanical forces is well recognized in eukaryotic physiology, but much less is known about prokaryotic organisms. Recent findings suggest an effect of physical forces on bacterial shape, cell division, motility, virulence, and biofilm initiation, but it remains unclear how mechanical forces applied to a bacterium are translated at the molecular level. In Gram-negative bacteria, multicomponent protein complexes can form rigid links across the cell envelope and are therefore subject to physical forces experienced by the cell. Here we manipulate tensile and shear mechanical stress in the bacterial cell envelope and use single-molecule tracking to show that octahedral shear (but not hydrostatic) stress within the cell envelope promotes disassembly of the tripartite efflux complex CusCBA, a system used byEscherichia colito resist copper and silver toxicity. By promoting disassembly of this protein complex, mechanical forces within the cell envelope make the bacteria more susceptible to metal toxicity. These findings demonstrate that mechanical forces can inhibit the function of cell envelope protein assemblies in bacteria and suggest the possibility that other multicomponent, transenvelope efflux complexes may be sensitive to mechanical forces including complexes involved in antibiotic resistance, cell division, and translocation of outer membrane components. By modulating the function of proteins within the cell envelope, mechanical stress has the potential to regulate multiple processes required for bacterial survival and growth.

scholarly journals A cooperative network at the nuclear envelope counteracts LINC-mediated forces during oogenesis in C. elegans

2021 ◽  
Author(s):  
Chenshu Liu ◽  
Zoe Lung ◽  
John S Wang ◽  
Fan Wu ◽  
Abby F Dernburg
Keyword(s):  
Nuclear Envelope ◽  
Mechanical Stress ◽  
Oocyte Maturation ◽  
Nuclear Membrane ◽  
Mechanical Forces ◽  
Linc Complex ◽  
Cooperative Network ◽  
C Elegans ◽  
Stressful Environment ◽  
Balance Of Forces

Oogenesis involves meiosis and oocyte maturation. Both processes rely on mechanical forces (Lee et al., 2015; Nagamatsu et al., 2019; Rog and Dernburg, 2015; Sato et al., 2009; Tsatskis et al., 2020; Wynne et al., 2012), which can be transduced from the cytoskeleton to the nuclear envelope (NE) through linker of nucleoskeleton and cytoskeleton (LINC) complexes (Burke, 2018; Chang et al., 2015; Fan et al., 2020; Link et al., 2014). Gametes must protect their genomes from damage in this mechanically stressful environment. In C. elegans, oocyte nuclei lacking the single lamin protein LMN-1 are vulnerable to nuclear collapse. Here we deploy the auxin-inducible degradation system to investigate the balance of forces that drive this collapse and protect oocyte nuclei. We find that nuclear collapse is not a consequence of apoptosis. It is promoted by dynein and a LINC complex comprised of SUN-1 and ZYG-12, which assumes polarized distribution at the NE in response to dynein-mediated forces. We also show that the lamin meshwork works in parallel with other inner nuclear membrane (INM) proteins to counteract mechanical stress at the NE during oogenesis. We speculate that a similar network may protect oocyte integrity during the long arrest period in mammals.

scholarly journals The anterior Hox gene ceh-13 and elt-1/GATA activate the posterior Hox genes nob-1 and php-3 to specify posterior lineages in the C. elegans embryo

2021 ◽  
Author(s):  
John Isaac Murray ◽  
Elicia Preston ◽  
Jeremy P. Crawford ◽  
Jonathan D. Rumley ◽  
Prativa Amom ◽  
...  
Keyword(s):  
Gene Regulation ◽  
Cell Division ◽  
Hox Genes ◽  
Hox Gene ◽  
Animal Development ◽  
C Elegans ◽  
Transcriptional Enhancers ◽  
Positional Identity ◽  
Cell Position ◽  
And Function

AbstractHox transcription factors play a conserved role in specifying positional identity during animal development, with posterior Hox genes typically repressing the expression of more anterior Hox genes. Here, we dissect the regulation of the posterior Hox genes nob-1 and php-3 in the nematode C. elegans. We show that nob-1 and php-3 are co-expressed in gastrulation-stage embryos in cells that express the anterior Hox gene ceh-13. This expression is controlled by several partially redundant transcriptional enhancers. Surprisingly, these enhancers require ceh-13 for expression, providing an example of an anterior Hox gene positively regulating a posterior Hox gene. Several other regulators also act positively through nob-1/php-3 enhancers, including elt-1/GATA, ceh-20/ceh-40/Pbx, unc-62/Meis, pop-1/TCF, ceh-36/Otx and unc-30/Pitx. We identified defects in both cell position and cell division patterns in ceh-13 and nob-1;php-3 mutants, suggesting that these factors regulate lineage identity in addition to positional identity. Together, our results highlight the complexity and remarkable flexibility of Hox gene regulation and function.

scholarly journals Mechanical stress compromises multicomponent efflux complexes in bacteria

2019 ◽  
Author(s):  
Lauren A. Genova ◽  
Melanie F. Roberts ◽  
Yu-Chern Wong ◽  
Christine E. Harper ◽  
Ace George Santiago ◽  
...  
Keyword(s):  
Cell Division ◽  
Mechanical Stress ◽  
Single Molecule ◽  
Protein Complexes ◽  
Cell Envelope ◽  
Mechanical Forces ◽  
Growth And Survival ◽  
Physical Forces ◽  
Bacterial Growth And Survival ◽  
Membrane Components

Physical forces have long been recognized for their effects on the growth, morphology, locomotion, and survival of eukaryotic organisms1. Recently, mechanical forces have been shown to regulate processes in bacteria, including cell division2, motility3, virulence4, biofilm initiation5,6, and cell shape7,8, although it remains unclear how mechanical forces in the cell envelope lead to changes in molecular processes. In Gram-negative bacteria, multicomponent protein complexes that form rigid links across the cell envelope directly experience physical forces and mechanical stresses applied to the cell. Here we manipulate tensile and shear mechanical stress in the bacterial cell envelope and use single-molecule tracking to show that shear (but not tensile) stress within the cell envelope promotes disassembly of the tripartite efflux complex CusCBA, a system used by E. coli to resist copper and silver toxicity, thereby making bacteria more susceptible to metal toxicity. These findings provide the first demonstration that mechanical forces, such as those generated during colony overcrowding or bacterial motility through submicron pores, can inhibit the contact and function of multicomponent complexes in bacteria. As multicomponent, trans-envelope efflux complexes in bacteria are involved in many processes including antibiotic resistance9, cell division10, and translocation of outer membrane components11, our findings suggest that the mechanical environment may regulate multiple processes required for bacterial growth and survival.

scholarly journals C. elegans discriminates colors to guide foraging

Science ◽  
2021 ◽  
Vol 371 (6533) ◽  
pp. 1059-1063 ◽  
Author(s):  
D. Dipon Ghosh ◽  
Dongyeop Lee ◽  
Xin Jin ◽  
H. Robert Horvitz ◽  
Michael N. Nitabach
Keyword(s):  
Stress Response ◽  
Cellular Stress ◽  
Color Discrimination ◽  
Cellular Stress Response ◽  
Blue Pigment ◽  
Natural Environments ◽  
C Elegans ◽  
Evolutionarily Conserved ◽  
Foraging Decisions ◽  
Light Guides

Color detection is used by animals of diverse phyla to navigate colorful natural environments and is thought to require evolutionarily conserved opsin photoreceptor genes. We report that Caenorhabditis elegans roundworms can discriminate between colors despite the fact that they lack eyes and opsins. Specifically, we found that white light guides C. elegans foraging decisions away from a blue-pigment toxin secreted by harmful bacteria. These foraging decisions are guided by specific blue-to-amber ratios of light. The color specificity of color-dependent foraging varies notably among wild C. elegans strains, which indicates that color discrimination is ecologically important. We identified two evolutionarily conserved cellular stress response genes required for opsin-independent, color-dependent foraging by C. elegans, and we speculate that cellular stress response pathways can mediate spectral discrimination by photosensitive cells and organisms—even by those lacking opsins.

scholarly journals An essential contractile ring protein controls cell division in Plasmodium falciparum

2019 ◽  
Vol 10 (1) ◽  
Author(s):  
Rachel M. Rudlaff ◽  
Stephan Kraemer ◽  
Vincent A. Streva ◽  
Jeffrey D. Dvorin
Keyword(s):  
Plasmodium Falciparum ◽  
Cell Division ◽  
Contractile Ring

scholarly journals pop-1/TCF, ref-2/ZIC and T-box factors regulate the development of anterior cells in the C. elegans embryo

2021 ◽  
Author(s):  
Jonathan D Rumley ◽  
Elicia A Preston ◽  
Dylan Cook ◽  
Felicia L Peng ◽  
Amanda L Zacharias ◽  
...  
Keyword(s):  
Wnt Pathway ◽  
Expression Patterns ◽  
Specific Expression ◽  
T Box ◽  
Animal Development ◽  
C Elegans ◽  
The Many ◽  
Necessary And Sufficient ◽  
Cell Division Timing ◽  
Anterior Posterior

Patterning of the anterior-posterior axis is fundamental to animal development. The Wnt pathway plays a major role in this process by activating the expression of posterior genes in animals from worms to humans. This observation raises the question of whether the Wnt pathway or other regulators control the expression of the many anterior-expressed genes. We found that the expression of five anterior-specific genes in Caenorhabditis elegans embryos depends on the Wnt pathway effectors pop-1/TCF and sys-1/β-catenin. We focused further on one of these anterior genes, ref-2/ZIC, a conserved transcription factor expressed in multiple anterior lineages. Live imaging of ref-2 mutant embryos identified defects in cell division timing and position in anterior lineages. Cis-regulatory dissection identified three ref-2 transcriptional enhancers, one of which is necessary and sufficient for anterior-specific expression. This enhancer is activated by the T-box transcription factors TBX-37 and TBX-38, and surprisingly, concatemerized TBX-37/38 binding sites are sufficient to drive anterior-biased expression alone, despite the broad expression of TBX-37 and TBX-38. Taken together, our results highlight the diverse mechanisms used to regulate anterior expression patterns in the embryo.

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