Mechanical strain breaks planar symmetry in embryonic epithelia via polarized microtubules.

Mechanical strain can act as a global cue to orient the core planar cell polarity pathway (Fz-PCP) in developing epithelia, but how strain directs a Fz-PCP vector is not known. Here we use live cell imaging of apical microtubules (MTs) and components of the Fz-PCP pathway to analyze epithelial cells in Xenopus embryos as they respond to anisotropic mechanical strain and form a Fz-PCP axis. We find that a Fz-PCP axis can be detected approximately 40 min after the application of strain.

Emi2 enables centriole amplification during multiciliated cell differentiation.

Massive centriole amplification during multiciliated cell (MCC) differentiation is a notable example of organelle biogenesis. This process is thought to be enabled by a derived cell cycle state, but the key cell cycle components required for centriole amplification in MCC progenitors remain poorly defined. Here, we show that () expression is up-regulated and acts in MCC progenitors after cell cycle exit to transiently inhibit anaphase-promoting complex/cyclosome (APC/C) activity.

Mechanical Strain Determines Cilia Length, Motility, and Planar Position in the Left-Right Organizer.

The Xenopus left-right organizer (LRO) breaks symmetry along the left-right axis of the early embryo by producing and sensing directed ciliary flow as a patterning cue. To carry out this process, the LRO contains different ciliated cell types that vary in cilia length, whether they are motile or sensory, and how they position their cilia along the anterior-posterior (A-P) planar axis. Here, we show that these different cilia features are specified in the prospective LRO during gastrulation, based on anisotropic mechanical strain that is oriented along the A-P axis, and graded in levels along the medial-lateral axis.

Mechanical strain determines the axis of planar polarity in ciliated epithelia.

Epithelia containing multiciliated cells align beating cilia along a common planar axis specified by the conserved planar cell polarity (PCP) pathway. Specification of the planar axis is also thought to require a long-range cue to align the axis globally, but the nature of this cue in ciliated and other epithelia remains poorly understood. We examined this issue using the Xenopus larval skin, where ciliary flow aligns to the anterior-posterior (A-P) axis.

Bbof1 is required to maintain cilia orientation.

Multiciliate cells (MCCs) are highly specialized epithelial cells that employ hundreds of motile cilia to produce a vigorous directed flow in a variety of organ systems. The production of this flow requires the establishment of planar cell polarity (PCP) whereby MCCs align hundreds of beating cilia along a common planar axis. The planar axis of cilia in MCCs is known to be established via the PCP pathway and hydrodynamic cues, but the downstream steps required for cilia orientation remain poorly defined.

Cadherin point mutations alter cell sorting and modulate GTPase signaling.

This study investigated the impact of cadherin binding differences on both cell sorting and GTPase activation. The use of N-terminal domain point mutants of Xenopus C-cadherin enabled us to quantify binding differences and determine their effects on cadherin-dependent functions without any potential complications arising as a result of differences in cytodomain interactions. Dynamic cell-cell binding measurements carried out with the micropipette manipulation technique quantified the impact of these mutations on the two-dimensional binding affinities and dissociation rates of cadherins in the native context of the cell membrane.

Biophysical properties of cadherin bonds do not predict cell sorting.

Differential binding between cadherin subtypes is widely believed to mediate cell sorting during embryogenesis. However, a fundamental unanswered question is whether cell sorting is dictated by the biophysical properties of cadherin bonds, or by broader, cadherin-dependent differences in intercellular adhesion or membrane tension. This report describes atomic force microscope measurements of the strengths and dissociation rates of homophilic and heterophilic cadherin (CAD) bonds.

Two stage cadherin kinetics require multiple extracellular domains but not the cytoplasmic region.

Micropipette manipulation measurements quantified the pre-steady state binding kinetics between cell pairs mediated by Xenopus cleavage stage cadherin. The time-dependence of the intercellular binding probability exhibits a fast forming, low probability binding state, which transitions to a slower forming, high probability state. The biphasic kinetics are independent of the cytoplasmic region, but the transition to the high probability state requires the third extracellular domain EC3.

Memory in receptor-ligand-mediated cell adhesion.

Single-molecule biomechanical measurements, such as the force to unfold a protein domain or the lifetime of a receptor-ligand bond, are inherently stochastic, thereby requiring a large number of data for statistical analysis. Sequentially repeated tests are generally used to obtain a data ensemble, implicitly assuming that the test sequence consists of independent and identically distributed (i.i.

Comet assay with nuclear extract incubation.

Alkaline comet assay is a simple sensitive method for detecting DNA strand breaks. However, at the time of cell lysis, only a fraction of the entire DNA damage appears as DNA strand breaks, while some DNA strand breaks may have been rejoined and some DNA lesions may still remain unexcised. We showed that nuclear extract (NE) prepared from human cells could excise the DNA adducts induced by UVC, X-ray, and methyl methanesulfonate (MMS).

Nitric oxide inhibits DNA-adduct excision in nucleotide excision repair.

Sustained induction of nitric oxide (NO) in chronic inflammation may be mutagenic, through DNA damage induction and/or DNA repair inhibition. Although there is good evidence that NO can cause DNA damage, how NO is involved in DNA repair remains elusive. By using DNA synthesis inhibitors to accumulate DNA strand breaks in comet assay, we show that NO and peroxynitrite inhibit DNA-adduct excision in human fibroblasts damaged by UVC, 4-nitroquinoline 1-oxide, benzo[a]pyrene dihydrodiol epoxide, cisplatin, or mitomycin C, but not with methyl methane sulfonate.