Actin Dynamics Drive Microvillar Motility and Clustering during Brush Border Assembly
Highlights d Microvilli exhibit persistent, active motility driven by actin assembly d Microvillar F-actin cores treadmill during motility d Barbed-end binding factors regulate microvillar motility d Motility promotes intermicrovillar collisions, adhesion, and cluster formation
The docking protein p130Cas is a major Src substrate involved in integrin signaling and mechanotransduction. Tyrosine phosphorylation of p130Cas in focal adhesions (FAs) has been linked to enhanced cell migration, invasion, proliferation, and survival. However, the mechanism of p130Cas targeting to FAs is uncertain, and dynamic aspects of its localization have not been explored. Using live cell microscopy, we show that fluorophore-tagged p130Cas is a component of FAs throughout the FA assembly and disassembly stages, although it resides transiently in FAs with a high mobile fraction. Deletion of either the N-terminal Src homology 3 (SH3) domain or the Cas-family C-terminal homology (CCH) domain significantly impaired p130Cas FA localization, and deletion of both domains resulted in full exclusion. Focal adhesion kinase was implicated in the FA targeting function of the p130Cas SH3 domain. Consistent with their roles in FA targeting, both the SH3 and CCH domains were found necessary for p130Cas to fully undergo tyrosine phosphorylation and promote cell migration. By revealing the capacity of p130Cas to function in FAs throughout their lifetime, clarifying FA targeting mechanism, and demonstrating the functional importance of the highly conserved CCH domain, our results advance the understanding of an important aspect of integrin signaling.p130Cas (Crk-associated substrate) is a Src substrate that functions in integrin signaling to promote cell motility, invasion, proliferation, and survival (1, 2). p130Cas was first recognized as a prominent tyrosine-phosphorylated protein in cells transformed by v-crk (3) and v-src (4). The observation that p130Cas interacts directly with the Src homology 2 (SH2) 2 domain of the v-Crk protein (5, 6) contributed to the recognition of SH2 domains as phosphotyrosine-binding modules in signal transduction. The primary structure of p130Cas (7) indicated a function as a docking/scaffolding protein, lacking domains indicative of intrinsic enzymatic activity but having various domains and motifs for mediating interactions with other proteins.p130Cas was independently identified in a screen for proteins that interact with focal adhesion kinase (FAK) (8), a tyrosine kinase named for its prominent localization to sites of integrin-mediated cell adhesion. A Src homology 3 (SH3) domain at the N terminus of p130Cas mediates the FAK interaction. Like FAK, p130Cas localizes to focal adhesions (FAs) and undergoes tyrosine phosphorylation in response to adhesion (9 -11). Thus, p130Cas is a signaling component of the FA protein complex ("adhesome") that assembles to bring about cellular responses to integrin engagement. A primary role for p130Cas in integrin signaling is consistent with the phenotype of p130Cas-deficient mice, which die during embryonic development due to defects associated with a disorganized actin cytoskeleton (12). Despite the direct interaction with FAK, tyrosine phosphorylation of p130Cas is attributed to Src-family kinases (13-15). However, FAK can act as a scaffold to recru...
Highlights d EPS8 and IRTKS puncta mark sites of new microvillus growth d EPS8 and IRTKS puncta remain enriched at the distal tips of nearly all microvilli d Existing microvilli also serve as mothers that give rise to daughter protrusions d Microvilli collapse when membrane wrapping and EPS8/ IRTKS tip enrichment are lost
The docking protein p130Cas is a prominent Src substrate found in focal adhesions (FAs) and is implicated in regulating critical aspects of cell motility including FA disassembly and protrusion of the leading edge plasma membrane. To better understand how p130Cas acts to promote these events we examined requirements for established p130Cas signaling motifs including the SH3-binding site of the Src binding domain (SBD) and the tyrosine phosphorylation sites within the substrate domain (SD). Expression of wild type p130Cas in Cas −/− mouse embryo fibroblasts resulted in enhanced cell migration associated with increased leading-edge actin flux, increased rates of FA assembly/disassembly, and uninterrupted FA turnover. Variants lacking either the SD phosphorylation sites or the SBD SH3-binding motif were able to partially restore the migration response, while only a variant lacking both signaling functions was fully defective. Notably, the migration defects associated with p130Cas signaling-deficient variants correlated with longer FA lifetimes resulting from aborted FA disassembly attempts. However the SD mutational variant was fully defective in increasing actin assembly at the protruding leading edge and FA assembly/disassembly rates, indicating that SD phosphorylation is the sole p130Cas signaling function in regulating these processes. Our results provide the first quantitative evidence supporting roles for p130Cas SD tyrosine phosphorylation in promoting both leading edge actin flux and FA turnover during cell migration, while further revealing that the p130Cas SBD has a function in cell migration and sustained FA disassembly that is distinct from its known role of promoting SD tyrosine phosphorylation.
Nonmuscle myosin-2 contractility-dependent actin turnover limits the length of epithelial microvilli
Brush border microvilli enable functions that are critical for epithelial homeostasis, including solute uptake and host defense. However, mechanisms that regulate the assembly and morphology of these protrusions are poorly understood. The parallel actin bundles that support microvilli have their pointed-end rootlets anchored in a filamentous meshwork referred to as the “terminal web.” Although classic EM studies revealed complex ultrastructure, the composition and function of the terminal web remains unclear. Here we identify non-muscle myosin-2C (NM2C) as a component of the terminal web. NM2C is found in a dense, isotropic layer of puncta across the sub-apical domain, which transects the rootlets of microvillar actin bundles. Puncta are separated by ∼210 nm, the expected size of filaments formed by NM2C. In intestinal organoid cultures, the terminal web NM2C network is highly dynamic and exhibits continuous remodeling. Using pharmacological and genetic perturbations in cultured intestinal epithelial cells, we found that NM2C controls the length of growing microvilli by regulating actin turnover in a manner that requires a fully active motor domain. Our findings answer a decades old question on the function of terminal web myosin and hold broad implications for understanding apical morphogenesis in diverse epithelial systems. [Media: see text] [Media: see text] [Media: see text] [Media: see text] [Media: see text] [Media: see text]
Apical microvilli are critical for the homeostasis of transporting epithelia, yet mechanisms that control the assembly and morphology of these protrusions remain poorly understood. Previous studies in intestinal epithelial cell lines suggested a role for the F-BAR domain protein PACSIN2 in normal microvillar assembly. Here we report the phenotype of PACSIN2 KO mice and provide evidence that through its role in promoting apical endocytosis, this molecule plays a role in controlling microvillar morphology. PACSIN2 KO enterocytes exhibit reduced numbers of microvilli and defects in the microvillar ultrastructure, with membranes lifting away from rootlets of core bundles. Dynamin2, a PACSIN2 binding partner, and other endocytic factors were also lost from their normal localization near microvillar rootlets. To determine whether loss of endocytic machinery could explain defects in microvillar morphology, we examined the impact of PACSIN2 KD and endocytosis inhibition on live intestinal epithelial cells. These assays revealed that when endocytic vesicle scission fails, tubules are pulled into the cytoplasm and this, in turn, leads to a membrane-lifting phenomenon reminiscent of that observed at PACSIN2 KO brush borders. These findings lead to a new model where inward forces generated by endocytic machinery on the plasma membrane control the membrane wrapping of cell surface protrusions.
Objective: Persons with HIV have doubled the risk of developing cardiovascular disease compared with the general population. A persistent and heightened immune response to cytomegalovirus coinfection may be one contributing factor, but the relationship between cytomegalovirus replication, virus-specific immune cells, and plaque burden is unclear. Approach and Results: We assessed the relationship between CD4 + T-cell subsets and carotid plaque burden in a cohort of 70 HIV-positive participants with sustained viral suppression on a single antiretroviral regimen and without known cardiovascular disease. We evaluated the relationship between immune parameters, carotid plaque burden, soluble markers of endothelial activation, and brachial artery flow-mediated vasodilation using multivariable linear and logistic regression models. We found that participants with carotid plaque had increased circulating CX3CR1 + ~GPR56 + ~CD57 + (ie, C~G~C) + CD4 + T cells ( P =0.03), which is a marker combination associated with antiviral and cytotoxic responses. In addition, a median of 14.4% (IQR, 4.7%–32.7%) of the C~G~C + CD4 + T-cells expressed antigen receptors that recognized a single cytomegalovirus glycoprotein-B epitope. Notably, using immunofluorescence staining, we found that CX3CR1 + CD4 + T cells were present in coronary plaque from deceased HIV-positive persons. C-G-C + CD4 + T cells were also present in cells isolated from the aorta of HIV-negative donors. Conclusions: HIV-positive persons with carotid atheroma have a higher proportion of circulating CD4 + T-cells expressing the C~G~C surface marker combination associated with cytotoxic function. These cells can be cytomegalovirus-specific and are also present in the aorta.
During differentiation, transporting epithelial cells generate large arrays of microvilli known as a brush borders to enhance functional capacity. To develop our understanding of brush border formation, we used live cell imaging to visualize apical surface remodeling during early stages of this process. Strikingly, we found that individual microvilli exhibit persistent active motility, translocating across the cell surface at ~0.2 μm/min. Perturbation studies with inhibitors and photokinetic experiments revealed that microvillar motility is driven by actin assembly at the barbed-ends of core bundles, which in turn is linked to robust treadmilling of these structures. Because the apical surface of differentiating epithelial cells is crowded with nascent microvilli, persistent motility promotes collisions between protrusions and ultimately leads to their clustering and consolidation into higher order arrays. Thus, microvillar motility represents a previously unrecognized driving force for apical surface remodeling and maturation during epithelial differentiation.3
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