Cytoskeletal interactions of synapsin I in non-neuronal cells

Synapsin I is a neuronal phosphoprotein involved in the localization and stabilization of synaptic vesicles. Recently, synapsin I has been detected in several non-neuronal cell lines, but its function in these cells is unclear. To determine the localization of synapsin I in non-neuronal cells, it was transiently expressed in HeLa and NIH/3T3 cells as an enhanced green fluorescent protein fusion protein. Synapsin I-enhanced green fluorescent protein colocalized with F-actin in both cell lines, particularly with microspikes and membrane ruffles. It did not colocalize with microtubules or vimentin and it did not cause major alterations in cytoskeletal organization. Synapsin Ia-enhanced green fluorescent protein colocalized with microtubule bundles in taxol-treated HeLa cells and with F-actin spots at the plasma membrane in cells treated with cytochalasin B. It did not noticeably affect F-actin reassembly following drug removal. Synapsin Ia-enhanced green fluorescent protein remained colocalized with F-actin in cells treated with nocodazole, and it did not affect reassembly of microtubules following drug removal. These results demonstrate that synapsin I interacts with F-actin in non-neuronal cells and suggest that synapsin I may have a role in regions where actin is highly dynamic.     

Evidence for a gelsolin-rich, labile F-actin pool in human polymorphonuclear leukocytes.

Filamentous (F) actin is a major cytoskeletal element in polymorphonuclear leukocytes (PMNs) and other non-muscle cells. Exposure of PMNs to agonists causes polymerization of monomeric (G) actin to F-actin and activates motile responses. In vitro, all purified F-actin is identical. However, in vivo, the presence of multiple, diverse actin regulatory and binding proteins suggests that all F-actin within cells may not be identical. Typically, F-actin in cells is measured by either NBDphallacidin binding or as cytoskeletal associated actin in Triton-extracted cells. To determine whether the two measures of F-actin in PMNs, NBDphallacidin binding and cytoskeletal associated actin, are equivalent, a qualitative and quantitative comparison of the F-actin in basal, non-adherent endotoxin-free PMNs measured by both techniques was performed. F-actin as NBDphallacidin binding and cytoskeletal associated actin was measured in cells fixed with formaldehyde prior to cell lysis and fluorescent staining (PreFix), or in cells lysed with Triton prior to fixation (PostFix). By both techniques, F-actin in PreFix cells is higher than in PostFix cells (54.25 +/- 3.77 vs. 23.5 +/- 3.7 measured as mean fluorescent channel by NBDphallacidin binding and 70.3 +/- 3.5% vs. 47.2 +/- 3.6% of total cellular actin measured as cytoskeletal associated actin). These results show that in PMNs, Triton exposure releases a labile F-actin pool from basal cells while a stable F-actin pool is resistant to Triton exposure. Further characterizations of the distinct labile and stable F-actin pools utilizing NBDphallacidin binding, ultracentrifugation, and electron microscopy demonstrate the actin released with the labile pool is lost as filament. The subcellular localization of F-actin in the two pools is documented by fluorescent microscopy, while the distribution of the actin regulatory protein gelsolin is characterized by immunoblots with anti-gelsolin. Our studies show that at least two distinct F-actin pools coexist in endotoxin-free, basal PMNs in suspension: 1) a stable F-actin pool which is a minority of total cellular F-actin, Triton insoluble, resistant to depolymerization at 4 degrees C, gelsolin-poor, and localized to submembranous areas of the cell; and 2) a labile F-actin pool which is the majority of total cellular F-actin, Triton soluble, depolymerizes at 4 degrees C, is gelsolin-rich, and distributed diffusely throughout the cell. The results suggest that the two pools may subserve unique cytoskeletal functions within PMNs, and should be carefully considered in efforts to elucidate the mechanisms which regulate actin polymerization and depolymerization in non-muscle cells.     

Actin cytoskeleton controls movement of intracellular organelles in pancreatic duct epithelial cells

In most eukaryotic cells, microtubules and filamentous actin (F-actin) provide tracks on which intracellular organelles move using molecular motors. Here we report that cytoplasmic movement of both mitochondria and lysosomes is slowed by F-actin meshwork formation in pancreatic duct epithelial cells (PDEC). Mitochondria and lysosomes were labeled with fluorescent Mitotracker Red CMXRos and Lysotracker Red DND-99, respectively, and their movements were monitored using epi-fluorescence and confocal microscopy. Mitochondria and lysosomes moving actively at rest stopped rapidly within several seconds after an intracellular Ca(2+) rise induced by activation of P2Y(2) purinergic receptors. The 'freezing' of the organelles was inhibited by blocking the Ca(2+) rise or by pretreatment with latrunculin B, an inhibitor of F-actin formation. Indeed, this freezing effect on the organelles was accompanied by the formation of F-actin in the whole cytoplasm as stained with Alexa 488-phalloidin in fixed PDEC. For real-time monitoring of F-actin formation in live cells, we expressed sGFP-fimbrin actin binding domain2 (fABD2) in PDEC. Rapid recruitment of the fluorescent probe near the nucleus and lysosomes suggested dense F-actin formation around intracellular structures. The development of F-actin paralleled that of organelle freezing. We conclude that rapid Ca(2+)-dependent F-actin formation physically restrains intracellular organelles and reduces their mobility non-selectively in PDEC.     

Cell migration without a lamellipodium: translation of actin dynamics into cell movement mediated by tropomyosin

The actin cytoskeleton is locally regulated for functional specializations for cell motility. Using quantitative fluorescent speckle microscopy (qFSM) of migrating epithelial cells, we previously defined two distinct F-actin networks based on their F-actin-binding proteins and distinct patterns of F-actin turnover and movement. The lamellipodium consists of a treadmilling F-actin array with rapid polymerization-dependent retrograde flow and contains high concentrations of Arp2/3 and ADF/cofilin, whereas the lamella exhibits spatially random punctae of F-actin assembly and disassembly with slow myosin-mediated retrograde flow and contains myosin II and tropomyosin (TM). In this paper, we microinjected skeletal muscle alphaTM into epithelial cells, and using qFSM, electron microscopy, and immunolocalization show that this inhibits functional lamellipodium formation. Cells with inhibited lamellipodia exhibit persistent leading edge protrusion and rapid cell migration. Inhibition of endogenous long TM isoforms alters protrusion persistence. Thus, cells can migrate with inhibited lamellipodia, and we suggest that TM is a major regulator of F-actin functional specialization in migrating cells.     

Comparisons of Endothelial Cell G- and F-Actin Distribution in Situ and in Vitro

Numerous studies have described the F-actin cytoskeleton; however, little information relevant to C-actin is available. The actin pools of bovine aortic endothelial cells were examined using in situ and in vitro conditions and fluorescent probes for G-(deoxyribonuclease I.0.3 μM) or F-actin (phalloidin, 0.2 μM). Cells in situ displayed a diffuse G-actin distribution, while F-actin was concentrated in the cell periphery and in fine stress fibers that traversed some cells. Cells of subconfluent or just confluent cultures demonstrated intense fluorescence, with many F-actin stress fibers. Postconfluent cultures resembled the condition in situ; peripheral F-actin was prominent, traversing actin stress fibers were greatly reduced and fluorescent intensity was diminished. Postconfluency had little influence on G-actin. with only an enhancement in the intensity of G-actin punctate fluorescence. When post-confluent cultures were incubated with cytochalasin D (15 min; 10^--⁴ M), F-actin networks were disrupted and actin punctate and diffuse fluorescence increased. G-actin fluorescence was not altered by the incubation. Although its unstructured nature may account for the minor changes observed, the stability of the G-actin pool in the presence of notable F-actin modulations suggested that filamentous actin was the key constituent involved in these actin cytoskeletal alterations. A separate finding illustrated that the concomitant use of actin probes with image enhancement and fluorescent microscopy could reveal simultaneously the G- and F-actin pools within the same cell.     

Distribution of fluorescently labeled actin and tropomyosin after microinjection in living tissue culture cells as observed with TV image intensification

Skeletal muscle F-actin and smooth muscle tropomyosin separately labeled with the fluorescent reporter group 5-iodoacetamidofluorescein (5-IAF) were further purified to yield G-actin fully competent to polymerize and tropomyosin able to bind specifically to F-actin. The two fluorescent proteins (dye content of 0.4–0.5 moles/mole of protein) were microinjected into tissue culture cells and their intracellular distribution was followed by TV image intensification. Fluorescent actin is found in the stress fibers and in the lamellopodia and ruffling edges of the cells. In addition a general cytoplasmic fluorescence is observed as well as fluorescent patches, which could be actin paracrystals. In contrast tropomyosin is not incorporated into ruffles although it is clearly seen along the stress fibers and gives rise to general cytoplasmic fluorescence. Control experiments using fluorescent serum albumin show no specific visualization of either stress fibers or ruffles. The specificity of the incorporation of the fluorescently labeled contractile proteins into the microfilament structures is further documented by the preparation of detergent resistant cytoskeletons which retain actin and tropomyosin in the appropriate structures but are devoid of fluorescent serum albumin. In addition the distribution of the contractile proteins in the living cells is affected by the microfilament specific drugs phalloidin and cytochalasin B (CB). The results obtained on live cells are in excellent agreement with conclusions drawn from immunofluorescence microscopical observations on fixed cells. In addition they directly prove the rather obvious point that contractile proteins are constantly rearranged in tissue culture cells.     

Microinjected fluorescent phalloidin in vivo reveals the F-actin dynamics and assembly in higher plant mitotic cells.

Endosperm mitotic cells microinjected with fluorescent phalloidin enabled us to follow the in vivo dynamics of the F-actin cytoskeleton. The fluorescent probe immediately bound to plant microfilaments. First, we investigated the active rearrangement of F-actin during chromosome migration, which appeared to be slowed down in the presence of phalloidin. These findings were compared with the actin patterns observed in mitotic cells fixed at different stages. Our second aim was to determine the origin of the actin filaments that appear at the equator during anaphase-telophase transition. It is not clear whether this F-actin is newly assembled at the end of mitosis and could control plant cytokinesis or whether it corresponds to a passive redistribution of broken polymers in response to microtubule dynamics. We microinjected the same cells twice, first in metaphase with rhodamine-phalloidin and then in late anaphase with fluorescein isothiocyanate-phalloidin. This technique enabled us to visualize two F-actin populations that are not co-localized, suggesting that actin is newly assembled during cell plate development. These in vivo data shed new light on the role of actin in plant mitosis and cytokinesis.     

F-actin distribution in the ovaries of pre-vitellogenic and vitellogenic black blowflies,Phormia regina (Meigen) (Diptera : Calliphoridae)

The spatial distribution of F-actin microfilaments in the ovaries of previtellogenic and vitellogenic female black blowflies, Phormia regina (Diptera : Calliphoridae), as the females shift from a sugar to a liver diet, is determined using rhodamine-labelled phalloidin (rh-phalloidin). During the pre-vitellogenic stages of ovarian development (i.e. corresponding to a sugar diet) a single bright fluorescent layer marks the interface between follicle cells and the oocyte. Fluorescence is also most evident at the inner surface of the ring canals of the nurse cells. This is observed in the nurse cells both in the distal part of the germarium, and in the vitellogenic growing oocyte. However, when liver-fed (i.e. necessary for vitellogenesis), 2 bright fluorescent layers are observed at the follicle cell-oocyte interface. In addition, the cytoplasm of the nurse cells during vitellogenesis appears full of fluorescent microfilaments and the actin rings are found to increase in size and thickness. The changing organization of the F-actin microfilaments in the follicles during the process of both egg chamber and oocyte formation is discussed and possible functions considered.     

In vivo visualization of F-actin structures during the development of the moss Physcomitrella patens

* The 'in planta' visualization of F-actin in all cells and in all developmental stages of a plant is a challenging problem. By using the soybean heat inducible Gmhsp17.3B promoter instead of a constitutive promoter, we have been able to label all cells in various developmental stages of the moss Physcomitrella patens, through a precise temperature tuning of the expression of green fluorescent protein (GFP)-talin. * A short moderate heat treatment was sufficient to induce proper labeling of the actin cytoskeleton and to allow the visualization of time-dependent organization of F-actin structures without impairment of cell viability. * In growing moss cells, dense converging arrays of F-actin structures were present at the growing tips of protonema cell, and at the localization of branching. Protonema and leaf cells contained a network of thick actin cables; during de-differentiation of leaf cells into new protonema filaments, the thick bundled actin network disappeared, and a new highly polarized F-actin network formed. * The controlled expression of GFP-talin through an inducible promoter improves significantly the 'in planta' imaging of actin.     

The influence of ethanol on cell membrane fluidity, migration, and invasion of murine melanoma cells

The short-term effects of ethanol (85.4, 170.8, and 256.2 mM) on cellular viability, proliferation, migration, and invasion were investigated on murine melanoma cells. Experiments with the fluorescent probe 1,6-diphenyl-1,3,5-hexatriene indicated that the two highest concentrations of ethanol induced low microviscosity (high lipid fluidity). Cellular viability and proliferation, as determined by the incorporation of [3H]IdUR, were unaffected by all three concentrations of ethanol. A membrane migration assay and a collagen type IV invasion assay evaluated cellular migration and invasion, respectively. For B16F10 and K1735 cells, the migration rate was significantly increased by 170.8 and 256.2 mM concentrations of ethanol. Although the invasion of B16F10 cells was not affected, invasion of K1735 cells was inhibited by 170.8 and 256.2 mM ethanol. The effect of ethanol on the cytoskeleton was monitored by fluorescent staining of F-actin. In contrast to untreated cells, F-actin staining of 256.2 mM ethanol-treated cells showed spike-like projections from the cell surface. Our findings suggest that ethanol can influence cell migration and invasion in vitro, as well as F-actin organization.     

Versatile fluorescent probes for actin filaments based on the actin-binding domain of utrophin

Actin filaments (F-actin) are protein polymers that undergo rapid assembly and disassembly and control an enormous variety of cellular processes ranging from force production to regulation of signal transduction. Consequently, imaging of F-actin has become an increasingly important goal for biologists seeking to understand how cells and tissues function. However, most of the available means for imaging F-actin in living cells suffer from one or more biological or experimental shortcomings. Here we describe fluorescent F-actin probes based on the calponin homology domain of utrophin (Utr-CH), which binds F-actin without stabilizing it in vitro. We show that these probes faithfully report the distribution of F-actin in living and fixed cells, distinguish between stable and dynamic F-actin, and have no obvious effects on processes that depend critically on the balance of actin assembly and disassembly.     

反义封闭NGAL基因表达对SHEEC食管癌细胞微丝骨架的影响

为了研究反义封闭NGAL基因表达对SHEEC食管癌细胞微丝骨架以及肿瘤细胞生物学行为的影响,以不同长度NGAL基因片段反义表达载体和硫代修饰反义寡核苷酸单链片段转染SHEEC食管癌细胞,通过G418筛选,建立一系列旨在封闭SHEEC食管癌细胞NGAL基因表达的亚细胞克隆.在细胞内F-肌动蛋白(F-actin)及DNA荧光双标记基础上,通过流式细胞术、激光共聚焦显微镜扫描术等技术手段检测封闭反义NGAL基因表达后, SHEEC食管癌细胞中F-actin和DNA含量、F-actin形态结构以及肿瘤细胞生物学行为的变化特征.结果显示,反义封闭NGAL基因表达后,SHEEC食管癌细胞F-actin的含量明显降低,与永生化食管上皮细胞SHEE相近,但细胞分裂增殖指数未见明显变化.表明反义封闭NGAL基因表达对SHEEC食管癌细胞的微丝骨架有明显影响,而对SHEEC食管癌细胞的分裂增殖影响不明显.激光共聚焦显微镜扫描观测显示,反义封闭NGAL基因表达可使SHEEC食管癌细胞F-actin分布均匀,F-actin小体减少,细胞间连接重新建立,结构较紧密,主要形态结构特征与SHEE细胞趋于一致.提示反义封闭NGAL基因表达可对SHEEC食管癌细胞的微丝骨架F-actin产生明显影响,推测癌细胞的微丝骨架F-actin可能是NGAL基因在SHEEC食管癌细胞中发挥功能的一种作用环节.     

Actin-dependent fluid-phase endocytosis in inner cortex cells of maize root apices

The fluorescent dye Lucifer Yellow (LY) is a well-known and widely-used marker for fluid-phase endocytosis. In this paper, both light and electron microscopy revealed that LY was internalized into transition zone cells of the inner cortex of intact maize root apices. The internalized LY was localized within tubulo-vesicular compartments invaginating from the plasma membrane at actomyosin-enriched pit-fields and individual plasmodesmata, as well as within adjacent small peripheral vacuoles. The internalization of LY was blocked by pretreating the roots with the F-actin depolymerizing drug latrunculin B, but not with the F-actin stabilizer jasplakinolide. F-actin enriched plasmodesmata and pit-fields of the inner cortex also contain abundant plant-specific unconventional class VIII myosin(s). In addition, 2,3 butanedione monoxime, a general inhibitor of myosin ATPases, partially inhibited the uptake of LY into cells of the inner cortex. Conversely, loss of microtubules did not inhibit fluid-phase endocytosis of LY into these cells. In conclusion, specialized actin- and myosin VIII-enriched membrane domains perform a tissue-specific form of fluid-phase endocytosis in maize root apices. The possible physiological relevance of this process is discussed.     

Characterization of cytoskeleton mechanical properties and 3D-actin structure in twisted adherent epithelial cells

Evaluation of the cytoskeleton mechanical properties requires specific micromanipulation techniques such as the magnetic twisting cytometry technique, in which microbeads are specifically linked to the cytoskeleton via transmembrane receptors. The aim of the study was to assess the structural relationship between the bead and the cytoskeleton structure. The spatial arrangement of the CSK network was therefore studied in fixed cells probed by beads and stained for F-actin by rhodamined phallo?dine. The spatial character of the actin CSK network, both in the bead neighborhood and at the cell scale, could then be studied for various degrees of fluorescent intensity from 3D-images of the actin structure, reconstructed from z-stack views obtained by confocal microscopy. Results show the feasibility of the staining/reconstruction technique which allows to reveal the three-dimensional organization of the cytoskeleton structure including an internal cytosolic structure with a high fluorescent F-actin intensity, and a sub-membranous cortical structure with a low fluorescent F-actin intensity.     

The actin-driven movement and formation of acetylcholine receptor clusters

A new method was devised to visualize actin polymerization induced by postsynaptic differentiation signals in cultured muscle cells. This entails masking myofibrillar filamentous (F)-actin with jasplakinolide, a cell-permeant F-actin-binding toxin, before synaptogenic stimulation, and then probing new actin assembly with fluorescent phalloidin. With this procedure, actin polymerization associated with newly induced acetylcholine receptor (AChR) clustering by heparin-binding growth-associated molecule-coated beads and by agrin was observed. The beads induced local F-actin assembly that colocalized with AChR clusters at bead-muscle contacts, whereas both the actin cytoskeleton and AChR clusters induced by bath agrin application were diffuse. By expressing a green fluorescent protein-coupled version of cortactin, a protein that binds to active F-actin, the dynamic nature of the actin cytoskeleton associated with new AChR clusters was revealed. In fact, the motive force generated by actin polymerization propelled the entire bead-induced AChR cluster with its attached bead to move in the plane of the membrane. In addition, actin polymerization is also necessary for the formation of both bead and agrin-induced AChR clusters as well as phosphotyrosine accumulation, as shown by their blockage by latrunculin A, a toxin that sequesters globular (G)-actin and prevents F-actin assembly. These results show that actin polymerization induced by synaptogenic signals is necessary for the movement and formation of AChR clusters and implicate a role of F-actin as a postsynaptic scaffold for the assembly of structural and signaling molecules in neuromuscular junction formation.     

Biomechanics of Schlemm's canal endothelial cells: influence on F-actin architecture

Aqueous humor drains from the eye through Schlemm's canal, a small endothelial-lined collecting duct. Schlemm's canal endothelial cells may be important in controlling the pressure within the eye (and hence are of interest in glaucoma), and are subject to an unusual combination of shear stress and a basal-to-apical pressure gradient. We sought to characterize this biomechanical environment and determine its effects on F-actin architecture in situ. A theoretical model of flow in Schlemm's canal was used to estimate shear stresses applied to endothelial cells by flowing aqueous humor. Alignment of Schlemm's canal endothelial cells in human eyes was quantified by scanning electron microscopy. F-actin architecture was visualized by fluorescent labeling and compared for closely adjacent cells exposed to different biomechanical environments. We found that, despite the relatively low flow rate of aqueous humor, shear stresses experienced by Schlemm's canal endothelial cells could reach those in the arterial system. Schlemm's canal endothelial cells showed a statistically significant preferential alignment, consistent with a shear-mediated effect. Schlemm's canal endothelial cells subjected to a basal-to-apical pressure gradient due to transendothelial flow showed a prominent marginal band of F-actin with relatively few cytoplasmic filaments. Adjacent cells not subject to this gradient showed little marginal F-actin, with a denser cytoplasmic random network. We conclude that Schlemm's canal endothelial cells experience physiologically significant levels of shear stress, promoting cell alignment. We speculate that this may help control the calibre of Schlemm's canal. F-actin distribution depends critically on the presence or absence of transendothelial flow and its associated pressure gradient. In the case of this pressure gradient, mechanical reinforcement around the cell periphery by F-actin seems to be critical.     

Effect of polyamine synthesis inhibitors separately and in combination with epidermal growth factor on fusion of lysosomes with phagosomes and F-actin level in mouse peritoneal macrophages

Effects of polyamine (PA) synthesis inhibitors--alpha-difluoromethylornithinchloride (DFMO) and alpha-methylornithinchloride (MO)--separately or in combination with the epidermal growth factor (EGF)--on lysosome-phagosome fusion (P-LF) and F-actin content in murine peritoneal macrophages were studied using fluorescent dye Acridine orange for lysosome labelling, FITC-phalloidin for F-actin, and yeast cells as a target. DFMO and MO significantly inhibited P-LF and decreased F-actin content in murine peritoneal macrophages. A combination of DFMO and MO with EGF failed to inhibit P-LF or to decrease F-actin content in these cells. The results obtained with DFMO and MO suggested new cellular targets of their effects. These results may be extended to cancer research to provide a rationale for clinical trials using combinations of EGF with DFMO or MO.     

F-Actin is a marker of dorsal induction in earlyPatella embryos

Summary The dorsal-ventral axis inPatella vulgata embryos is established at the 32-cell stage by an inductive interaction between the animal micromeres and one vegetal macromere. This vegetal macromere, once induced, is called the 3D macromere, and marks the future dorsal side of the embryo. We examined the pattern of filamentous (F) actin in such embryos using fluorescent phalloidin and found that this dorsal 3D macromere contains more F-actin than the remainder of the cells. In addition, only one of its two daughter cells, i.e. the 4D macromere, retains this higher density. In embryos in which the establishment of the dorsal-ventral axis has been experimentally inhibited via treatment with monensin, such differences in F-actin were not found. These results suggest that the appearance of an increased density of F-actin in the dorsal 3D and 4D macromeres of normal embryos requires the inductive interactions that establish the dorsal-ventral axis. We therefore conclude that F-actin is an early marker for dorsal induction in thePatella embryo.     

Dynamic changes in chromaffin cell cytoskeleton as prelude to exocytosis

Earlier work by us as well as others has demonstrated that filamentous actin is mainly localized in the cortical surface of chromaffin cell. This F-actin network acts as a barrier to the chromaffin granules, impeding their contact with the plasma membrane. Chromaffin granules contain α-actinin, an anchorage protein that mediates F-actin association with these vesicles. Consequently, chromaffin granules crosslink and stabilize F-actin networks. Stimulation of chromaffin cell produces disassembly of F-actin and removal of the barrier. This interpretation is based on: (1) Cytochemical experiments with rhodamine-labeled phalloidin indicated that in resting chromaffin cells, the F-actin network is visualized as a strong cortical fluorescent ring; (2) Nicotinic receptor stimulation produced fragmentation of this fluorescent ring, leaving chromaffin cell cortical areas devoid of fluorescence; and (3) These changes are accompanied by a decrease in F-actin, a concomitant increase in G-actin, and a decrease in the F-actin associated with the chromaffin cell cytoskeleton (DNAse I assay). We also have demonstrated the presence in chromaffin cells of gelsolin and scinderin, two Ca²⁺-dependent actin filament-severing proteins, and suggested that chromaffin cell stimulation activates scinderin with the consequent disruption of F-actin networks. Scinderin, a protein recently isolated in our laboratory, is restricted to secretory cells and is present mainly in the cortical chromaffin cell cytoplasm. Scinderin, which is structurally different from gelsolin (different pI_s, amino acid composition, peptide maps, and so on), decreases the viscosity of actin gels as a result of its F-actin-severing properties, as demonstrated by electron microscopy. Stimulation of chromaffin cells either by nicotine (10 μM) or high K+ (56 mM) produces a redistribution of subplasmalemmal scinderin and actin disassembly, which preceded exocytosis. The redistribution of scinderin and exocytosis is Ca²⁺-dependent and is not mediated by muscarinic receptors. Furthermore, our cytochemical experiments demonstrate that chromaffin cell stimulation produces a concomitant and similar redistribution of scinderin (fluorescein-labeled antibody) and F-actin (rhodamine phalloidin fluorescence), suggesting a functional interaction between these two proteins. Stimulation-induced redistribution of scinderin and F-actin disassembly would produce subplasmalemmal areas of decreased cytoplasmic viscosity and increased mobility for chromaffin granules. Exocytosis sites, evaluated by antidopamine-β-hydroxylase (anti-DβH) surface staining, are preferentially localized in plasma membrane areas devoid of F-actin.     

The mechanism for regulation of the F-actin binding activity of IQGAP1 by calcium/calmodulin.

IQGAP1 colocalizes with actin filaments in the cell cortex and binds in vitro to F-actin and several signaling proteins, including calmodulin, Cdc42, Rac1, and beta-catenin. It is thought that the F-actin binding activity of IQGAP1 is regulated by its reversible association with these signaling molecules, but the mechanisms have remained obscure. Here we describe the regulatory mechanism for calmodulin. Purified adrenal IQGAP1 was found to consist of two distinct protein pools, one of which bound F-actin and lacked calmodulin, and the other of which did not bind F-actin but was tightly associated with calmodulin. Based on this finding we hypothesized that calmodulin negatively regulates binding of IQGAP1 to F-actin. This hypothesis was tested in vitro using recombinant wild type and mutated IQGAP1s and in live cells that transiently expressed IQGAP1-YFP. In vitro, the affinity of wild type IQGAP1 for F-actin decreased with increasing concentrations of calmodulin, and this effect was dramatically enhanced by Ca(2+) and required the IQ domains of IQGAP1. In addition, we found that calmodulin bound wild type IQGAP1 much more efficiently in the presence of Ca(2+) than EGTA, and all 8 IQ motifs in each IQGAP1 dimer could bind calmodulin simultaneously. In live cells, IQGAP1-YFP localized to the cell cortex, but elevation of intracellular Ca(2+) reversibly induced the fluorescent fusion protein to become diffusely distributed. Taken together, these results support a model in which a rise in free intracellular Ca(2+) promotes binding of calmodulin to IQGAP1, which in turn inhibits IQGAP1 from binding to cortical actin filaments.