Cortical filamentous actin disassembly and scinderin redistribution during chromaffin cell stimulation precede exocytosis, a phenomenon not exhibited by gelsolin

Immunofluorescence and cytochemical studies have demonstrated that filamentous actin is mainly localized in the cortical surface of the chromaffin cell. It has been suggested that these actin filament networks act as a barrier to the secretory granules, impeding their contact with the plasma membrane. Stimulation of chromaffin cells produces a disassembly of actin filament networks, implying the removal of the barrier. The presence of gelsolin and scinderin, two Ca(2+)-dependent actin filament severing proteins, in the cortical surface of the chromaffin cells, suggests the possibility that cell stimulation brings about activation of one or more actin filament severing proteins with the consequent disruption of actin networks. Therefore, biochemical studies and fluorescence microscopy experiments with scinderin and gelsolin antibodies and rhodamine-phalloidin, a probe for filamentous actin, were performed in cultured chromaffin cells to study the distribution of scinderin, gelsolin, and filamentous actin during cell stimulation and to correlate the possible changes with catecholamine secretion. Here we report that during nicotinic stimulation or K(+)-evoked depolarization, subcortical scinderin but not gelsolin is redistributed and that this redistribution precedes catecholamine secretion. The rearrangement of scinderin in patches is mediated by nicotinic receptors. Cell stimulation produces similar patterns of distribution of scinderin and filamentous actin. However, after the removal of the stimulus, the recovery of scinderin cortical pattern of distribution is faster than F-actin reassembly, suggesting that scinderin is bound in the cortical region of the cell to a component other than F-actin. We also demonstrate that peripheral actin filament disassembly and subplasmalemmal scinderin redistribution are calcium-dependent events. Moreover, experiments with an antibody against dopamine-beta-hydroxylase suggest that exocytosis sites are preferentially localized to areas of F-actin disassembly.     

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.     

Chromaffin cell scinderin, a novel calcium-dependent actin filament-severing protein.

Scinderin, a novel Ca2+-activated actin filament-severing protein, has been purified to homogeneity from bovine adrenal medulla using a combination of several chromatographic procedures. The protein has an apparent mol. wt of 79,600 +/- 450 daltons, three isoforms (pIs 6.0, 6.1 and 6.2) and two Ca2+ binding sites (Kd 5.85 x 10(-7) M, Bmax 0.81 mol Ca2+/mol protein and Kd 2.85 x 10(-6) M, Bmax 1.87 mol Ca2+/mol protein). Scinderin interacts with F-actin in the presence of Ca2+ and produces a decrease in the viscosity of actin gels as a result of F-actin filament severing as demonstrated by electron microscopy. Scinderin is a structurally different protein from chromaffin cell gelsolin, another actin filament-severing protein described. Scinderin and gelsolin have different mol. wts, isoelectric points, amino acid composition and yield different peptide maps after limited proteolytic digestion by either Staphylococcus V8 protease or chymotrypsin. Moreover, scinderin antibodies do not cross-react with gelsolin and gelsolin antibodies fail to recognize scinderin. Immunofluorescence with anti-scinderin demonstrated that this protein is mainly localized in the subplasmalemma region of the chromaffin cell. Immunoblotting tests with the same antibodies indicated that scinderin is also expressed in brain and anterior as well as posterior pituitary. Presence of scinderin and gelsolin, two Ca2+-dependent actin filament-severing proteins in the same tissue, suggests the possibility of synergistic functions by the two proteins in the control of cellular actin filament networks. Alternatively, the actin filament-severing activity of the two proteins might be under the control of different transduction and modulating influences.     

Scinderin,a Ca2+-Dependent Actin Filament Severing Protein that Controls Cortical Actin Network Dynamics During Secretion

Secretory vesicles are localized in specific compartments within neurosecretory cells. These are different pools in which vesicles are in various states of releasability. The transit of vesicles between compartments is controlled and regulated by Ca²⁺, scinderin and the cortical F-actin network. Cortical F-actin disassembly is produced by the filament severing activity of scinderin. This Ca²⁺-dependent activity of scinderin together with its Ca²⁺-independent actin nucleating activity, control cortical F-actin dynamics during the secretory cycle. A good understanding of the interaction of actin with scinderin and of the role of this protein in secretion has been provided by the analysis of the molecular structure of scinderin together with the use of recombinant proteins corresponding to its different domains.     

An antisense oligodeoxynucleotide targeted to chromaffin cell scinderin gene decreased scinderin levels and inhibited depolarization-induced cortical F-actin disassembly and exocytosis

Chromaffin cell secretion requires cortical F-actin disassembly and it has been suggested that scinderin, a Ca2+ dependent F-actin severing protein, controls cortical actin dynamics. An antisense oligodeoxynucleotide targeting the scinderin gene was used to decrease the expression of the protein and access its role in secretion. Treatment with 2 microM scinderin antisense oligodeoxynucleotide for 4 days produced a significant decrease in scinderin expression and its mRNA levels. The expression of gelsolin, another F-actin severing protein, was not affected. Scinderin decrease was accompanied by concomitant and parallel decreases in depolarization-evoked cortical F-actin disassembly and exocytosis. Similar treatment with a mismatched oligodeoxynucleotide produced no effects. Scinderin antisense oligodeoxynucleotide treatment was also a very effective inhibitor of exocytosis in digitonin-permeabilized cells stimulated with increasing concentrations of Ca2+. This ruled out scinderin antisense interference with stimulation-induced depolarization or Ca2+ channel activation. Scinderin antisense treatment decreased the maximum (B(max)) secretory response to Ca2+ without modifying the affinity (K(m)) of the cation for the exocytotic machinery. Moreover, the antisense treatment did not affect norepinephrine uptake or the expression of dopamine ss-hydroxylase, suggesting that the number and function of chromaffin vesicles was not modified. In addition, scinderin antisense treatment did not alter the expression of proteins involved in vesicle-plasma membrane fusion, such as synaptophysin, synaptotagmin or syntaxin, indicating a lack of effects on the fusion machinery components. These observations strongly suggest that scinderin is a key player in the events involved in the secretory process.     

Regulation of sperm motility by PIP2(4,5) and actin polymerization

Actin polymerization and development of hyperactivated (HA) motility are two processes that take place during sperm capacitation. In previous studies, we demonstrated that the increase in F-actin during capacitation depends upon inactivation of the actin severing protein, gelsolin, by its binding to phosphatydilinositol-4, 5-bisphosphate (PIP₂). Here, we showed for the first time the involvement of PIP₂/gelsolin in human sperm motility before and during capacitation. Activation of gelsolin by causing its release from PIP₂ inhibited sperm motility, which could be restored by adding PIP₂ to the cells. Reduction of PIP₂ synthesis inhibited actin polymerization and motility, and increasing PIP₂ synthesis enhanced these activities. Furthermore, sperm demonstrating low motility contained low levels of PIP₂ and F-actin. During capacitation there was an increase in PIP₂ and F-actin levels in the sperm head and a decrease in the tail. In sperm with high motility, gelsolin was mainly localized to the sperm head before capacitation, whereas in low motility sperm, most of the gelsolin was localized to the tail before capacitation and translocated to the head during capacitation. We also showed that phosphorylation of gelsolin on tyrosine-438 depends on its binding to PIP₂. Activation of phospholipase C by Ca²⁺-ionophore or by activating the epidermal-growth-factor-receptor inhibits tyrosine phosphorylation of gelsolin. In conclusion, the data indicate that the increase of PIP₂ and/or F-actin in the head during capacitation enhances gelsolin translocation to the head. As a result the decrease of gelsolin in the tail allows keeping high level of F-actin in the tail, which is essential for the development of HA motility.     

Scinderin and cortical F-actin are components of the secretory machinery

Secretory vesicle exocytosis is the mechanism of release of neurotransmitters and neuropeptides. Secretory vesicles are localized in at least two morphologically and functionally distinct compartments: the reserve pool and the release-ready pool. Filamentous actin networks play an important role in this compartmentalization and in the trafficking of vesicles between these compartments. The cortical F-actin network constitutes a barrier (negative clamp) to the movement of secretory vesicles to release sites, and it must be locally disassembled to allow translocation of secretory vesicles in preparation for exocytosis. The disassembly of the cortical F-actin network is controlled by scinderin (a Ca(2+)-dependent F-actin severing protein) upon activation by Ca2+ entering the cells during stimulation. There are several factors that regulate scinderin activation (i.e., Ca2+ levels, phosphatidylinositol 4,5-bisphosphate (PIP2), etc.). The results suggest that scinderin and the cortical F-actin network are components of the secretory machinery.     

Gelsolin-Like Domain 3 Plays Vital Roles in Regulating the Activities of the Lily Villin/Gelsolin/Fragmin Superfamily

The villin/gelsolin/fragmin superfamily is a major group of Ca²⁺-dependent actin-binding proteins (ABPs) involved in various cellular processes. Members of this superfamily typically possess three or six tandem gelsolin-like (G) domains, and each domain plays a distinct role in actin filament dynamics. Although the activities of most G domains have been characterized, the biochemical function of the G3 domain remains poorly understood. In this study, we carefully compared the detailed biochemical activities of ABP29 (a new member of this family that contains the G1-G2 domains of lily ABP135) and ABP135_G1-G3 (which contains the G1-G3 domains of lily ABP135). In the presence of high Ca²⁺ levels in vitro (200 and 10 μM), ABP135_G1-G3 exhibited greater actin severing and/or depolymerization and nucleating activities than ABP29, and these proteins had similar actin capping activities. However, in the presence of low levels of Ca²⁺ (41 nM), ABP135_G1-G3 had a weaker capping activity than ABP29. In addition, ABP29 inhibited F-actin depolymerization, as shown by dilution-mediated depolymerization assay, differing from the typical superfamily proteins. In contrast, ABP135_G1-G3 accelerated F-actin depolymerization. All of these results demonstrate that the G3 domain plays specific roles in regulating the activities of the lily villin/gelsolin/fragmin superfamily proteins.     

Phosphoinositide-binding peptides derived from the sequences of gelsolin and villin.

The polyphosphoinositides phosphatidylinositol 4-monophosphate (PIP) and phosphatidylinositol 4,5-bisphosphate (PIP2) inactivate the actin filament-severing proteins villin and gelsolin and dissociate them from monomeric and polymeric actin. A potential polyphosphoinositide- (PPI) binding site of human plasma gelsolin regulating filament severing has been localized to the region between residues 150-169 and to the corresponding region in villin which occurs in the second of six homologous domains present in both proteins. Synthetic peptides based on these sequences bind tightly to both PIP and PIP2, in either micelles or bilayer vesicles, compete with gelsolin for binding to PPIs, and dissociate gelsolin-PIP2 complexes, restoring severing activity to the protein. These peptides also bind with moderate affinity to F-actin, suggesting that inactivation of the severing function of the intact proteins by PPIs results from competition between actin and PPIs for a critical binding site on gelsolin-villin. The PPI-binding peptides contain numerous basic amino acids, but their effects on PPIs are far greater than those of Arg or Lys oligomers, a highly basic peptide derived from the calmodulin-binding site of myristoylated, alanine-rich kinase C substrate protein, or the 5-kDa actin-binding protein thymosin beta-4, suggesting that specific aspects of the primary and secondary structure of these basic peptides are important for their interaction with the acidic headgroups of PPIs. In addition to elucidating the structure of PIP2-binding sites in gelsolin, the results describe a sensitive assay for phosphoinositide-binding molecules based on their ability to prevent inhibition of gelsolin function.     

CAPS and Munc13 utilize distinct PIP2-linked mechanisms to promote vesicle exocytosis

Phosphoinositides provide compartment-specific signals for membrane trafficking. Plasma membrane phosphatidylinositol 4,5-bisphosphate (PIP₂) is required for Ca²⁺-triggered vesicle exocytosis, but whether vesicles fuse into PIP₂-rich membrane domains in live cells and whether PIP₂ is metabolized during Ca²⁺-triggered fusion were unknown. Ca²⁺-dependent activator protein in secretion 1 (CAPS-1; CADPS/UNC31) and ubMunc13-2 (UNC13B) are PIP₂-binding proteins required for Ca²⁺-triggered vesicle exocytosis in neuroendocrine PC12 cells. These proteins are likely effectors for PIP₂, but their localization during exocytosis had not been determined. Using total internal reflection fluorescence microscopy in live cells, we identify PIP₂-rich membrane domains at sites of vesicle fusion. CAPS is found to reside on vesicles but depends on plasma membrane PIP₂ for its activity. Munc13 is cytoplasmic, but Ca²⁺-dependent translocation to PIP₂-rich plasma membrane domains is required for its activity. The results reveal that vesicle fusion into PIP₂-rich membrane domains is facilitated by sequential PIP₂-dependent activation of CAPS and PIP₂-dependent recruitment of Munc13. PIP₂ hydrolysis only occurs under strong Ca²⁺ influx conditions sufficient to activate phospholipase Cη2 (PLCη2). Such conditions reduce CAPS activity and enhance Munc13 activity, establishing PLCη2 as a Ca²⁺-dependent modulator of exocytosis. These studies provide a direct view of the spatial distribution of PIP₂ linked to vesicle exocytosis via regulation of lipid-dependent protein effectors CAPS and Munc13.     

Purification and functional characterization of an 85-kDa gelsolin from the ascidians Microcosmus sulcatus and Phallusia mammilata

From the pharyngeal baskets of the ascidians Microcosmus sulcatus and Phallusia mammilata we have purified an 85-kDa protein that is characterized as a member of the gelsolin family. These proteins from both species show the same behaviour in functional assays. The ascidian gelsolin binds two actin monomers in a highly cooperative manner. This complex formation is Ca²⁺-dependent, but not completely reversible, as on removal of Ca²⁺ one actin monomer dissociates leaving a 1:1 complex between gelsolin and G-actin. The properties of F-actin severing and G-actin nucleation depend on the presence of free Ca²⁺ in a micromolar range, with half maximum activation at about 3×10⁻⁶ M. The protein becomes inactivated when Ca²⁺ concentrations of 0.5 mM are exceeded. Fragmentation of F-actin by the ascidian gelsolin is comparably fast to that of vertebrate gelsolin. A steady state of actin fragmentation is reached within 2–4 s. Promotion of G-actin nucleation is also comparable to that of vertebrate gelsolin. Regarding functional aspects, the ascidian gelsolin is more closely related to vertebrate gelsolin than to an arthropod gelsolin from crayfish tail muscle.     

Differential Effects of Lysophosphatidic Acid and Phosphatidylinositol 4,5-Bisphosphate on Actin Dynamics by Direct Association with the Actin-binding Protein Villin

We have previously reported that the epithelial cell-specific actin-binding protein villin directly associates with phosphatidylinositol 4,5-bisphosphate (PIP₂) through three binding sites that overlap with actin-binding sites in villin. As a result, association of villin with PIP₂ in hibits actin depolymerization and enhances actin cross-linking by villin. In this study, we demonstrate that these three PIP₂-binding sites also bind the more hydrophilic phospholipid, lysophosphatidic acid (LPA) but with a higher affinity than PIP₂ (dissociation constant (K_d) of 22 μm versus 39.5 μm for PIP₂). More interestingly, unlike PIP₂, the association of villin with LPA inhibits all actin regulatory functions of villin. In addition, unlike PIP₂, LPA dramatically stimulates the tyrosine phosphorylation of villin by c-Src kinase. These studies suggest that in cells, selective interaction of villin with either PIP₂ or LPA could have dramatically different outcomes on actin reorganization as well as phospholipid-regulated cell signaling. These studies provide a novel regulatory mechanism for phospholipid-induced changes in the microfilament structure and cell function and suggest that LPA could be an intracellular regulator of the actin cytoskeleton.     

Functional comparison of villin and gelsolin. Effects of Ca2+, KCl, and polyphosphoinositides

A family of homologous actin-binding proteins sever and cap actin filaments and accelerate actin filament assembly. The functions of two of these proteins, villin and gelsolin, and of their proteolytically derived actin binding domains were compared directly by measuring their effects, under various ionic conditions, on the rates and extents of polymerization of pyrene-labeled actin. In 1 mM Ca2+ and 150 mM KCl, villin and gelsolin have similar severing and polymerization-accelerating properties. Decreasing [Ca2+] to 25 microM greatly reduces severing by villin but not gelsolin. Decreasing [KCl] from 150 to 10 mM at 25 microM Ca2+ increases severing by villin, but not gelsolin, over 10-fold. The C-terminal half domains of both proteins have Ca2+-sensitive actin monomer-binding properties, but neither severs filaments nor accelerates polymerization. The N-terminal halves of villin and gelsolin contain all the filament-severing activity of the intact proteins. Severing by gelsolin's N-terminal half is Ca2+-independent, but that of villin has the same Ca2+ requirement as intact villin. The difference in Ca2+ sensitivity extends to 14-kDa N-terminal fragments which bind actin monomers and filament ends, requiring Ca2+ in the case of villin but not gelsolin. Severing of filaments by villin and its N-terminal half is shown to be inhibited by phosphatidylinositol 4,5-bisphosphate, as shown previously for gelsolin (Janmey, P.A., and Stossel, T.P. (1987) Nature 325, 362-364). The functional similarities of villin and gelsolin correlate with known structural features, and the greater functional dependence of villin on Ca2+ compared to gelsolin is traced to differences in their N-terminal domains.     

Gelsolin Modulates Phospholipase C Activity In Vivo through Phospholipid Binding

Gelsolin and CapG are actin regulatory proteins that remodel the cytoskeleton in response to phosphatidylinositol 4,5-bisphosphate (PIP₂) and Ca²⁺ during agonist stimulation. A physiologically relevant rise in Ca²⁺ increases their affinity for PIP₂ and can promote significant interactions with PIP₂ in activated cells. This may impact divergent PIP₂- dependent signaling processes at the level of substrate availability. We found that CapG overexpression enhances PDGF-stimulated phospholipase C_γ (PLC_γ) activity (Sun, H.-q., K. Kwiatkowska, D.C. Wooten, and H.L. Yin. 1995. J. Cell Biol. 129:147–156). In this paper, we examined the ability of gelsolin and CapG to compete with another PLC for PIP₂ in live cells, in semiintact cells, and in vitro. We found that CapG and gelsolin overexpression profoundly inhibited bradykinin-stimulated PLC_β. Inhibition occurred at or after the G protein activation step because overexpression also reduced the response to direct G protein activation with NaF. Bradykinin responsiveness was restored after cytosolic proteins, including gelsolin, leaked out of the overexpressing cells. Conversely, exogenous gelsolin added to permeabilized cells inhibited response in a dose-dependent manner. The washout and addback experiments clearly establish that excess gelsolin is the primary cause of PLC inhibition in cells. In vitro experiments showed that gelsolin and CapG stimulated as well as inhibited PLC_β, and only gelsolin domains containing PIP₂-binding sites were effective. Inhibition was mitigated by increasing PIP₂ concentration in a manner consistent with competition between gelsolin and PLC_β for PIP₂. Gelsolin and CapG also had biphasic effects on tyrosine kinase– phosphorylated PLC_γ, although they inhibited PLC_γ less than PLC_β. Our findings indicate that as PIP₂ level and availability change during signaling, cross talk between PIP₂-regulated proteins provides a selective mechanism for positive as well as negative regulation of the signal transduction cascade.     

Comparison between the gelsolin and adseverin domain structure.

Adseverin (74-kDa protein, scinderin) is a calcium- and phospholipid-modulated actin-binding protein that promotes actin polymerization, severs actin filaments, and caps the barbed end of the actin filament, with its NH2-terminal half retaining these properties (Sakurai, T., Kurokawa, H., and Nonomura, Y. (1991) J. Biol. Chem. 266, 4581-4585). Further proteolysis of this NH2-terminal half generated five fragments, and two of them (Mr 15,000 and 31,000) showed Ca(2+)-dependent binding to monomeric actin. The Mr 31,000 fragment especially caused actin filament fragmentation, although its severing activity was also inhibited by several acidic phospholipids as was found in adseverin and its NH2-terminal half. Amino acid sequencing demonstrated that the two fragments' NH2 terminus were blocked in the same manner as the NH2 terminus of adseverin, and thus these two fragments are possibly located at the NH2-terminal of the adseverin molecule. This would then indicate that NH2-terminal fragments had a Ca(2+)-sensitive actin-binding function that relates to actin severing. The other two fragments' NH2-terminal sequencing showed a similar homology to the amino acid sequences of gelsolin and villin. Based on these observations, we propose that adseverin has a functional domain structure similar to that of the gelsolin and villin core.     

Helix Straightening as an Activation Mechanism in the Gelsolin Superfamily of Actin Regulatory Proteins

Villin and gelsolin consist of six homologous domains of the gelsolin/cofilin fold (V1–V6 and G1–G6, respectively). Villin differs from gelsolin in possessing at its C terminus an unrelated seventh domain, the villin headpiece. Here, we present the crystal structure of villin domain V6 in an environment in which intact villin would be inactive, in the absence of bound Ca²⁺ or phosphorylation. The structure of V6 more closely resembles that of the activated form of G6, which contains one bound Ca²⁺, rather than that of the calcium ion-free form of G6 within intact inactive gelsolin. Strikingly apparent is that the long helix in V6 is straight, as found in the activated form of G6, as opposed to the kinked version in inactive gelsolin. Molecular dynamics calculations suggest that the preferable conformation for this helix in the isolated G6 domain is also straight in the absence of Ca²⁺ and other gelsolin domains. However, the G6 helix bends in intact calcium ion-free gelsolin to allow interaction with G2 and G4. We suggest that a similar situation exists in villin. Within the intact protein, a bent V6 helix, when triggered by Ca²⁺, straightens and helps push apart adjacent domains to expose actin-binding sites within the protein. The sixth domain in this superfamily of proteins serves as a keystone that locks together a compact ensemble of domains in an inactive state. Perturbing the keystone initiates reorganization of the structure to reveal previously buried actin-binding sites.Actin is crucial to such processes as cell movement, cell division, and apoptosis, which are regulated by numerous actin-binding proteins, including gelsolin, Arp2/3, and profilin (for review, see Ref. 1). Gelsolin, the most potent actin filament-severing protein known, can bind to, sever, cap, and nucleate actin filaments in a calcium-, pH-, ATP-, and phospholipid-dependent manner (for review, see Ref. 2). Villin, found in microvilli of absorptive epithelium, is a second member of the gelsolin family of actin-binding proteins. In addition to standard gelsolin-type activities, villin is able to bundle actin filaments and is subject to regulation by tyrosine phosphorylation as well as by Ca²⁺ and phosphatidylinositol 4,5-bisphosphate (for review, see Ref. 3). Many comparisons have been made between gelsolin and villin. The two share 50% amino acid sequence identity and show similar proteolytic cleavage patterns (4). Both contain six similarly folded domains, but villin possesses a seventh domain at its C terminus, the headpiece (HP)² domain, which folds into a compact structure that introduces a second F-actin-binding site into the protein. Recent studies indicate that villin uses the HP F-actin-binding sites to achieve bundling (5). In an environment devoid of free Ca²⁺, gelsolin and villin assume inactive conformations. After binding Ca²⁺, both undergo conformational rearrangements that expose their binding sites for F-actin. In villin, this includes revealing the HP actin-binding site through a “hinge mechanism” (6).Biochemical and structural studies have revealed eight Ca²⁺-binding sites of two types in gelsolin (for review, see Ref. 7). Each of the six domains contains a complete and evolutionarily conserved site, termed type 2, whereas G1 and G4 provide partial Ca²⁺ coordination at interfaces with actin through sites termed type 1. Sequential mutagenesis of these sites in villin has identified six functional Ca²⁺-binding sites (8): two major sites, one each of type 1 and type 2, in V1, plus four type 2 sites in V2–V6. The type 1 site in V1 regulates F-actin-capping and F-actin-severing activities, whereas the lower affinity type 2 site in V1 only affects severing (9). The other four sites are involved in stabilizing villin conformation, but they do not directly influence actin-severing activity. NMR studies of a fragment of villin that consists of V6 and the HP domain have implicated V6 residues Asn⁶⁴⁷, Asp⁶⁴⁸, and Glu⁶⁷⁰ in binding Ca²⁺ (10). These experiments also revealed the first 80 residues of V6 to undergo significant conformational change as a result of Ca²⁺ binding.Nanomolar to micromolar concentrations of free Ca²⁺ govern the actin-binding activities of gelsolin. In contrast, micromolar and millimolar concentrations of calcium ions are required for villin to exhibit capping and severing, respectively. However, after tyrosine phosphorylation, villin can sever actin filaments even at nanomolar Ca²⁺ concentrations (11). Furthermore, although the actin-severing ability of the N-terminal half of villin is calcium-dependent, that by the N-terminal half of gelsolin is not. In contrast, the binding of G-actin of the C-terminal half of both villin and gelsolin requires Ca²⁺. Creation of hybrid proteins demonstrated that the domains of villin and gelsolin are not interchangeable (12).Abundant x-ray crystallographic structural information exists for gelsolin, including the calcium ion-free (Ca²⁺-free), inactive structure of the intact protein (13), the activated N- and C-terminal halves, each in a bimolecular complex with actin (7, 14), and the activated C-terminal half on its own (15, 16). Structural data for intact villin are unavailable and are limited to fragment V1 (17), solved using NMR methods, and the HP domain, solved by NMR and x-ray crystallography (18, 19). NMR experiments also indicate that HP is connected to V6 by a 40-residue disordered linker. As a result, HP has been proposed to bind actin independently of the remainder of the protein (10).In this report, we present the structure of Ca²⁺-free, isolated villin V6, which exhibits a typical gelsolin domain fold. The long helix in V6 in this structure is straight, unlike the corresponding helix in G6 of intact Ca²⁺-free gelsolin, which is bent, and only straightens on calcium activation of the intact protein. Hence, V6 appears to be in an active conformation in the absence of Ca²⁺. Molecular dynamics simulations indicate that the preferred state of the long helix is also straight for isolated G6 in the absence of Ca²⁺. Furthermore, they suggest a bistable mechanism of helix conformational change regulated by the presence of the remaining domains, by calcium ions, and by other interactants. We therefore propose a mechanism for the gelsolin family proteins whereby Ca²⁺ triggers the straightening of the domain 6 helix in the native conformation of the inactive proteins to propagate more widespread conformational changes.     

Gelsolin: calcium- and polyphosphoinositide-regulated actin-modulating protein

Receptor-mediated stimulation induces massive actin polymerization and cyto-skeletal reorganization. The activity of a potent actin-modulating protein, gelsolin, is regulated both by Ca²⁺ and polyphos-phoinositides, and it may have a pivotal role in restructuring the actin cytoskeleton in response to agonist stimulation. Structure-function analysis of gelsolin has (1) indicated that its NH₂-terminal half is primarily responsible for modulating actin filament length and polymerization; and (2) elucidated mechanisms by which Ca²⁺ and phospholipids may regulate such functions. Gelsolin is functionally and structurally similar to villin, another Ca²⁺-activated actin-severing protein found in microvilli, suggesting that gelsolin may be a prototype of this family of actin-modulating proteins. A molecular variant of gelsolin is secreted and may be involved in the clearance of actin filaments released during tissue damage. The two forms of gelsolin are encoded by a single gene, and distinct messages are derived by alternative message splicing.     

Arabidopsis VILLIN1 and VILLIN3 Have Overlapping and Distinct Activities in Actin Bundle Formation and Turnover

Actin filament bundles are higher-order cytoskeletal structures that are crucial for the maintenance of cellular architecture and cell expansion. They are generated from individual actin filaments by the actions of bundling proteins like fimbrins, LIMs, and villins. However, the molecular mechanisms of dynamic bundle formation and turnover are largely unknown. Villins belong to the villin/gelsolin/fragmin superfamily and comprise at least five isovariants in Arabidopsis thaliana. Different combinations of villin isovariants are coexpressed in various tissues and cells. It is not clear whether these isovariants function together and act redundantly or whether they have unique activities. VILLIN1 (VLN1) is a simple filament-bundling protein and is Ca²⁺ insensitive. Based on phylogenetic analyses and conservation of Ca²⁺ binding sites, we predict that VLN3 is a Ca²⁺-regulated villin capable of severing actin filaments and contributing to bundle turnover. The bundling activity of both isovariants was observed directly with time-lapse imaging and total internal reflection fluorescence (TIRF) microscopy in vitro, and the mechanism mimics the “catch and zipper” action observed in vivo. Using time-lapse TIRF microscopy, we observed and quantified the severing of individual actin filaments by VLN3 at physiological calcium concentrations. Moreover, VLN3 can sever actin filament bundles in the presence of VLN1 when calcium is elevated to micromolar levels. Collectively, these results demonstrate that two villin isovariants have overlapping and distinct activities.     

Interaction of maize actin-depolymerising factor with actin and phosphoinositides and its inhibition of plant phospholipase C.

We have previously reported the isolation of three Zea mays genes that encode actin-depolymerising factors/cofilins, a family of low molecular weight actin regulating proteins. In the present study, we have characterised one of these proteins, ZmADF3. We report that ZmADF3 binds G-actin with a 1:1 stoichiometry, and that the interaction with F-actin is pH-sensitive. ZmADF3 co-sediments mainly with F-actin at pH 6.0 and mainly with G-actin at pH 9.0. This response is more similar to that of vertebrate cofilin and ADF than to that of Acanthamoeba actophorin which, although more similar in primary sequence to ZmADF3, is not pH sensitive. However, ZmADF3 requires a more basic environment to depolymerise actin relative to either vertebrate ADF or cofilin. Filaments decorated with ZmADF3 at low pH are very rapidly depolymerised upon raising the pH, which is consistent with a severing mechanism for the disruption of actin filaments. Also, we demonstrate that ZmADF3 binds specific polyphosphatidylinositol lipids, especially phosphatidylinositol 4,5-bisphosphate (PIP₂), and we show that this binding inhibits the actin-depolymerising function of ZmADF3. Moreover, we show that a consequence of ZmADF3 binding PIP₂ is the inhibition of the activity of polyphosphatidylinositol specific plant phospholipase C, indicating the possibility of reciprocal modulation of this major signalling pathway and the actin cytoskeleton.     

The 135 kDa actin-bundling protein fromLilium longiflorum pollen is the plant homologue of villin

Summary Actin microfilaments, which are essential for cell growth and cytoplasmic streaming in pollen tubes, are closely dependent on actin-binding proteins for their organization and regulation. We have purified the plant 135 kDa actin-bundling protein (P-135-ABP) fromLilium longiflorum pollen and determined that its amino acid composition is highly similar to members of the villin-gelsolin family of proteins. We used antibodies against P-135-ABP to probe an expression cDNA library ofL. longiflorum pollen and isolated a full-length clone (ABP135) that corresponds to a 106 kDa polypeptide. The deduced amino acid sequence ofABP135 shows homology with members of the villin-gelsolin family of proteins and contains the characteristic six repeats of this family, as well as an extended carboxy-terminal domain that includes the villin headpiece preceded by a highly variable region. Using two-dimensional polyacrylamide gel electrophoresis we detected at least 5 isoforms of P-135-ABP, with isoelectric points (pI) ranging between 5.6 to 5.9. The most abundant P-135-ABP isoform has a pI of 5.8, closely approximating the pI predicted from the deducedABP135 amino acid sequence. These data, together with the partial amino acid sequence from a proteolytic peptide of the protein, indicate that P-135-ABP is a plant villin. Immuno-detection of Lilium villin in rapidly frozen pollen tubes localized it to actin bundles. Lilium villin is also ubiquitously expressed in all tissues tested. Since villins, like gelsolins, are also Ca²⁺-dependent severing, capping, and nucleating proteins, Lilium villin may participate in F-actin fragmentation and nucleation in the apex of the pollen tube where there is steep Ca²⁺ gradient.Abbreviations BMM butyl methyl-methacrylate - PPI polyphos-phoinositides - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis