Twinfilins are conserved actin‐binding proteins composed of two actin depolymerizing factor homology (ADF‐H) domains. Twinfilins are involved in diverse morphological and motile processes, but their mechanism of action has not been elucidated. Here, we show that mammalian twinfilin both sequesters ADP‐G‐actin and caps filament barbed ends with preferential affinity for ADP‐bound ends. Twinfilin replaces capping protein and promotes motility of N‐WASP functionalized beads in a biomimetic motility assay, indicating that the capping activity supports twinfilin's function in motility. Consistently, in vivo twinfilin localizes to actin tails of propelling endosomes. The ADP‐actin‐sequestering activity cooperates with the filament capping activity of twinfilin to finely regulate motility due to processive filament assembly catalyzed by formin‐functionalized beads. The isolated ADF‐H domains do not cap barbed ends nor promote motility, but sequester ADP‐actin, the C‐terminal domain showing the highest affinity. A structural model for binding of twinfilin to barbed ends is proposed based on the similar foldings of twinfilin ADF‐H domains and gelsolin segments.
Twinfilin is an evolutionarily conserved actin‐binding protein involved in motile and morphological processes from yeast to mammals. Twinfilin plays a nonessential regulatory role in turnover of cortical actin patches in Saccharomyces cerevisiae (Goode et al, 1998), is required for developmental processes in Drosophila (Wahlstrom et al, 2001), and is important in clathrin‐mediated endocytosis and distribution of endocytic organelles in mammalian cells (Pelkmans et al, 2005). At least in yeast and mammals, twinfilin is a highly abundant protein and it localizes to regions of rapid actin dynamics in cells (Vartiainen et al, 2000, 2003; Palmgren et al, 2001).
Twinfilin is composed of two actin depolymerizing factor (ADF) homology (ADF‐H) domains (Paavilainen et al, 2002). Like ADF, twinfilin shows preferential binding to ADP‐actin, but at variance with ADF, it does not bind F‐actin but instead makes a 1:1 complex with G‐actin only (Ojala et al, 2002). Hence, twinfilin cannot act like ADF by accelerating filament treadmilling. Twinfilin inhibits actin polymerization, likely by sequestering G‐actin (Ojala et al, 2002). Twinfilin also interacts with capping protein (CP) and at least in yeasts S. cerevisiae and Shizosaccharomyces pombe this interaction is essential for twinfilin's localization to the cortical actin cytoskeleton, although binding of twinfilin leaves the function of CP unchanged (Vartiainen et al, 2003; Falck et al, 2004; Kovar et al, 2005). However, G‐actin sequestering and CP binding cannot satisfactorily explain how twinfilin contributes to actin dynamics and various motile processes in cells. Furthermore, the function of the N‐terminal ADF‐H domain of mammalian twinfilin has remained enigmatic, because both the CP binding and G‐actin sequestering activities were shown to reside at the C‐terminal half of the protein (Ojala et al, 2002; Falck et al, 2004), while G‐actin binding by other twinfilins requires both ADF‐H domains.
Here we analyze the effects of mammalian twinfilin on actin assembly dynamics in vitro and using biomimetic actin‐based motility assays (Loisel et al, 1999; Romero et al, 2004). We demonstrate that it is by capping the barbed ends of filaments that mammalian twinfilin regulates motility, and show that both ADF‐H domains are required for this activity. Our data also suggest that this property, which adds to the actin‐sequestering activity of twinfilin, emerged at the vertebrate stage in evolution.
Yeast, Drosophila and mouse twinfilins sequester ADP‐G‐actin in solutions of F‐actin assembled at steady state in ATP
All twinfilins bind ADP‐G‐actin with higher affinity than ATP‐G‐actin; however, in the ATP‐rich physiological medium, the form of actin that is sequestered by twinfilin is not known. The following experiment demonstrates that essentially ADP‐G‐actin is sequestered by yeast or mouse twinfilin (Figure 1, the same result was established for Drosophila twinfilin in an independent experiment). Filament growth was seeded by gelsolin‐actin seeds in the presence or absence of twinfilin or thymosin β4 as a regular sequesterer of ATP‐G‐actin specifically (Carlier et al, 1993). Growth proceeded monotonously up to a steady‐state plateau for actin alone and to a lower plateau in the presence of thymosin β4. In contrast, in the presence of twinfilin, the initial growth was followed by extensive depolymerization. This biphasic behavior is not compatible with sequestration of ATP‐G‐actin only. Since ATP is hydrolyzed as filament growth proceeds, the presence of dissociable ADP‐actin during growth at filament pointed ends allows twinfilin to promote endwise depolymerization of filaments through tight binding and sequestration of ADP‐G‐actin. Actin is sequestered mainly in ADP‐bound form because (1) twinfilin has ∼10‐fold higher affinity for ADP‐ than for ATP‐actin (Ojala et al, 2002); (2) nucleotide exchange is very slow in twinfilin‐actin (Goode et al, 1998; Vartiainen et al, 2003); (3) twinfilin does not dissociate fast enough from actin to recycle ATP‐actin (the dissociation rate constant for mouse twinfilin‐1:ADP‐G‐actin complex under physiological ionic conditions at 20°C is 1.8 s−1 (Ojala et al, 2002); (4) twinfilin‐ADP‐actin, at variance with ADF‐ADP‐actin (Carlier et al, 1997), does not polymerize.
Twinfilin caps filament barbed ends
The effect of mouse twinfilin‐1 on actin dynamics at the two ends of actin filaments was analyzed. Twinfilin inhibited growth totally at either end in a saturation manner (Figure 2A). Sequestering of ATP‐G‐actin by twinfilin well accounted for inhibition of pointed end growth. In addition, twinfilin showed a slight pointed end nucleation activity in the range of 0 to 1 μM. The data were consistent with the formation of a twinfilin‐ATP‐G‐actin complex (KT of about 2–3 μM) that did not support pointed end growth. The value of KT is similar to the one derived from the two‐fold increase in the fluorescence of pyrenyl‐labeled ATP‐G‐actin upon binding twinfilin (Falck et al, 2004). In contrast, twinfilin inhibited barbed end growth in a range of concentrations substoichiometric to G‐actin. These data are not consistent with the sequestration of actin by twinfilin observed at pointed ends and suggest that twinfilin could inhibit filament growth by blocking barbed ends.
Like other barbed end CPs, twinfilin inhibited dilution‐induced depolymerization of F‐actin at the barbed ends (Figure 2B). The affinity of twinfilin for barbed ends was one order of magnitude higher in the depolymerization (KF=13 nM) than in the growth assay (KF=0.1–0.3 μM with different preparations of twinfilin), indicating that twinfilin caps barbed ends with a higher affinity when terminal F‐actin subunits have bound ADP (in depolymerizing regime) than ATP or ADP‐Pi (growth regime). Consistently, dilution‐induced depolymerization of AMPPNP‐F‐actin in an F buffer containing AMPPNP (a non‐hydrolyzable analog of ATP) was inhibited by twinfilin with a 10‐fold lower affinity (KF=150 nM, Figure 2B).
The pointed end nucleating activity of twinfilin observed in growth assays (Figure 2A) is fully consistent with the barbed end capping activity of twinfilin.
To evaluate the barbed end capping of twinfilin independently of its G‐actin sequestering activity, we measured the effect of twinfilin on barbed end growth from profilin‐actin (Figure 2C). Profilin, which has a 20‐fold higher affinity than twinfilin for ATP‐G‐actin, was used at a much larger concentration than twinfilin, so that all G‐actin is profilin‐actin (consistently, the data were identical in the presence of a twice larger amount of profilin). The rate of barbed end growth from profilin‐actin is only 30% lower than from G‐actin (Gutsche‐Perelroizen et al, 1999). Once normalized, the dependence of the growth rate on twinfilin concentration was almost identical in the absence or presence of profilin, testifying that the capping activity of twinfilin accounts for about 80% of the inhibition of barbed end growth. The data were analyzed (see Materials and methods) assuming that twinfilin caps barbed ends, and the twinfilin–ATP–G‐actin complex does not assemble at either barbed or pointed ends. The best fit was obtained for values of KT of 3 μM for binding of twinfilin to ATP‐G‐actin and KF of 0.2 μM for binding of twinfilin‐actin to barbed ends. In the presence of an excess profilin, the data were well fitted assuming that twinfilin only caps barbed ends (KF=0.6 μM).
The effect of twinfilin on the steady state of actin assembly was measured when barbed ends were free or gelsolin‐capped (Figure 3A). Twinfilin caused a linear decrease in F‐actin and eventually totally depolymerized F‐actin. When barbed ends were free, the data showed an initial steep decline until they reached and superimposed the straight line observed for depolymerization of gelsolin‐capped filaments. A comprehensive interpretation of all data in Figures 1, 2 and 3 is that twinfilin caps barbed ends (the steep initial decline in F‐actin is due to the increase in critical concentration) and sequesters G‐actin mainly in the ADP‐bound form, thus resulting in identical depolymerization in the presence or absence of gelsolin.
The effect of profilin on F‐actin at steady state in the presence of twinfilin was measured with free or capped barbed ends (Figure 3B). When barbed ends were capped, profilin and twinfilin sequestered G‐actin in an additive manner. When barbed ends were free, addition of increasing amounts of profilin failed to cause total depolymerization of F‐actin, in the presence as well as in the absence of twinfilin. Instead, in the presence of twinfilin, F‐actin was maintained by profilin‐actin at a steady‐state concentration. The steady level of F‐actin at saturation by profilin decreased upon increasing the concentration of twinfilin (data not shown). These data indicate that twinfilin fails to cap 100% of the barbed ends. Hence, profilin does not sequester G‐actin. The few barbed ends that remain free are maintained in a dynamic state by profilin‐actin. In other words, twinfilin and profilin synergize in tuning the steady state of actin assembly. As will be explored in greater detail below, the maintenance of free barbed ends arises from the actin‐sequestering activity of twinfilin.
Role of twinfilin in actin‐based motility
The role of mammalian twinfilin in motility was addressed using a biomimetic motility assay. N‐WASP‐coated beads were placed in a motility mix (Loisel et al, 1999) containing actin, Arp2/3, a capping protein (e.g. gelsolin), ADF and profilin. These proteins are confirmed to be essential in lamellipodium motility (Rogers et al, 2003). Twinfilin was added to the standard medium, or challenged for its ability to replace a component of the medium.
Addidion of twinfilin to the optimized motility medium did not affect the rate of propulsion nor the morphology of actin tails (Figure 4A and D). Twinfilin was unable to replace ADF in the motility mix, thus confirming biochemical data (Ojala et al, 2002). In contrast, twinfilin replaced gelsolin or CP and induced actin‐based propulsion of beads in a medium containing no capper, as efficiently as CP or gelsolin (Figure 4B and C and Supplementary movie M1). On addition of increasing amounts of twinfilin, as observed with gelsolin (Pantaloni et al, 2000), bead‐associated actin structures changed from asters to actin tails with a fishbone pattern, followed by regular actin tails and rapid movement (Figure 4B). In the absence of both ADF and capper, only few beads (10%) moved very slowly (0.37±0.21 μm/min) and the actin tails elongated without depolymerizing; addition of either twinfilin or CP or gelsolin caused an identical slight increase in velocity (Figure 4C). In summary, twinfilin behaves as a bona fide barbed end capper in the above assays.
Twinfilin is known to bind CP, but the functional significance of the interaction is unknown. To address this issue, twinfilin was added to a motility medium containing suboptimal amounts of either CP, gelsolin or CapG as standard cappers (Figure 4D). Twinfilin supplemented the low levels of any one of the three cappers and enhanced motility with equal efficiency, demonstrating that the effect of twinfilin in motility is independent of its interaction with CP. Consistently, addition of either gelsolin or CP to a suboptimal amount of twinfilin increases velocity identically (Figure 4E). At this point, the physiological significance of the interaction between twinfilin and CP remains enigmatic.
Barbed end capping and G‐actin sequestering activities of mouse twinfilin finely tune formin‐induced processive filament assembly
Actin‐based motile processes are also driven by formins, which catalyze rapid processive barbed end assembly of filaments. Capping proteins play different roles in N‐WASP‐Arp2/3 and formin machineries. They are essential for maintenance of a densely branched actin network generated by WAVE‐ or N‐WASP‐Arp2/3 (Wiesner et al, 2003), but cause arrest of formin‐induced movements by binding to barbed ends in competition with formins (Higashida et al, 2004; Romero et al, 2004). We addressed the role of twinfilin in formin‐induced motility in comparison with CP, using the FH1–FH2 domain of mDia1 (Figure 5). FH1–FH2‐coated beads initiated processive filament assembly in a solution of actin and profilin (Romero et al, 2004) and displayed a high density of attached filaments after 2 h (Figure 5A, left panel). When twinfilin was present, after 2 h about 100‐fold less filaments were attached (6±3 filaments per bead, average of 20 beads), while many filaments are present in the solution (Figure 5A, right panel). The time course of filament dissociation from the bead after addition of twinfilin (Figure 5B and Movie M2) confirms that twinfilin caps filaments in competition with formin; however, processive assembly of a small number of filaments (0.9 μm/min) is still observed at late times.
In a second experiment, FH1–FH2‐coated beads moved rapidly in a solution of F‐actin maintained at a steady state in the presence of profilin and ADF. CP, like gelsolin (Romero et al, 2004), transiently enhanced propulsion, by increasing the steady‐state concentration of G‐actin linked to barbed end capping in the medium, and eventually caused arrest of movement due to capping of the formin‐bound barbed ends. Addition of twinfilin also increased the rate of propulsion, consistent with twinfilin capping the barbed ends of filaments in the medium; however, movement was never arrested, even though the number of filaments that formed the actin tail decreased (Figure 5C and D). The phenotype of maintained movement differentiates twinfilin from other barbed end capping proteins. On further increasing twinfilin up to concentrations that caused complete depolymerization of filaments in the medium, efficient processive actin assembly from FH1–FH2 beads resumed, large actin tails were again formed causing bead propulsion (Figure 5C, bottom panel).
A straightforward explanation for the above observations is derived from twinfilin's additive ADP‐actin sequestering and barbed end capping activities. The initial increase in velocity and concomitant decrease in the number of bead‐attached filaments is consistent with the capping activity of twinfilin. In this experimental context, twinfilin additionally causes depolymerization of filaments present in the motility medium and increasingly sequesters ADP–G‐actin. The sequestering activity of twinfilin buffers the concentration of free twinfilin and establishes a ‘ground level’ of free barbed ends, resulting in maintenance of active processive barbed end growth and motility of formin‐coated beads. This effect is quantitatively modeled in Figure 5E (see Materials and methods for model). When enough twinfilin has been added to totally depolymerize the filaments, which were initially maintained at a steady state in the motility medium, ADP‐actin is not longer produced. ATP‐G‐actin then forms, it binds less tightly than ADP‐actin to twinfilin and interacts with profilin to feed rapid processive growth off the formin‐coated beads.
Both ADF‐H domains of twinfilin are required for barbed end capping
Twinfilin is composed of two actin‐binding ADF‐H domains separated by a short linker and followed by a 35‐residue C‐terminal extension that binds CP (Falck et al, 2004). The strong G‐actin binding and sequestering activity reside in twinfilin's C‐terminal ADF‐H domain, whereas the N‐terminal domain has a relatively modest affinity for G‐actin (Ojala et al, 2002). Insight into the putative role of each of the two ADF‐H domains in the barbed end capping activity of full‐length mouse twinfilin was obtained by assaying the effect of each domain on actin dynamics at barbed and pointed ends. Constructs used included the N‐terminal ADF‐H domain with the linker, and the C‐terminal ADF‐H domain with or without the linker. All three ADF‐H constructs inhibited barbed and pointed end growth with almost identical efficiencies, consistent with sole ATP‐G‐actin sequestering activity and absence of barbed end capping activity. The N‐terminal ADF‐H domain showed about 10‐fold lower affinity than the C‐terminal ADF‐H domains for ATP‐G‐actin (Figure 6A). Steady‐state measurements of F‐actin confirmed that both the N‐terminal and C‐terminal ADF‐H domains caused depolymerization of F‐actin (Figure 6B and C). Consistent with the polymerization assays, neither the N‐terminal nor the C‐terminal ADF‐H domains of twinfilin affected actin‐based motility of N‐WASP‐coated beads in the standard motility assay, nor were they able to induce bead movement, at concentrations up to 2 μM, in a medium containing no CP (Supplementary Figure S1). Neither one was able to replace ADF in the motility assay.
In conclusion, the isolated ADF‐H domains of twinfilin possess the actin‐sequestering but not the capping activity of twinfilin and fail to act like twinfilin in motility. Thus, the barbed end capping activity of twinfilin requires the two ADF‐H domains and is essential in motile processes.
Mouse twinfilin contributes to actin‐dependent motility of endocytic vesicles
In vivo experiments addressed the physiological consequences of the barbed end capping activity of twinfilin in motility. Twinfilin localizes to the regions of rapid actin dynamics such as the leading edge of motile cells, but its possible contribution to motile processes has not been demonstrated. Instead, RNAi studies on Drosophila S2 cells provided evidence that twinfilin is not crucial to actin‐dependent lamella formation (Rogers et al, 2003). Because twinfilin regulates the motility of N‐WASP‐coated beads (Figure 4) and because N‐WASP is involved in actin‐based vesicular transport (Innocenti et al, 2005), we examined twinfilin's contribution to transferrin uptake. In NIH 3T3 cells, endogenous twinfilin was found in dot‐like structures that co‐localized with actin tails of transferrin‐positive particles. Virtually, all (>95%) transferrin particles that were positive for F‐actin, labeled with twinfilin. In contrast, twinfilin was absent from transferrin particles that did not co‐localize with F‐actin, indicating that twinfilin is specifically associated with endosomes that are driven by actin‐based motility (Figure 7A). Together with recent studies showing that subcellular distribution of endocytotic vesicles was severely defective in twinfilin knockdown cells (Pelkmans et al, 2005), these data suggest that twinfilin is involved in actin‐driven internalization or motility of endocytic vesicles.
To elucidate the specific role of twinfilin in endocytosis, we examined the effects of various twinfilin constructs on transferrin uptake. Myc‐tagged twinfilin constructs were transfected to NIH 3T3 cells and expressed for 16 h under CMV promoter. Based on immunofluorescence experiments using an anti‐myc antibody, all constructs were expressed at comparable levels in cells. Overexpression of wild‐type twinfilin did not significantly affect transferrin uptake (Figure 7C). However, overexpression of either twinfilin's isolated N‐terminal ADF‐H domain or C‐terminal half (including the C‐terminal ADF‐H domain and the tail‐region) interfered with subcellular distribution of transferrin vesicles. Transferrin showed perinuclear accumulation in wild‐type cells, but punctate cytoplasmic staining in cells overexpressing twinfilin's N‐terminal or C‐terminal ADF‐H domain. The efficiency of transferrin uptake was also severely reduced in these cells as compared to cells overexpressing wild‐type twinfilin (Figure 7B and C). These data suggest that twinfilin's isolated ADF‐H domains, which do not cap barbed ends, inhibit endocytosis by depolymerizing F‐actin to a detrimental extent, due to their actin monomer sequestering activity. In support to this view, the effect of the isolated domains on endocytosis is similar to the effect of Latrunculin A, which efficiently sequesters G‐actin and inhibits endocytosis (Fujimoto et al, 2000). Twinfilin, in contrast, does not inhibit endocytosis when it is overexpressed, because it not only sequesters G‐actin but also caps the filaments. While the failure to cap barbed ends like full‐length twinfilin, and the known actin‐sequestering activity of the isolated domains of twinfilin are sufficient to account for the results, we cannot eliminate other not known effects of these domains.
Yeast and Drosophila twinfilins sequester ADP‐G‐actin but do not cap filament barbed ends
We examined whether the twinfilins of lower eukaryotes like S. cerevisiae or Drosophila also possess a weak barbed end capping activity in addition to their known G‐actin sequestering activity. S. cerevisiae and Drosophila twinfilins both failed to show the high‐affinity inhibition of barbed end growth and depolymerization that characterized the barbed end capping activity of mammalian twinfilin. Only low‐affinity sequestration of ATP‐G‐actin was measured in a range of 0–50 μM (Table I). Finally, the yeast and fly twinfilins did not induce actin‐based motility of N‐WASP‐coated beads in the reconstituted motility assay in the absence of CP (Supplementary Figure S2). In steady‐state measurements of F‐actin assembled in the presence or absence of gelsolin, yeast twinfilin depolymerized actin by sequestration of ADP‐actin, exactly as found for mouse twinfilin (displayed in Figure 3), and in agreement with data shown in Figure 1.
Twinfilin has unique original properties as compared to known actin binding proteins. All twinfilins, from yeast to mammals, sequester ADP‐G‐actin with high affinity under physiological conditions, that is, when filaments are assembled in the presence of ATP. Mammalian twinfilin, in addition, caps filament barbed ends with a higher affinity for ADP‐bound terminal subunits. The barbed end cappping activity develops in the range of physiological concentrations of twinfilin (1–5 μM, Vartiainen et al, 2003). Using yeast twinfilin and the isolated ADF‐H domains of mouse twinfilin as references that only sequester G‐actin, we show that the barbed end capping activity of mouse twinfilin is essential for its role in motile processes. In vitro motility assays based on N‐WASP‐Arp2/3 show that twinfilin's effect is mediated by its capping activity. Similarly, we show that twinfilin's role in internalization/transport of vesicles, which is also N‐WASP‐Arp2/3 dependent (Innocenti et al, 2005), is consistent with a capping function. If twinfilin simply sequestered actin, the complex would be freely diffusable and twinfilin would not localize in actin tails of endocytic vesicles. Thus, twinfilin is associated to F‐actin either by capping barbed ends itself or by binding CP at barbed ends. In the future, twinfilin mutants with specific defects in barbed end capping will have to be identified. These site‐directed mutants can then be used in RNAi and rescue experiments to confirm the role of twinfilin's activities in motile processes.
The barbed end capping activity of twinfilin emerged late in evolution. However, this conclusion relies on results obtained with skeletal muscle actin. The possibility that yeast and Drosophila twinfilins cap the barbed ends of filaments only when they are assembled from yeast or Drosophila actins, respectively, is not totally excluded. The evolution of twinfilin activity at the vertebrate stage correlates with the ability of isolated ADF‐H domains of mouse twinfilin to sequester actin individually, while the two ADF‐H domains of yeast twinfilin are required to sequester ADP‐G‐actin (Goode et al, 1998; Palmgren et al, 2001).
Many barbed end CPs are involved in motile processes. Twinfilin adds up to the growing family of proteins that control actin dynamics at barbed ends. Eps8 caps barbed ends in a signal‐controlled, spatially defined manner, and formins switch from leaky capping to processive growth catalysis in a profilin‐dependent manner (Disanza et al, 2004; Kovar and Pollard, 2004; Romero et al, 2004). Twinfilin therefore is not essential, but may help adjust the extent of barbed end capping to the optimum level for motility. Identically cumulative capping properties are at work when twinfilin is added to suboptimal levels of either CP or CapG or gelsolin.
Uniquely, twinfilin has both actin sequestering and barbed end capping activities, and it sequesters ADP‐G‐actin specifically. These distinctive properties have interesting functional consequences. First, the ADP‐G‐actin sequestering and barbed end capping activities develop concomitantly, which limits the extent of barbed end capping and buffers free barbed ends at a low level (Figure 6). Twinfilin thus allows the maintenance of a basal level of formin‐based processive filament assembly in a biomimetic assay and of dynamic barbed ends in the presence of profilin (Figure 3B). This property is specific to twinfilin, is not observed with standard CPs and may have physiological relevance. Second, in sequestering ADP‐G‐actin specifically, twinfilin builds a pool of unassembled actin, hence decreases the average length of filaments. The size of this pool is not governed by the concentration of free ATP‐G‐actin at steady state, as in the case of β‐thymosins, which sequester ATP‐G‐actin specifically (Carlier et al, 1993). Instead, the amount of ADP‐G‐actin sequestered by twinfilin at steady state depends on the number of filaments (Pantaloni et al, 1984). Hence, twinfilin promotes the maintenance of actin meshworks formed of many capped short filaments, thus regulating filament length.
The structural mechanism of barbed end capping by twinfilin is an open issue. Assuming a single molecule of twinfilin caps a barbed end by binding to the terminal actin subunit, the two ADF‐H domains of twinfilin, which when isolated bind G‐actin in competition with ADF, must interact with different regions of this subunit. Remarkably, the two ADF‐H domains of twinfilin display structural similarity to gelsolin domains (r.m.s.d. value of 3.0 Å for twinfilin's N‐terminal domain and gelsolin segment‐1), although these proteins do not display detectable sequence homology to each other (Figure 8). The six structurally related domains of gelsolin are involved in actin filament severing and capping through sequential interactions with distinct interfaces of actin filament subunits (Choe et al, 2002; Burtnick et al, 2004). Twinfilin may cap a barbed end by a similar mechanism to gelsolin S1–S2 fragment (reviewed in Weeds and Maciver, 1993). Kinetic studies of binding of twinfilin and its isolated domains to G‐actin (Ojala et al, 2002) as well as the present data show that the C‐terminal ADF‐H domain has a higher affinity for actin, and may bind actin like ADF. Our results thus suggest the following general model for barbed end capping by proteins that have repeated modules. The N‐terminal domain of twinfilin binds first to the barbed face of actin subdomain 1 exposed at the end of the filament, thus allowing positioning of the C‐terminal domain at the ADF/cofilin binding site at the outside of the filament (Figure 8C). Structural analysis of twinfilin and its individual ADF‐H domains in complex with actin (manuscript in preparation) should reveal the individual roles of the two ADF‐H domains in barbed end capping.
Whether other ADF‐H containing proteins act at barbed ends like twinfilin is an issue of structural, functional and evolutional interest. Coactosin and Abp1p are the two other members of the ADF‐H family. Coactosin consists of a single ADF‐H domain that binds F‐actin, shows a fold similar to gelsolin and villin (Liu et al, 2004) and prevents binding of CPs to barbed ends (Rohrig et al, 1995). The binding of actin to the ADF‐H domain of Abp1p is required for the Arp2/3‐dependent filament branching activity of Abp1p (Goode et al, 2001). The present data open a new perspective on the possible function of the ADF‐H domain inserted in a modular protein.
Materials and methods
Actin was purified from rabbit muscle and pyrenyl‐labeled (Egile et al, 1999). Recombinant S. cerevisiae and Drosophila twinfilins were purified (Goode et al, 1998; Wahlstrom et al, 2001). His‐tagged full‐length mouse twinfilin‐1 and its C‐terminal (Twf169–350 and Twf140–350) ADF‐H domains were expressed in Escherichia coli and purified (Vartiainen et al, 2003), and its N‐terminal ADF‐H domain (Twf1–174) was expressed as GST‐fusion protein, purified, GST was removed by thrombin digestion (Ojala et al, 2002). Recombinant human ADF, gelsolin (Carlier et al, 1997), CP (Falck et al, 2004) and mDia1 FH1–FH2 domain (Romero et al, 2004) were purified as described. Profilin was purified from bovine spleen (Gutsche‐Perelroizen et al, 1999), Arp2/3 complex from bovine brain (Egile et al, 1999). Human his‐tagged N‐WASP was expressed in Sf9 cells.
Actin polymerization assays
Actin assembly was monitored by the increase in pyrenyl‐actin fluorescence (excitation and emission wavelengths 366 and 407 nm, respectively). Initial rates of barbed end growth were measured using spectrin‐actin seeds (Casella et al, 1986). Gelsolin‐actin complexes (0.4 μM gelsolin and 1 μM CaATP‐G‐actin mix) were used to seed pointed end growth. Growth assays were monitored using 2.5 μM G‐actin (5% pyrenyl‐labeled) and twinfilin as indicated. Only fresh solutions of twinfilin were used, since the protein loses rapidly actin‐binding activity upon storage on ice. The initial rate of filament growth was normalized to the value of 1 measured in the absence of twinfilin.
Steady‐state measurements of F‐actin were carried out by measuring the fluorescence of pyrenyl‐labeled F‐actin incubated overnight at 4°C with twinfilin, profilin and gelsolin as indicated.
Barbed end growth assays. Data were analyzed using models in which twinfilin (Tw) binds ATP‐G‐actin (T) in a 1:1 nonpolymerizable TTw complex with an equilibrium dissociation constant KT and caps barbed ends forming a FTw complex with an equilibrium dissociation constant KF. The following equations were used.
The rate of filament growth from spectrin‐actin seeds is where [F] and [F0] are the concentrations of free barbed and pointed ends, [T0] is the total concentration of ATP‐G‐actin. TCB and TCP are the critical concentrations at the barbed and pointed ends respectively. To simplify the resolution of the equation, we will assume below that TCB and TCP are negligible as compared to the total G‐actin concentration [T0], and that [FTw] is negligible as compared to free (Tw) and G‐actin‐bound (TTw) twinfilin. The total concentrations of filaments and twinfilin are [F0] and [Tw0]. Equation (1) can be written as In the absence of twinfilin, the growth rate is V0: where k+P=α k+BEquation (2) then becomes where In the presence of profilin in large amounts, twinfilin only caps barbed ends and no growth takes place at pointed ends. Then Equation (4) reduces to Steady‐state motility assays. The effect of twinfilin (barbed end capping+actin sequestration) on the movement of formin‐coated beads was accounted for by the combination of the ADP‐G‐actin sequestering and barbed end capping activities of twinfilin, as follows. The model stipulates that filaments treadmill rapidly, ADP‐G‐actin (D) is produced by rapid pointed end depolymerization due to the effect of ADF (Carlier et al, 1997), ATP‐G‐actin (T) is produced from ADP‐actin via nucleotide exchange with rate constant ke, twinfilin (Tw) sequesters ADP‐ and ATP‐G‐actin with equilibrium dissociation constants KD and KT, and caps barbed ends with equilibrium dissociation KF. At steady state, where k+B, k+P, k−B, k−P are the rate constants for association of ATP‐actin to barbed ends of ADP‐actin to pointed ends, dissociation of ATP‐actin from barbed ends and dissociation of ADP‐actin from pointed ends, respectively.
Motility assays were carried out as described (Wiesner et al, 2003; Romero et al, 2004). Carboxylated polystyrene microspheres (2 μm diameter, Polysciences Inc., 2% solids) were incubated with either 400 nM N‐WASP or 10 μM FH1–FH2 in Xb buffer (10 mM HEPES, pH 7.8, 0.1 M KCl, 1 mM MgCl2, 1 mM ATP, 0.1 mM CaCl2, and 0.01% NaN3) for 1 h on ice. BSA (10 mg/ml) was added for 15 min. Beads were washed, stored on ice in Xb buffer with 1 mg/ml BSA and used for 4–5 days.
The standard motility medium for N‐WASP‐coated beads consisted of 7 μM F‐actin in Xb buffer, 9 μM ADF, 2.4 μM profilin, 90 nM gelsolin, and 90 nM Arp2/3, except when indicated. The steady state of actin assembly was reached in 10 min. In the absence of ADF, steady state was reached in 6 h. Beads (0.02% solids final) were added to the steady motility medium. The medium for FH1FH2‐coated beads consisted of 7 μM F‐actin (5% rhodamine‐labeled)), 14 μM ADF, 4 μM profilin and twinfilin as indicated. Samples of 5 μl were placed between a slide and a coverslip. Valap‐sealed samples were observed in phase contrast or fluorescence microscopy (AX70, Olympus, equipped with a × 20 phase objective (NA 0.5) or a × 100 objective (NA 1.35), a motorized stage (Märzhäuser) and a camera (Cascade, Photometrics). Using Metamorph 6.0 (Universal Imaging Corp.) for microscope control and image acquisition, synchronous movies of up to five fields were recorded, following a dead time of about 10 min for selecting observation fields and entering their positions in the recognition‐based tracking program. About 10 moving beads were selected and tracked. Average velocities were calculated for each set of beads.
Myc‐tagged wild‐type mouse twinfilin‐1, the N‐terminal ADF‐H domain (Twf1–142) and the C‐terminal half (Twf169–350) constructs were expressed in NIH 3T3 cells and detected by immunofluorescence microscopy using a polyclonal anti‐myc‐antibody (Vartiainen et al, 2000). The efficiency of receptor‐mediated endocytosis in these cells was measured (Bertling et al, 2004). In co‐localization experiments, F‐actin and endogenous twinfilin were visualized using Alexa488‐phalloidin (Molecular Probes) and polyclonal anti‐twinfilin‐1 antibody (Vartiainen et al, 2003).
Supplementary data are available at The EMBO Journal Online.
Supplementary movie M1 [emboj7601019-sup-0001.mpg]
Supplementary movie M2 [emboj7601019-sup-0002.mpg]
Supplementary Material [emboj7601019-sup-0003.pdf]
We thank Robert Robinson for sending the gelsolin‐F‐actin model. PL is supported by Academy of Finland and Emil Aaltonen Foundation. MFC is supported in part by the Ligue Nationale contre le Cancer (équipe labellisée) and by a HFSP research grant RGP0072/2003‐C. SR is supported by a fellowship from the Ligue Nationale contre le Cancer.
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