* Dynamique du Cytosquelette, Laboratoire d'Enzymologie et Biochimie Structurales, Centre National de la Recherche
Scientifique, 91198 Gif-sur-Yvette Cedex, France; Laboratory of Plant Cell Biology, Institute of Molecular Agrobiology,
National University of Singapore, Singapore 118240; and § Laboratory of Plant Molecular Biology, Rockefeller University, New
York 10021
Actin-binding proteins of the actin depolymerizing factor (ADF)/cofilin family are thought to control actin-based motile processes. ADF1 from Arabidopsis thaliana appears to be a good model that is functionally similar to other members of the family. The function of ADF in actin dynamics has been examined using a combination of physical-chemical methods and actin-based motility assays, under physiological ionic conditions and at pH 7.8. ADF binds the ADPbound forms of G- or F-actin with an affinity two orders of magnitude higher than the ATP- or ADP-Pi- bound forms. A major property of ADF is its ability to enhance the in vitro turnover rate (treadmilling) of actin filaments to a value comparable to that observed in vivo in motile lamellipodia. ADF increases the rate of propulsion of Listeria monocytogenes in highly diluted, ADF-limited platelet extracts and shortens the actin tails. These effects are mediated by the participation of ADF in actin filament assembly, which results in a change in the kinetic parameters at the two ends of the actin filament. The kinetic effects of ADF are end specific and cannot be accounted for by filament severing. The main functionally relevant effect is a 25-fold increase in the rate of actin dissociation from the pointed ends, while the rate of dissociation from the barbed ends is unchanged. This large increase in the rate-limiting step of the monomer-polymer cycle at steady state is responsible for the increase in the rate of actin-based motile processes. In conclusion, the function of ADF is not to sequester G-actin. ADF uses ATP hydrolysis in actin assembly to enhance filament dynamics.
Actin filaments are a major cytoskeletal component of
eukaryotic cells. Rapid changes in the levels of
polymeric (F-) actin and monomeric (G-) actin are
involved in the morphological changes of living cells that
occur, in a spatially and temporally controlled fashion, in
response to environmental signals. Observation of actin
dynamics in motile cells indicates that not only are actin filaments actively polymerizing beneath the plasma membrane at the leading edge, but also the turnover of actin filaments is faster in the lamellipodia than in other regions of
the cell (Condeelis, 1993 A family of related actin-binding proteins, actin depolymerizing factor (ADF)/cofilin1, appear as choice candidates
for the control of actin-based motility processes in response to signaling (for review see Moon and Drubin, 1995 These conserved, essential proteins, initially characterized by their ability to depolymerize F-actin, possess the
unique property, among other G-actin-binding proteins,
to be regulated by reversible phosphorylation (Ohta et al.,
1989 In vitro studies of the interaction of ADF/cofilin with
actin have revealed a broad complexity of functional properties. These proteins are identified as G-actin-binding,
F-actin depolymerizing proteins; however, they have been
shown to bind also to F-actin and proposed to sever filaments in a pH-sensitive fashion. The severing activity is
thought to account for the ADF-induced rapid assembly
and disassembly of filaments, as well as for the rapid drop
in viscosity of F-actin solutions upon addition of ADF
(Yonezawa et al., 1985 The present work addresses the function of ADF in actin dynamics using physical-chemical methods and in vitro
motility assays, and Arabidopsis ADF1 is used as a model.
We show that the main function of ADF is to increase 25fold the turnover rate of actin filaments by changing the
kinetic parameters for actin assembly and disassembly in
an end-directed fashion. As a result, ADF increases the rate
of actin-based motility of Listeria monocytogenes in highly
diluted platelet extracts. ADF does not act as a G-actin sequestering protein and does not appear to fragment filaments in vitro, but it changes their hydrodynamic parameters, which may account for its effects on the viscosity of
F-actin solutions. Comparative assays carried out with other
ADFs confirm that these proteins all act as "actin dynamizing factors."
Proteins
Actin, purified from rabbit muscle acetone powder, was isolated as
CaATP-G-actin by gel filtration over Sephadex G-200 in G-buffer (5 mM
Tris Cl Recombinant ADF1 from Arabidopsis thaliana was prepared as follows. A cDNA clone 33D1T7 encoding a protein with homology to the
ADF/cofilin family was obtained from the Arabidopsis Biological Resources Center at the Ohio State University. We determined the entire
nucleotide sequence of both strands of the cDNA insert. The 0.69-kb
cDNA was found to encode a full-length protein designated ADF1. The
cDNA was expressed in Escherichia coli BL21DE3 strain by the use of
pET 16b vector (Studier et al., 1990 Sequence comparison of ADF1 with other members of the ADF/cofilin
family (actophorin from Acanthamoeba castellanii, yeast, Dictyostelium
discoideum, human cofilins) is displayed in Table I. ADF1 contains 139 amino acid residues, with a molecular mass of 16,113 D and an isoelectric
point of 7.08.
Table I.
Sequence Comparison of ADF1 from Arabidopsis thaliana with Other Members of the ADF/Cofilin Family
; Fechheimer and Zigmond, 1993
).
While it is well appreciated that G-actin-binding proteins
establish a pool of unassembled actin subunits ("sequestered actin") that is used in site-directed actin assembly
(Carlier and Pantaloni, 1994
; Sun et al., 1995
), the molecular mechanisms by which the local changes in critical concentration and the turnover rate of actin filaments are controlled in vivo remain largely unknown.
).
The recently solved tertiary structure of vertebrate ADF shows a folding similar to that of gelsolin segment-1, severin segment-2, and profilin (Hatanaka et al., 1996
).
; Agnew et al., 1995
). In all cases investigated, the activity of ADF/cofilins was inhibited by phosphorylation of
a serine in the NH2-terminal region. Rapid dephosphorylation occurs in response to stimuli. Consistently, ADF/cofilins are localized in ruffling membranes and at the leading edge of locomoting cells (Aizawa et al., 1995
), and
overexpression of ADF in Dictyostelium discoideum stimulates cell movement (Aizawa et al., 1996
). In plants, ADF
is encoded by a small multigene family, and at least one
member is preferentially expressed in germinating pollen
tubes (Lopez et al., 1996
). Experiments with transgenic
Arabidopsis thaliana indicate that ADF is involved in cell
shape maintenance and cell elongation (Xia, G., Y. Ishimaru, L. Dong, Y. Hong, S. Ramachandran, A. Cleary, and N.-H.
Chua, unpublished data).
; Cooper et al., 1986
; Maciver et al.,
1991
; Hawkins et al., 1993
; Hayden et al., 1993
). The issue
of the preferential binding of ADFs to ADP- or ATP-actin
is still controversial (Hayden et al., 1993
; Maciver and
Weeds, 1994
).
Materials and Methods
, 0.2 mM ATP, 0.2 mM DTT, 0.1 mM CaCl2, 0.01% NaN3, pH 7.8)
as described (Carlier et al., 1996
). CaATP-G-actin was converted into
MgATP-G-actin by the addition of 0.2 mM EGTA and 1 molar equivalent +10 µM excess of MgCl2 and used 3 min later. Actin was polymerized
by the addition of 1 mM MgCl2 and 0.1 M KCl to Mg-G-actin. Gelsolincapped filaments were obtained by polymerizing Ca-actin without EGTA
and 2 mM instead of 1 mM MgCl2. MgADP-G-actin was prepared by preincubation of MgATP-G-actin with 20 U/ml hexokinase and 5 mM glucose (Pollard et al., 1992
). Actin was labeled by either pyrenyl iodoacetamide (Kouyama and Mihashi, 1981
) or NBD-Cl (Detmers et al., 1981
).
Thymosin
4 (T
4) was purified from bovine spleen (Carlier et al., 1996
).
Spectrin-actin seeds were prepared from human erythrocytes and their
molar concentration was determined as described (Casella et al., 1986
)
and by titration by gelsolin.
). Expression of 35S-labeled ADF1 (3.5 to 7 Ci/mol) was performed in M9 minimal medium containing 1.5 mCi
[35S]methionine and [35S]cysteine in the presence of 0.2 mg/ml rifampicin,
30 min after the induction of T7 RNA polymerase expression by IPTG.
A bacterial extract (80 ml) was dialyzed overnight against 2 liters of
DEAE buffer (10 mM Tris Cl, pH 7.8, 50 mM NaCl, 5 mM DTT, 0.2 mM
EGTA, 0.1 mM PMSF, 0.01% NaN3) and chromatographed on DEAE
cellulose equilibrated in the same buffer. ADF1 was recovered 85-90%
pure in the flow-through. The solution was equilibrated in 10 mM Pipes,
pH 6.5, 5 mM DTT, 0.2 mM EGTA, 0.01% NaN3, 25 mM NaCl and chromatographed on SP-trisacryl in the same buffer. ADF1 was recovered
99% pure in the flow-through. ADF1 was concentrated to 150-250 µM by
ultrafiltration, dialyzed against 5 mM Tris Cl
, pH 7.5, 1 mM DTT, 0.01%
NaN3, centrifuged at 400,000 g for 15 min, and stored on ice for up to 4 wk
without any loss in activity. The concentration of ADF1 was determined
spectrophotometrically, using the same extinction coefficient of 0.89 mg
1cm2 at 278 nm as for actophorin (Cooper et al., 1986
).
Binding of ADF1 to G-actin
ADF1 binding to MgATP-G-actin or MgADP-G-actin was assayed by
the quenching of fluorescence F of NBD-labeled actin. Experiments were
carried out at 20°C, pH 7.8, in a Spex fluorolog 2 spectrofluorimeter (exc
475 nm,
em 530 nm) using 0.3 ml samples of 0.8 µM G-actin in 4 × 4 mm
square section cuvettes. The quenching of fluorescence,
,
was measured at each concentration of added ADF. Data were analyzed using Kaleidagraph software (Synergy Software, Reading, PA) and fitted using the following equation:
(1)
where [ ADF]
(2)
= Q/Qmax, Qmax is the maximum quenching reached at saturation of
G-actin by ADF, [ADF]0 and [G]0 are the total concentrations of ADF
and G-actin, respectively, and K is the equilibrium dissociation constant
for the G-actin-ADF complex.
Binding of ADF1 to F-actin
Sedimentation Assay.
Samples of 0.3 ml containing F-actin and 35S-labeled
ADF at the indicated concentrations were incubated for 10 min to 2 h at most and sedimented at 20°C for 30 min at 400,000 g. When barbed ends
were capped, a gelsolin/actin molar ratio of 1:300 to 1:500 was used. The
amount of ADF bound to F-actin was derived from radioactivity measurements of the amounts of 35S-labeled ADF present in the samples before
centrifugation and in the supernatant of sedimented samples. Supernatants and resuspended pellets were submitted to SDS-PAGE (15% acrylamide). Coomassie blue-stained gels were scanned (model Arcus II scanner; AGFA Corp., Orangeburg, NY), and the patterns were compared to
those obtained for actin and ADF standards to estimate the amounts of
actin and ADF in the pellets and supernatants, using the NIH Image program. The amount of G-actin in the supernatants was also derived from measurements of the inhibition of DNaseI activity (Blickstad et al., 1978).
Fluorescence Assay. Samples of fully labeled pyrenyl- or NBD-F-actin at steady state in polymerization buffer were supplemented at time zero with ADF. Changes in light scattering at a 90° angle and fluorescence were recorded simultaneously using the "T" configuration of the Spex fluorimeter. The excitation monochromator was set at 366 nm for pyrenylactin and at 475 nm for NBD-actin. One of the two emission monochromators was set at the same wavelength as the excitation wavelength to monitor light scattering. The other monochromator was set at 387 or 530 nm to monitor pyrene or NBD fluorescence, respectively.
Polymerization and Depolymerization Assays
Kinetics of actin assembly and disassembly were monitored turbidimetrically at 310 nm in a spectrophotometer (model Uvikon; Kontron Instrs., Milan, Italy or model Cary 1; Varian Techtron, Victoria, Australia) using 1-cm path cuvettes thermostated at 20°C.
Measurements of initial rate of growth from barbed ends were carried out using spectrin-actin seeds. Assembly was started by adding ADF to preformed Mg-G-actin, followed by the seeds and salt. All buffer solutions were thoroughly filtered and degassed before the experiment.
The initial rate of growth is:
(3)Vi=[S](k+B [ G-actin]+k+B[ G-actin
ADF]) ,
where [S] represents the concentration of spectrin-actin seeds, and kB+ and
kB+ represent the association rate constants of G-actin and G-actin-ADF,
respectively, to the barbed ends. The contribution of the off rate was neglected in Eq. 3 because the actin concentration (3.3 µM) is well above the
critical concentration. The concentrations of G-actin and G-actin-ADF can
be calculated knowing the values of [G]o, [ADF]o, and K:
[G-actinADF]=
(4) .
The value of kB+ can be derived from the plot of
versus [G-actin- ADF]. Since initial rate measurements have been performed at a low percentage of ADF-actin, the impact of the difference in specific turbidities
of F-actin and ADF-F-actin on the value of the rate parameters is minor.
Elongation of filaments from the pointed ends was carried out using gelsolin-actin seeds (4 µM gelsolin + 8 µM Ca-G-actin in G buffer). A solution of 6.5 µM Mg-G-actin was supplemented at time zero with ADF, followed immediately by 0.2 mM CaCl2, 75 nM CapG (to cap the potential spontaneous barbed end nuclei), different amounts of gelsolin-actin seeds, and salt. The optimum amount of CapG was experimentally determined to efficiently cap spontaneous barbed end nuclei but avoid nucleation of new pointed ends, which we found to occur at concentrations of CapG above 150 nM.
Depolymerization of F-actin from the barbed ends was induced by adding 6 µM DNaseI and ADF as indicated to a solution of 6 µM F-actin.
DNaseI binds tightly to monomeric actin (Blickstad et al., 1978) and to the
pointed end subunits (Podolski and Steck, 1988
; Weber et al., 1994
);
hence, the effect of ADF on the rate of depolymerization from the barbed
ends specifically can be measured.
Depolymerization of F-actin from the pointed ends was induced by
adding 26 µM T4 and ADF as indicated to a solution of 3.5 µM F-actin
polymerized in the presence of 7 nM gelsolin. The amount of T
4 added is
low enough for this protein to act only as a G-actin sequestering agent.
Measurement of the Treadmilling Rate of Actin Filaments
The rate of filament turnover at steady state (treadmilling) was monitored
by the decrease in fluorescence of ADP bound to F-actin after addition
of a chase amount of ATP. Since ADP is nonexchangeable on F-actin
(Pollard et al., 1992
, and references therein) and since its fluorescence is
sixfold higher in the actin-bound than in the free state, the rate of fluorescence decrease is a true measurement of filament turnover.
ATP-G-actin
(15 µM), prepared as described (Valentin-Ranc and Carlier, 1989
), was
polymerized in the presence of 30 µM free
ATP. Samples of F-
ADPactin were preincubated with the desired amounts of ADF for 20 min. The
change in fluorescence of
ADP (
exc = 350 nm;
em = 410 nm) was recorded versus time after addition of 1 mM ATP. Identical results, but with
a lower time resolution, were obtained using a sedimentation assay
(400,000 g for 15 min) of [3H]ADP-F-actin and measuring the increase in
[3H]ADP in the supernatant at different time intervals after the onset of
the ATP chase.
ATP Hydrolysis Measurements in F-actin Solutions at Steady State
Ca-G-actin (16 µM) was equilibrated in G buffer containing 0.2 mM 32P-labeled ATP, converted into Mg-G-actin, and polymerized by addition of 1 mM MgCl2 and 0.1 M KCl. ADF was added at 15 min, when
steady state was reached. Acid labile [32Pi] resulting from ATP hydrolysis
was monitored by extraction of the phosphomolybdate complex (Carlier
et al., 1986
) during assembly and at steady state over a period of 5 h.
Actin-based Motility Assay of Listeria monocytogenes in Platelet Extracts
Platelet extracts were prepared (Laurent and Carlier, 1997) by sonication
of a suspension of washed unstimulated platelets in 10 mM Tris Cl
, pH
7.5, 2 mM MgCl2, 10 mM EGTA (8 × 109 ± 1 × 109 cells/ml) followed by
centrifugation at 100,000 g for 35 min, 4°C. The amount of G-actin in the
extracts was 35 µM, as derived from the DNaseI inhibition assay. The
amount of T
4 was 61 µM as derived from HPLC (Carlier et al., 1996
).
The amount of unassembled actin and T
4 being 200 and 320-500 µM, respectively, in platelets (Weber et al., 1992
), the cytoplasm was about sixfold diluted in the extracts. The extract was supplemented with extraction buffer, 5 mM ATP-Mg, 6 mM DTT, 3.25 µM rhodamine-labeled G-actin, oxygen scavengers (Isambert et al., 1995
), methyl cellulose and ADF as
indicated, and 108 bacteria/ml. The final dilution of the platelet cytoplasm
could be varied by changing the volume of extraction buffer present in the
motility assay. Sample preparation, fluorescence microscopy observation,
and video recording of the formation of comet tails and bacteria propulsion were carried out as described (Marchand et al., 1995
). 10-15 mobile
bacteria were recorded per sample to derive the average rates and tail
lengths. It was checked that ADF1 binds rhodamine-actin used in the motility assay. A 25% quenching of the fluorescence of rhodamine-F-actin
occurred upon binding ADF1.
Sedimentation Velocity of Actin Filaments
in the Analytical UltracentrifugeEffects of ADF1
and Gelsolin
Solutions of F-actin containing different amounts of ADF or gelsolin were centrifuged at 20°C at 20,000 rpm in an analytical ultracentrifuge (model Optima XLA; Beckman Instrs., Fullerton, CA). Scans were recorded at 295 nm at 4-min intervals. The average sedimentation coefficients of filaments present in the different samples were compared. Control samples for severed filaments were obtained using gelsolin at a 1:100, 1:500, or 1: 1,000 ratio to actin.
ADF1 Binds ADP-G-actin with a 100-fold Higher Affinity than ATP-G-actin under Physiological Ionic Conditions
The fluorescence of NBD-G-actin was partially quenched
upon binding ADF. Therefore, this parameter was used to
determine the values of the equilibrium dissociation constant of the ADF-G-actin complex under a variety of conditions. The extent of quenching of NBD fluorescence versus
ADF concentration displayed a saturation behavior, consistent with the formation of a tight 1:1 complex between
G-actin and ADF. Under physiological ionic conditions (0.1 M KCl, 1 mM MgCl2, pH 7.8; Fig. 1), ADF bound to
MgADP-G-actin with an affinity (Kd = 0.1 µM) two orders
of magnitude higher than MgATP-G-actin (Kd = 8 µM).
The quenching of NBD fluorescence was slightly higher in
the ADP-bound complex (32 ± 2%) than in the ATPbound complex (27 ± 2%). At low ionic strength, the affinity of ADF for MgATP-G-actin was higher than at
physiological ionic strength (Kd = 0.08 µM) and only
three- to fourfold lower than for MgADP-G-actin (Kd = 0.025 µM). Binding constants at different ionic strength are
displayed in Table II. Identical values of the binding constants (within 20%) were derived from kinetic measurements of the inhibition of nucleotide exchange on G-actin
by ADF1 (data not shown).
Table II. Equilibrium Parameters for the Interaction of ADF with G- and F-actin |
The Different Binding of ADF1 to ADP-G-actin and ADP-F-actin Causes the Partial Depolymerization of Filaments
Sedimentation assays of the binding of 35S-labeled ADF to
F-actin (Fig. 2 a) in the presence of 0.1 M KCl, 1 mM
MgCl2, pH 7.8, show that ADF binds tightly to F-actin
with a sigmoidal saturation curve. In agreement with others (Nishida et al., 1984; Hawkins et al., 1993
; Hayden et
al., 1993
; Moon et al., 1993
), one molar equivalent ADF
per F-actin subunit was found in the pellet at saturation by
ADF. The amount of F-actin decreased to a limited extent
upon increasing the concentration of ADF. At saturating amounts of ADF, a constant amount of ADF-F-actin (1:1)
coexisted at steady state with a constant amount of unassembled actin. Identical data were obtained when ADF was
added to preassembled F-actin and when actin was assembled in the presence of ADF. The concentration of unassembled actin reached at saturation by ADF was independent of the total concentration of actin and was 1.7-2 µM
at pH 7.8. The binding behavior of ADF was qualitatively
identical to the above in a range of pH from 6.5 to 8.3 (Fig.
2, b and c). At pH 6.5, the amount of unassembled actin at
steady state at saturating amounts of ADF was 1.2 ± 0.2 µM;
it reached 3.5 ± 0.5 µM at pH 8.3.
The partial depolymerization of actin by ADF is not in
agreement with the behavior expected for a G-actin sequestering protein, which should eventually depolymerize
F-actin totally in a concentration-dependent fashion (Carlier and Pantaloni, 1994). Rather, the results suggest that
ADF-actin complex copolymerizes with actin and that a
new steady-state concentration of unassembled actin is established in the presence of ADF. The sigmoidicity of the
binding curves of ADF to F-actin is consistent with the observation of the gel patterns (Fig. 2) showing that addition
of a small amount of ADF (~1 µM) to an F-actin solution
essentially causes depolymerization of F-actin (hence binding of ADF to G-actin), while very little ADF binds to the
remaining filaments. At higher concentrations, ADF binds
to F-actin. The sigmoidal curve therefore does not result from the cooperative binding of ADF to F-actin as previously
thought (Hayden et al., 1993
) but reflects the preferential
interaction of ADF with G-ADP-actin over F-ADP-actin.
In the presence of BeF3, a Pi analog that binds to F-ADPactin subunits and reconstitutes the F-ADP-P* transition
state of ATP hydrolysis on F-actin (Carlier, 1991
), ADF
neither bound appreciably to F-actin nor depolymerized it,
in agreement with other reports (Maciver et al., 1991
; Maciver and Weeds, 1994
). The binding of ADF to phalloidin-
F-actin was very low. In conclusion, the affinity of ADF
for F-actin, as well as for G-actin, is strongly dependent on
the bound nucleotide and much higher for the ADP forms
of both G- and F-actin.
The binding of ADF to gelsolin-capped filaments was examined next. A steady-state concentration of unassembled actin of 3.5 ± 0.3 µM was found at saturation by ADF. In the presence of ADP, a true critical concentration of 4.5 ± 0.5 µM for assembly of ADF-ADP-actin was found at saturation by ADF, both in the presence and absence of gelsolin. This value is threefold higher than the critical concentration for assembly of ADP-actin. Detailed balance therefore implies that the equilibrium dissociation constant for binding of ADF to ADP-F-actin subunits be threefold higher than to ADP-G-actin, i.e., 0.3 µM, as described by the following thermodynamic square scheme:
,
where K1 and K2 refer to the propagation constants (i.e., the critical concentrations for polymerization) of ADP-actin and ADF-ADP-actin, respectively, and K3 and K4 are the equilibrium dissociation constants for binding of ADF to G-ADP-actin and F-ADP-actin, respectively, with K1·K4 = K2·K3. All data are summarized in Table II.
Interaction of ADF with F-actin: Fluorescence and Light Scattering Measurements
The mechanism by which ADF causes partial depolymerization of F-actin was addressed in kinetic experiments. Since
excess ADF causes depolymerization of a maximum of
1.7 µM actin, it was interesting to compare the effects of
ADF addition (0.7 molar equivalent to actin) to either a
low or a high amount of F-actin, at which depolymerization occurs to very different extents. Typical curves are
shown in Fig. 3. The addition of ADF to 4.5 µM pyrenyl-
F-actin (Fig. 3 a) caused a small instantaneous increase,
followed by a time-dependent 38% decrease in light scattering, consistent with the depolymerization of 1.7 µM
F-actin. Similarly, the addition of ADF to 15 µM F-actin (Fig. 3 b) caused a 10% decrease in light scattering, also
consistent with 1.7 µM depolymerized actin.
The changes in fluorescence did not quantitatively correlate with the changes in light scattering. A rapid large
decrease was followed by a slower decrease. The slow
phase was kinetically consistent with the decrease in light
scattering. At all F-actin concentrations, the amplitude of
the large rapid fluorescence decrease varied linearly with
ADF and reached 95% quenching at a 1:1 molar ratio of
ADF/F-actin (Fig. 3 d). This implies that the rapid binding
of ADF to F-actin is linked to the quenching of pyrenyl-
F-actin fluorescence to the level of G-actin and is followed
by a slower partial depolymerization. The linear dependence of quenching on ADF concentration indicates that
the ADF binds with high affinity (Ka > 106 M1) to F-ADPactin. The fast binding was noncooperative, which confirms our interpretation of the sigmoidal binding curves (Fig. 2)
obtained when ADF binding is assayed by sedimentation
after the slow relaxation to a new steady state. Identical
results were obtained using NBD-labeled actin. The fluorescence of NBD-F-actin was quenched, upon binding ADF,
to a level corresponding to 70% of the fluorescence of
NBD-G-actin.
When ADF was added to partially labeled pyrenyl-Factin, the fluorescence change was more complex (Fig. 3 c).
The rapid and slow decreases were then followed by a
slow recovery to a higher stable limit, in agreement with
others (Maciver et al., 1991; Aizawa et al., 1995
). A straightforward interpretation is that ADF binds rapidly to both
labeled and unlabeled F-actin subunits and then slowly redistributes from the labeled to the unlabeled F-actin subunits, with fluorescence recovery. This kinetic behavior is
generated when the rate constants for association to unlabeled and labeled actins are similar, but the higher affinity
for unlabeled actin is linked to a lower dissociation rate
constant. A similar behavior is displayed by myosin subfragment-1 binding to partially labeled actin and was recently quantitatively analyzed with the same mechanism
(Blanchoin et al., 1996
). No changes in fluorescence nor
light scattering were observed when ADF was added to
phalloidin-F-actin or to F-ADP-BeF3-actin, which confirmed the observations made in Fig. 2.
Effect of ADF1 on the Kinetics of Actin Polymerization
The results presented above demonstrate that ADF modifies the steady state of actin assembly and point to the need to understand how the kinetics of assembly/disassembly at the barbed and pointed ends of the filaments are affected by ADF. Preliminary experiments (not shown) indicated that, in agreement with data in Fig. 3, the time courses of actin assembly followed simultaneously by light scattering and either NBD- or pyrenyl-actin fluorescence were no longer kinetically correlated in the presence of ADF because of the quenching of fluorescence that occurs upon binding of ADF to F-actin during polymerization.
Since fluorescence of labeled actin cannot be used reliably to monitor actin assembly in the presence of ADF,
turbidimetry was used as an alternative tool. Fig. 4 shows
the effects of ADF on the spontaneous assembly of MgATP-actin (a) and Mg-ADP-actin (b). In both cases, ADF
increased the rate of assembly and the maximum extent of
turbidity change. In the simple case of reversible polymerization of ADP-actin, monotonic time courses of assembly correspond to the copolymerization of ADP-actin and ADF-
ADP-actin. In the presence of ATP, the overshoot kinetics
suggest that partial depolymerization of ADF-F-actin occurs consecutive to some kinetic barrier. We know that:
(a) Pi release after ATP hydrolysis associated with actin
polymerization is a slow process (t1/2 = 2 min) that takes
place on the filaments after actin assembly (Carlier, 1991); and (b) ADF binds to ADP-actin with a 100-fold higher affinity than to ATP-actin. Hence, the most plausible explanation accounting for the different kinetics in ADP and ATP
is that in the presence of ATP, ADF binds to F-actin and
promotes its partial depolymerization only after Pi has
been released. The final steady state concentration of unassembled actin in the presence of ADF (2 µM at this pH) is therefore established via overshoot kinetics. In the presence of inorganic phosphate, which maintains the filaments in the F-ADP-Pi state, the overshoot was abolished
but the ADF-induced increase in initial rate of assembly
was still observed.
The polymerization time courses are not consistent with
fragmentation of filaments by ADF because they do not
exhibit the acceleration and symmetric shape around the
half-polymerization time point characteristic of such a
process, which has been observed and mathematically analyzed (Carlier et al., 1985).
The validity of the turbidity change as a measure of the
mass amount of assembled actin in the absence and presence of ADF is illustrated by the linearity of the critical
concentration plots shown in Fig. 4 c. The extent of turbidity change per unit mass of assembled actin was 1.65-fold
greater for ADF-F-actin than for F-actin. This figure is
quantitatively consistent with the increase in mass per unit
length of filaments decorated by ADF. Indeed, the turbidity is expected to be proportional to the square of the molecular mass per unit length of the polymer (Carlier et al.,
1994). Assuming that the structure factor of F-actin filaments remains unchanged, in a first approximation, when
ADF is bound to F-actin, the ratio of the specific turbidity
of ADF-F-actin and F-actin is expected to be equal to the
ratio of the square of the molecular mass of the polymerizing unit, which in this case is equal to (58/42)2 = 1.9, in reasonable agreement with the experimental value of 1.65. The
steady-state concentrations of monomeric actin, as derived from the plot shown in Fig. 4 c, were 0.15 and 2.5 µM in
the absence and presence of a saturating amount of ADF,
respectively, consistent with the sedimentation data.
Note that the turbidity reached at steady state (Fig. 4 a) in the presence of different concentrations of ADF is fully consistent with the sedimentation data (Fig. 2 a) and the increase in specific turbidity of F-actin upon binding ADF (Fig. 4 c), as follows. Low concentrations of ADF essentially promote depolymerization of F-actin; hence, filaments are eventually poorly decorated by ADF at steady state, and the final turbidity is low. At higher concentrations of ADF, the final turbidity is higher because of the increased binding of ADF to F-actin.
ADF1 Increases the Association Rate Constant of Actin to Barbed Ends, Not to Pointed Ends of Actin Filaments
To determine the association rate constant of actin-ADF
to barbed ends, the effect of ADF on the initial rate of
growth from spectrin-actin seeds was examined. Data (Fig.
5 a) were analyzed using Eqs. 3 and 4 (Materials and
Methods). The association rate constant of G-actin-ADF
complex to barbed ends appeared to be 12 ± 3-fold higher
than that of G-actin. This result may seem puzzling since
the association rate constant of actin to barbed ends (107
M1·s
1) has been shown to be diffusion-limited (Drenkhahn and Pollard, 1986
). It is plausible that, upon binding
to G-actin, ADF induces a dipolar moment in the actin
monomer, which modifies the charge distribution at the interface of G-actin with the barbed end, thus enhancing
long-range electrostatic interactions and steering the association reaction. As an example, the electrostatically assisted association of barnase to barstar has recently been
described (Schreiber and Fersht, 1996
) and modeled (Janin, 1997
). This interpretation was challenged by testing
the shielding effect of ionic strength. In a low ionic strength
F buffer (1 mM MgCl2), ADF-G-actin associated 20-fold
faster to barbed ends than G-actin. At high ionic strength (0.4 M KCl, 1 mM MgCl2), the steering effect of ADF was
abolished. Specifically, no change was observed in the rate
of filament elongation when the concentration of ADFATP-G-actin, calculated using Eq. 4 with the experimentally determined value of Kd at 20 µM (Table I), represented up to 40% of the total amount of G-actin in the elongation assay. The strong ionic strength dependence of
the kinetic facilitation of actin association to barbed ends
by ADF therefore supports the view that electrostatic
forces are involved in its action.
The effect of ADF on the rate of actin association to the pointed ends (Fig. 5 b) was evaluated using gelsolin-actin seeds to nucleate pointed end growth. The effect of ADF was much less pronounced than at the barbed ends. The presence of the overshoot indicated that partial depolymerization induced by ADF occurs at least partly from the pointed ends.
If the increase in the rate of elongation from spectrinactin seeds had been due to a severing effect of ADF rather than an effect on the association rate, then the same severing action would have occurred when filaments were induced to grow from their pointed ends. Clearly the data eliminate this possibility.
ADF1 Increases the Rate of Filament Depolymerization from the Pointed Ends, Not from the Barbed Ends
Depolymerization of gelsolin-capped actin filaments (3.5 µM
F-actin) was induced by addition of ADF at different concentrations and monitored turbidimetrically (Fig. 6 a). The
critical concentration at the pointed ends being increased
up to 3.5 µM by ADF, addition of ADF to capped F-actin
promotes, in these conditions, total depolymerization. The
initial rate of depolymerization then truly represents the
off rate at the pointed ends. Identical time courses were
obtained in the additional presence of T4 used as a sequestering agent (not shown). The rate of depolymerization, in absorbance U/min, was increased up to 36 ± 5-fold
by ADF, compared with a control in which total depolymerization was promoted by T
4. Once corrected for the
65% higher specific turbidity of ADF-F-actin as compared to F-actin (Fig. 4 c), the rate of depolymerization is
actually increased 22 ± 3-fold by ADF. The ADF concentration dependence of the increase in rate reflected the
high-affinity 1:1 binding of ADF to ADP-F-actin.
The effect of ADF on the rate of depolymerization from
the barbed ends was examined next using DNaseI (Fig. 6 b).
The rate of DNaseI-induced depolymerization was unaffected by ADF in saturating amounts. From the turbidity
data, the initial rate of disassembly was about 100 nM subunits/s, consistent with a population of filaments of 2.5-µm
average length depolymerizing at a rate of 12 subunits/s (Pollard and Cooper, 1986). After capping the barbed ends
of the same F-actin solution by 120 nM CapG in the presence of 0.2 mM Ca2+ ions (Carlier et al., 1996
), depolymerization from the pointed ends was induced by T
4 in the
presence and absence of ADF. The same 22-fold increase
in rate of depolymerization as in Fig. 6 a was observed.
If the increase in the rate of depolymerization from the
pointed ends (Fig. 6 a) had been due to a severing action
of ADF, creating a large number of uncapped, rapidly depolymerizing filaments, then the same severing action
would have caused a large increase in the rate of DNaseIinduced depolymerization from the barbed ends (Fig. 6 b).
Clearly the data again eliminate this possibility. Also note
that if ADF had a weak severing efficiency of 0.1% (Hawkins et al., 1993), a stoichiometric effect (Fig. 6 a) would not be observed. In conclusion, the effects of ADF on actin assembly and disassembly are end specific.
ADF1 Increases the Turnover of Actin Filaments and the Steady-State ATPase of F-actin
The rate of treadmilling at steady state was derived from
the rate at which the nonexchangeable, F-actin-bound ADP
was replaced, after an ATP chase, by nonfluorescent ADP
as a result of subunit flux through the filaments (Wegner,
1976
). The decrease in fluorescence of
ADP proceeded
linearly with time, at all concentrations of ADF, for over
60% of the total renewal of F-
ADP-actin, suggesting that
under physiological conditions monomer-polymer exchange
is essentially due to treadmilling (Brenner and Korn, 1983
).
A very large increase in the rate of treadmilling was induced by ADF. The increase was concentration dependent
(Fig. 7) and reached a maximum of 25-fold, which corresponded to an average flux of 2 subunits/s. At higher concentrations of ADF, an apparent decrease in the treadmilling
rate was recorded, most likely as a result of the inhibition
by ADF of
ADP dissociation from G-actin after its dissociation from the pointed ends. The exchange of nucleotide on G-actin then becomes rate limiting in the monomer-
polymer exchange process. The 25-fold increase in treadmilling rate is consistent with the 22-fold increase in the
dissociation rate at the pointed ends.
The steady-state ATPase of F-actin provides an alternative measure of filament turnover. The ATPase of F-actin was greatly increased by ADF. ATP hydrolysis was linear with time for over 5 h at all ADF concentrations. The data (Fig. 7) superimpose onto the turnover measurements. At the maximum, ~0.8 ATP was hydrolyzed per second per average filament of 8-10-µm length. After 18 h of incubation at 20°C, at least 90% of the ATP was found hydrolyzed in samples containing 5-10 µM ADF.
ADF1 Increases the Rate of Listeria Propulsion in Platelet Extracts
The actin-based movement of Listeria monocytogenes can
be reconstituted in human platelet extracts (Laurent and
Carlier, 1997). Assays were carried out increasing the
dilution of the extract in extraction buffer supplemented
with rhodamine-actin. As documented in detail elsewhere
(Laurent and Carlier, 1997
; Table I), the rate at which actin "clouds" are formed around the bacteria as well as the
rate of propulsion of the bacteria increase upon increasing the dilution of the extracts, reach a maximum, and then decrease at high dilution, most likely because of the limiting
amounts of one or several of the cellular components necessary for efficient movement. At a 48-fold dilution of the
platelet cytoplasm, Listeria moved at an average steady
rate of 4 µm/min, i.e., 2.5-fold lower than the maximum
rate observed at a lower dilution, and displayed actin tails
of 16-µm length. The fact that both the length of the actin
tails and the rate of movement are constant over several hours indicates that movement of Listeria results from a
steady state of actin assembly, in which the measured rate
of actin polymerization, which drives the movement (Theriot et al., 1992
), is equal to the rate of the kinetically limiting step in the steady-state cycle. The ADF/actin molar ratio is 0.1 in platelets (Davidson and Haslam, 1994
); hence,
the concentration of endogenous ADF might have been at
most 200·(0.1)/48 µM = 0.4 µM in the assay. When added
to the diluted platelet extract, ADF1 increased the rate of
actin-based motility in a concentration-dependent fashion and caused a shortening of the length of the actin tail (Table III). In the presence of 0.75 µM ADF1, the bacteria
moved twice as fast and the actin tails were fourfold
shorter. Typical pictures are shown in Fig. 8. No effect of
ADF on the rate of movement was observed when it was
added to less diluted extracts in which Listeria moved at 10 µm/min. These results indicate that in the highly diluted
extracts the rate of movement is low because of the limited
amounts of endogenous ADF. Platelet extracts appeared to be more convenient than Xenopus egg extracts for monitoring the movement of Listeria at high dilution, presumably because platelets are specialized cells for actin-based
motility and contain high amounts of actin-binding proteins.
Table III. Effect of ADF on the Rate of Propulsion of L. monocytogenes in Platelet Extracts |
The effects of ADF on the motility of Listeria are consistent with our biochemical data showing that ADF increases the rate of depolymerization at the pointed ends,
which is the kinetically limiting step in the turnover rate of
actin filaments and therefore limits the rate of assembly at
the barbed ends at the surface of the bacteria. The shortening of the tail is consistent with results (Marchand et al.,
1995) indicating that filaments are capped in the tail body
and depolymerize from their pointed ends. We checked
that capping proteins are functional in platelet extracts by
measuring the shift in critical concentration of a pyrenyllabeled F-actin solution upon addition of increasing amounts
of platelet extracts. The critical concentration of the pointed
ends was established as soon as 5% in volume of the platelet extract (corresponding to a 120-fold dilution of the platelet cytoplasm) was added to F-actin.
As the tails grew shorter and the bacteria moved faster upon addition of ADF, the trajectories of the bacteria became less straight, and the frequent changes in direction made it more difficult to measure the rate of propulsion with accuracy. When high concentrations of ADF were added, the actin tails never reached a size (i.e., acquired a friction coefficient) sufficient to support unidirectional movement. The lower limit size of the actin tail required to start movement was of the same magnitude as the length of the bacterium, i.e., 1 µm. Data are summarized in Table III.
Does ADF1 Fragment Filaments In Vitro?
In agreement with reports on other ADFs (Cooper et al.,
1986; Hawkins et al., 1993
; Moon et al., 1993
; Aizawa et al.,
1995
), the addition of Arabidopsis ADF to F-actin resulted
in a rapid drop in viscosity (data not shown), which temporally correlated with binding of ADF to F-actin and preceded depolymerization. No recovery of viscosity with
time was observed. Even after overnight incubation, the
viscosity of ADF-F-actin solutions (20 µM, pH 6.5-8.0)
remained low, while the F-actin controls were solid gels.
The rapid decrease in viscosity has generally been attributed to the severing activity of ADF. However, the fact
that ADF affects the rates of assembly/disassembly differently at both ends (Figs. 5 and 6) cannot be simply accounted for by a severing activity. Consistently, electron
microscopy observation of negatively stained samples of
ADF-decorated filaments (Fig. 9) failed to display a 20fold decrease in filament length, which should have been
observed to account for the kinetic data in Figs. 5 a, 6 a,
and 7. The electron micrographs of ADF1-decorated actin
filaments show the same features as those obtained by
Ohta et al. (1984), i.e., a thickened appearance and contorted shape, but no appreciable change in average length.
To get more insight into the putative severing activity of
ADF1, the sedimentation velocity of samples of F-actin
(15 µM) containing different concentrations of ADF or
gelsolin was examined in the analytical ultracentrifuge at
pH 7.8 in physiological ionic strength buffer. The apparent
sedimentation coefficient of F-actin at 15 µM was 60 ± 5 S,
and increased to 93 ± 7 S in the presence of 20 µM ADF.
In contrast, it decreased to 53 ± 5 and 32 ± 2 S in the presence of gelsolin at molar ratios to actin of 1:500 and 1:100,
respectively. These data show that actin filaments severed
by gelsolin sediment more slowly, while they sediment faster in the presence of ADF. In an additional experiment,
the sedimentation velocity of F-actin (7.7 µM) containing
gelsolin at a 1:1,000 molar ratio to actin and increasing
amounts of ADF was examined. Average sedimentation
coefficients of 76 ± 4, 96 ± 5, and 121 ± 6 S were measured for F-actin samples containing 0, 4, and 8 µM ADF,
respectively. The concentration dependence of the sedimentation coefficients of F-actin and ADF-F-actin was derived from these data, considering the 3 µM difference
in concentration of assembled actin in the presence and
absence of ADF. Extrapolation to zero actin concentration yielded the values of S0,20 of 96 ± 6 and 135 ± 10 S for
F-actin and ADF-F-actin in the presence of gelsolin at a 1:
1,000 molar ratio to actin. Actin filaments have a persistence length of 7-8 µm (Isambert et al., 1995); hence, they
can be considered as rods in this experiment where their average length is 3 µm. The sedimentation coefficient of
rods is given by the following equation (Garcia de la
Torre, 1992):
(5) ,
where M is the molecular mass of the polymer, L its
length, and d its diameter. v is the partial specific volume,
the density,
the solvent viscosity, and N the Avogadro's number. For very long rods (L
10d),
takes the
value 0.386. The ratio of the molecular masses of ADF-Factin and F-actin subunits being 1.38, the ratio of the average diameters of the corresponding filaments is
= 1.17 (assuming that the binding of ADF to F-actin thickens
the filament but does not increase its length).
The ratio of the sedimentation coefficients of ADF-Factin and F-actin can be calculated using Eq. 5, in two
cases, using an average filament length of 3,000 nm (fixed
by gelsolin) and values of 8 and 9.4 nm for the diameters
of F-actin and ADF-F-actin: (a) If ADF does not fragment filaments, the ratio of the sedimentation coefficients is
1.38 [ln(3,000/9.4) + 0.386]/[ln(3,000/8) + 0.386] = 1.35, which
is in good agreement with the experimental value of 135/
96 = 1.4. (b) If ADF had a weak severing activity of 0.1% (Hawkins et al., 1993), the addition of 20 µM ADF to a 15 µM F-actin solution would generate 20 nM fragments,
thus decreasing the average length by about threefold. It
can then be calculated that the sedimentation coefficient
would be decreased by 18% if ADF only severed filaments
without binding F-actin, as was proposed to occur at pH
above 7.0. It would be increased by only 10% if ADF both
severed and bound tightly to F-actin.
In conclusion, although the drop in viscosity of F-actin upon binding ADF1 is suggestive of severing of filaments, electron microscopy and sedimentation velocity fail to confirm the fragmentation hypothesis.
Other Members of the ADF/Cofilin Family Are Biochemically Similar to ADF1 from A. thaliana and Increase the Turnover Rate of Actin Filaments by the Same Mechanism
Yeast cofilin, Acanthamoeba actophorin, and human ADF (destrin) were tested using the assays described in this paper. The following results were obtained: All three proteins bound to F-ADP-actin, causing a quenching of fluorescence of NBD- and pyrenyl-labeled F-actin. In physiological ionic strength buffer, pH 7.8, all three proteins partially depolymerized F-actin like ADF1. The concentration of unassembled actin at steady state was 0.7 and 1.2 µM for the yeast and ameba proteins and 3 µM for human ADF, values close to the one found for ADF1 (1.8 µM). The pH dependence was similar too. The steady-state ATPase of F-actin was increased up to 12-fold by all three proteins.
Turbidimetric kinetic measurements showed that these
three proteins increased the rate of disassembly of F-ADPactin from the pointed end. Therefore, the enhancement
of actin dynamics is a common feature to all ADF/cofilins,
and it has the same mechanistic origin, which indicates
that all ADFs/cofilins might have the same function in actin-based motility in different species. This conclusion of
biochemical work is in agreement with recent genetic studies (Iida et al., 1993).
Ameba, yeast, and vertebrate ADFs also increased the rate of assembly at the barbed end to different extents, which reflected their different affinities for ATP-G-actin. (Actophorin did not increase the rate of actin assembly at the barbed ends, while yeast and human ADFs did.) All three proteins behaved very similarly to ADF1 turbidimetrically and showed overshoot polymerization time courses.
In conclusion, interesting quantitative differences in the biochemistry of these different ADF/cofilins are worth investigating further, using the quantitative assays that we set up here, to understand how their primary function in the enhancement of actin dynamics may be modulated in different species.
The recombinant ADF1 protein from A. thaliana studied here exhibits phenomenological properties similar to other members of the ADF/cofilin protein family. Since it has been largely documented that the native and recombinant ADF/cofilins from other species have identical properties, we can be reasonably confident that the native plant protein is functionally identical to the recombinant protein. The new data reported here lead us to propose a comprehensive interpretation of the present and previous results obtained on a variety of ADF/cofilin variants. A novel view of the mechanism of action of ADF is proposed, according to which the main functional property of ADF in actinbased motility is to increase the turnover rate of actin filaments at steady state. This function is mediated by the large increase in the rate of depolymerization from the pointed ends, which is the rate-limiting step in the steady-state monomer-polymer cycle of actin in the presence of ATP.
The detailed biochemical analysis of ADF1 function has
been made possible by the development of new tools (fluorescence quenching, turbidimetry) and by the use of kinetics to understand the mechanism of action of ADF in a
quantitative fashion. This kind of study required the use of
muscle actin, which is easily available and whose kinetics
have been extensively studied. While the physiological relevance of our approach may be questioned, our results compare well with previous works in which muscle actin has been
used to study ADF/cofilins from amebas (Maciver et al.,
1991), yeast (Moon et al., 1993
), starfish oocytes (Sutoh and
Mabuchi, 1989
), plant (Lopez et al., 1996
), and vertebrate
nonmuscle tissues (Nishida et al., 1985
; Yonezawa et al., 1985
;
Moriyama et al., 1990
; Hayden et al., 1993
). To temper the
concern one might have about the relevance of such in
vitro studies, one should note that the biochemical properties of Acanthamoeba actophorin (Cooper et al., 1986
) and D. discoideum cofilin (Aizawa et al., 1995
) remained the
same when these proteins were assayed with homologous
actin. The lethality of yeast cofilin-minus mutants was rescued
by mammalian cofilin or ADF (Iida et al., 1993
). However,
actophorin reacts differently with muscle and ameba actins
when Ca2+ is bound to actin (Mossakowska and Korn, 1996
).
ADF Does Not Act as a G-actin Sequestering Protein
In a broad pH range (6.5-8.3), the ADF/cofilins assayed
here all cause only partial depolymerization of F-actin.
Our understanding of ADF function therefore is conceptually different from the one derived from previous in
vitro work (for review see Sun et al., 1995). Thus far, ADF
from various sources has been described as a protein
which completely depolymerized actin in a 1:1 molar ratio
at pH 8.0 (Nishida et al., 1985
; Yonezawa et al., 1985
), which is the exact definition of a high-affinity G-actin sequestering protein. This conclusion was derived from experiments carried out at actin concentrations of 3 µM at
most. Our data are in perfect agreement with those; however, our interpretation differs because we observe that at
higher actin concentrations, ADF fails to further depolymerize actin. ADF binds to both F- and G-actin, hence the ADF-actin complex should be considered as another polymerizable rather than a sequestered form of actin. This
conceptual difference is important in the analysis of the
data, as follows.
The action of a G-actin sequestering protein is usually
visualized by a shift in critical concentration plots, from
which the value of its affinity for G-actin can be derived.
The exclusive binding of the protein to ATP-G-actin is implicit in this calculation (Carlier and Pantaloni, 1994). This
analysis cannot apply to ADF, which binds to both G- and
F-actin, preferentially in their ADP-bound forms. Therefore, the ADF-induced shift in critical concentration plots
that have been routinely observed (Hawkins et al., 1993
; Hayden et al., 1993
) led to an incorrect estimate of the equilibrium dissociation constant for binding of ADF to ATP-
G-actin because they were interpreted within a G-actin sequestering activity of ADF. In addition, a strong bias
would be introduced in the interpretation by assuming
that the changes in fluorescence of labeled actin reflect
changes in the amount of F-actin, which we have seen is not the case.
The pH dependence of the F-actin/G-actin ratio in the presence of ADF1, like for other ADFs, is simply quantitative and does not reflect a switch in function from an F- to a G-actin-binding activity of ADF upon increasing pH.
Although ADF tightly binds ADP-G-actin, it cannot be considered as an ADP-G-actin sequestering protein either. Indeed, in the presence of ADP, ADF also binds to F-actin and a true polymerization equilibrium of ADFADP-G-actin into ADF-ADP-F-actin is established, with a critical concentration of 4 µM (see the thermodynamic square scheme presented in Results section).
The Enhancement of Actin Dynamics by ADF Cannot Be Accounted for by Severing of Filaments
The severing of filaments by ADF/cofilins was originally
proposed for the following reasons: It was first noticed
that ADF accelerated actin polymerization and promoted
a rapid drop in fluorescence of NBD- or pyrenyl-labeled
F-actin (Cooper et al., 1986; Maciver et al., 1991
; Moon et al.,
1993
; Quirk et al., 1993
; Maciver and Weeds, 1994
), but
both properties were interpreted in terms of an increase in
filament number due to fragmentation. The fragmentation
hypothesis was enticing because it also provided a satisfactory explanation for the rapid drop in viscosity of F-actin
solutions after addition of substoichiometric amounts of
ADF, similar to the effect of the severing protein gelsolin. Further effort was made to visualize the fragmentation in
electron or optical microscopy. In some instances, filaments
were observed to be shorter, which was thought to be because of depolymerization (Abe and Obinata, 1989
) or
severing (Cooper et al., 1986
). In other instances, filaments did not appear shorter (Ohta et al., 1984
). In fluorescence optical microscopy, filaments immobilized on
myosin-coated glass surfaces and partly stabilized by
rhodamine-phalloidin appeared fragmented by flushing
ADF in the flow-cell (Maciver et al., 1991
).
The fragmentation hypothesis, however, did not provide
a description of ADF effects fully consistent with all data.
No increase in the number of ends could be detected using
cytochalasin B. The severing was then thought to be transient and followed by reannealing (Hawkins et al., 1993;
Hayden et al., 1993
). Other works rejected the reannealing
hypothesis (Nishida et al., 1985
; Maciver et al., 1991
).
The present work shows that some of the effects of ADF
that were attributed to severing should be reinterpreted.
First, the rapid decrease in fluorescence of pyrenyl- or
NBD-labeled F-actin appears to be due to a quenching of
fluorescence linked to ADF binding to F-actin. The depolymerization process is partial at all pHs and occurs on a
slower time scale. The possibility of quenching has been
evoked in other reports (Ohta et al., 1984; Cooper et al.,
1986
; Moon et al., 1993
) but was not considered quantitatively.
Second, the apparent acceleration previously noted in
the time courses of spontaneous polymerization in the
presence of ADF/cofilins is explained, in view of the
present work, by two independent reasons. First, in previous works, polymerization was started by addition of KCl
and MgCl2 to mixtures of ADF and Ca-G-actin. ADF,
which slows down metal/nucleotide exchange on G-actin,
thereby slowed down the production of rapidly nucleating
Mg-actin (Tobacman and Korn, 1983). Second, the tight
binding of ADF/cofilin to F-ADP-actin, produced late in
the polymerization process (Carlier, 1991
), causes a delayed increase in the specific light scattering of the filament, which was not appreciated in earlier works.
Third, the present kinetic data showing that the increases in rates are different at the two ends rule out the fragmentation hypothesis as an interpretation of the effects of ADF on actin assembly/disassembly. Fourth, both electron microscope observations and sedimentation velocity data fail to show evidence for appreciable fragmentation of filaments by ADF1.
The absence of evident severing activity of ADF argues
against the structural model recently proposed on the basis of a severing activity of ADF (Hatanaka et al., 1996),
according to which ADF would bind actin like gelsolin
segment-1, at the pointed end of the actin monomer.
Proposals can be made to reconcile the above discrepancies about the severing activity of ADFs. The possibility
cannot be discounted that some F-actin-binding proteins
enhance photobleaching-induced fragmentation. It is also
possible that ADF-decorated filaments are more fragile
than native filaments and break more easily when submitted to the mechanical stresses involved in the preparation of samples for electron microscopy, to shearing forces in
Ostwald-type viscometers (Ohta et al., 1984), or to Brownian movement. Such side effects, however, are different
from a gelsolin-like activity. More experiments are needed
to explain these discrepancies.
If the drop in viscosity cannot be interpreted by severing
of filaments, an alternative explanation should be sought
for the change in viscosity of the filaments linked to ADF
binding to F-actin. It is possible that ADF binding induces
a large change in the flexibility of the filaments. As noted
by Ohta et al. (1984), the binding of ADF to F-actin may
change the surface properties of the filaments, affecting
their electroviscosity, thus preventing the filament-filament
interactions that lead to the formation of a gel. It is also
possible that the ADF-induced increase in treadmilling
rate changes the rheological properties of actin (Isambert
and Maggs, 1996
). Experiments are in progress to address these questions. Interestingly, the structural/mechanical
change in actin filaments linked to the binding of an accessory protein may provide an alternative mechanistic description of the gel-sol transition, thus far understood generally in terms of filament severing (Bray, 1992
).
ADF Functions as an Actin Dynamizing Factor
We show that ADF can increase up to 25-fold the rate of treadmilling of actin filaments at steady state. This result implies that the rate-limiting step in the steady-state monomer-polymer exchange process is increased by ADF. The rate-limiting step is the dissociation of ADP-actin subunits from the pointed ends, which we show to be consistently 22-fold higher when ADF is bound to F-actin. It is remarkable that the effect of ADF is end specific, the rate of dissociation of ADP-actin from the barbed ends being unaffected by ADF.
The effect of ADF on the steady-state turnover of F-actin
is displayed in Fig. 10. In the absence of ADF, it is known
that at steady state, barbed ends contain predominantly
ADP-Pi subunits, while ADP subunits are present at the
pointed ends. Net slow association of ATP-G-actin at the
barbed ends is compensated by net slow depolymerization of ADP-actin at the pointed ends, which is the rate-limiting step in the cycle. To be specific, at the measured
steady-state concentration of ATP-actin (CSS), the on rate
at the barbed end is kB+ ·(CSS CBC), where CBC is the critical concentration at the barbed end. The off rate at the
pointed end is very close to k P
, and these two fluxes are
equal and of opposite sign. Using established values of 10 µM
1 for kB+ , 0.1 µM for CSS, and 0.2 s
1 for k P
(Pollard
and Cooper, 1986
), we conclude that the value of CBC must
be 0.08 µM to support a steady-state flux of 0.2 s
1.
In the presence of ADF, the steady-state cycle is faster
as a result of the faster depolymerization of ADF-F-ADPactin from the pointed ends. Subsequent dissociation of
ADF from its complex with ADP-G-actin, followed by exchange of ATP for bound ADP, results in a larger association flux of ATP-G-actin (at a new steady-state concentration CSS) and ADF-ATP-G-actin to barbed ends. The new barbed end association flux is:
(6)JON=k+B·( CSS
0.08)+k
+B·( C
SS{ADF}/ Kd
CCADF)
where {ADF} is the concentration of free ADF, C CADFis the
critical concentration for polymerization of ADF-ATP-Gactin, and kB+ is the association rate constant of ADFATP-G-actin to barbed ends. Assuming {ADF} = 1 µM as
an example, since Kd = 10 µM, the concentration of ADFATP-G-actin is 10-fold lower than the concentration of
ATP-G-actin. Since its critical concentration for polymerization ( C CADF) is probably much larger than zero, the contribution of ADF-ATP-G-actin to barbed end growth at
steady state (second term in Eq. 6) is much lower than that
of ATP-G-actin. Within this simplification, a 25-fold
faster steady-state flux of subunits through the filament
(i.e., 5 s1) will be established at a steady-state concentration of ATP-G-actin CSS
given by the following equation.
(7)kB1·(CSS
0.08)=5 s
1
,
which leads to CSS = 0.58 µM, to be compared to the
value of 0.1 µM found in the absence of ADF. This calculation emphasizes that a 25-fold faster treadmilling rate
can be obtained at a steady-state concentration of ATP-
G-actin less than sixfold higher than in the absence of
ADF. In summary, an off rate of 5 s
1 at the pointed end is
generated by the depolymerization of ADF-ADP-F-actin, and the concentration of ATP-G-actin self-adjusts to a
higher value that allows the on-flux at the barbed end to
exactly compensate the off-flux from the pointed ends.
In the presence of ADF, the steady-state concentration of monomeric actin is a mixture of ATP-G-actin, ADP-Gactin, and their complexes with ADF. While the total concentration of all these components (1.7 µM) is obtained in sedimentation assays, the exact partial concentration of each of these species is the steady-state solution of a set of differential equations describing the kinetics of association and dissociation of each species to the two ends of the filament (in preparation). According to the above calculation, in the presence of 1 µM free ADF, if ATP-G-actin is equal to 0.58 µM at steady state, and if the amounts of ADF-ATP-G-actin and ADP-G-actin represent only 10% of the amounts of ATP-G-actin and ADF-ADP-G-actin, respectively (see the values of the equilibrium dissociation constants, Table II), the measured amount of 1.7 µM unassembled actin would imply that the concentration of ADFADP-G-actin is close to 1.12 µM. These values should be considered as plausible approximates that reasonably account for the data.
We should note that because ADF has a much higher affinity for ADP-actin than for ATP-actin, the nature of the
major actin species that associates to the filament (mostly
ATP-actin) is not the same as the one that dissociates from
the filament (mostly ADF-ADP-actin), both in terms of
bound nucleotide and in terms of bound ligand that potentially allows ADF to modulate the nonlinearity in the J(c)
plots (Carlier, 1991).
ADF Activates Actin-based Motility
Do the above in vitro biochemical properties of ADF provide a clue to understanding its cellular function in actinbased motility? It has long been recognized (Wang, 1985;
Fechheimer and Zigmond, 1993
) that net polymerization
of actin occurs at the front of locomoting cells, while net
depolymerization occurs throughout the lamella, but puzzlingly the rate of actin flux in this treadmilling-like process was one order of magnitude faster than expected from
the in vitro measurements of actin filament treadmilling.
Similarly, the rate of Listeria movement in Xenopus egg
extracts appeared 10-fold faster than the calculated rate of
actin assembly (Marchand et al., 1995
) in the medium. The
present data showing that ADF increases the rate of treadmilling in vitro up to values of the same magnitude as the
one observed in vivo in the lamellipodium (Small, 1995
;
Small et al., 1995
) lead us to conclude that endogenous ADF is responsible for this fast rate. The actin-based propulsion of Listeria monocytogenes in acellular extracts offers
an opportunity to test the effects of ADF in an integrated
system closer to the in vivo situation. ADF increases the
rate of propulsion because it increases the rate of depolymerization from the pointed ends of the bulk population
of filaments, which kinetically limits the rate of barbed end
assembly at the bacterium surface. This in turn causes the
shortening of the capped filaments present in the medium,
in particular those in the body of the actin tail attached to
the bacteria, hence a shortening of the tail itself. Assuming
that the motility assay of Listeria in acellular extracts is a
good model for actin-based motile processes in response
to signaling, these results indicate that ADF might, by the
same mechanism, control the dynamics and the length of
actin filaments in vivo. They also account for the enhanced
motility of cells overexpressing cofilin (Aizawa et al., 1996
),
and for the high levels of ADF in developmental stages
(Bamburg and Bray, 1987
; Abe et al., 1989
, 1996), in which
extensive actin dynamics are involved.
In conclusion, it is emphasized that different actin-binding proteins amazingly use the conformational switch of
ATP hydrolysis on actin in a variety of ways to modulate
actin dynamics. Profilin, in binding preferentially to ATPactin, promotes assembly at the barbed ends (Pantaloni
and Carlier, 1993; Perelroizen et al., 1996
). ADF, in binding preferentially to ADP-actin, enhances the directional
shuttling of subunits through the filaments.
Received for publication 8 November 1996 and in revised form 23 January 1997.
This work was funded in part by the Association pour la Recherche contre le Cancer (ARC), the Association Française contre les Myopathies (AFM), the EC (grant No. CHRX-CT94-0652), the Ligue Nationale Française contre le Cancer, and a grant from the National Science and Technology Board, Singapore.We thank Drs. Yukio Doi, David Drubin, Thomas D. Pollard, and Helen Yin for generous gifts of gelsolin, yeast cofilin, actophorin, and CapG, respectively, and Dr. Sally Zigmond for a detailed protocol of the preparation of spectrin-actin seeds. We are grateful to Jean Lepault for the electron microscopy work. We thank Matt Welch and Tim Mitchison for communication of the use of platelets to monitor actin-based motility of Listeria. We acknowledge helpful discussions with Drs. François Amblard, Joël Janin, Anthony Maggs, and Annemarie Weber, and the constructive comments of Dr. E.D. Korn on an earlier version of the manuscript.
ADF, actin depolymerizing factor;
NBD, 7-chloro-4-nitrobenzeno-2-oxa-1,3-diazole;
T4, thymosin
4.