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Vol. 14, Issue 7, 2617-2629, July 2003
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*Whitehead Institute for Biomedical Research and
Massachusetts Institute of Technology, Cambridge, Massachusetts 02142; and
Biology Department and Rosenstiel Center,
Brandeis University, Waltham, Massachusetts 02454
Submitted January 21, 2003;
Revised March 7, 2003;
Accepted March 7, 2003
Monitoring Editor: Anthony Bretscher
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ABSTRACT |
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 TOP ABSTRACT INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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defects, and
deletion of SCP1 enhances sac6 defects. Together,
these data show that Scp1 and Sac6/fimbrin cooperate to stabilize and organize
the yeast actin cytoskeleton. |
INTRODUCTION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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). One such
protein module, the calponin homology (CH) domain, is found in
actin-associated proteins that cross-link actin filaments (e.g., spectrin,
filamin, and fimbrin), link actin to other cytoskeletal systems (e.g., fimbrin
and plectin), and form signaling scaffolds (e.g., IQGAP, Vav; reviewed in
Gimona et al., 2002).
It is well established that a pair of CH domains forms a classic actin binding
domain (e.g., 
-actinin and fimbrin; reviewed in
Matsudaira, 1991). In
contrast, calponin family members contain only a single CH domain, and it
remains controversial whether this domain can bind to actin filaments
(Gimona and Winder, 1998;
Fu et al., 2000;
Winder, 2003).
The calponin protein family, which includes calponins and transgelins, is
characterized by a single CH domain located at the amino terminus and either
one or more calponin-like repeats (CLR) located at
the carboxy terminus (Prinjha et
al., 1994). Both mammalian transgelin and Saccharomyces
cerevisiae calponin (Scp1) have a single CLR, whereas mammalian calponin
contains three CLRs (Figure 1).
The calponin family is highly conserved from yeast to humans. Fungal genomes
(S. cerevisiae, Schizosaccharomyces pombe, and Neurospora
crassa) contain a single transgelin-like gene, whereas higher eukaryotic
genomes have multiple transgelins and calponins. This evolutionary
conservation of calponin family proteins suggests that they may have highly
conserved functions in vivo, yet our understanding of these functions is
limited. Calponin is a regulator of smooth muscle contraction, but the
functions of nonmuscle calponins are not as well understood (reviewed in
Morgan and Gangopadhyay,
2001).
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Transgelin (also called SM22 and WS3-10;
Lees-Miller et al.,
1987a; Lawson et al.,
1997) was named for its in vitro gelation activity on actin
filaments (Shapland et al.,
1993), but this activity has been questioned because it does not
occur at physiological salt concentrations (see DISCUSSION). In vivo,
transgelin localizes to actin structures such as stress fibers
(Fu et al., 2000),
yet the ability of transgelin to bind directly to actin filaments in vitro
also has been disputed (Gimona and Mital,
1998; Morgan and Gangopadhyay,
2001). Increased levels of transgelin expression have been
correlated with cell differentiation and senescence, but the function, if any,
of transgelins in these processes has not been demonstrated
(Thweatt et al.,
1992; Liu et al.,
1994; Grigoriev et
al., 1996). Thus, little is known about the in vitro or in
vivo functions of transgelins.
The S. cerevisiae genome contains a single open reading frame with
homology to the calponin protein family, and this gene was annotated as S.
cerevisiae calponin homolog, Scp1 (Epp
and Chant, 1997). However, the domain organization of Scp1 more
closely resembles transgelin than calponin. As shown in
Figure 1B, Scp1 contains a
single CH domain (residues 28–139; shaded) and one calponin-like repeat
(residues 174–200; underlined). The yeast genome encodes two other
proteins with readily apparent CH domains, Sac6 (fimbrin) and Iqg1/Cyk1
(IQGAP), shown schematically in Figure
1A. IQGAP has a single CH domain, localizes to the bud neck, and
functions in cytokinesis, but little is known about its interactions with
actin (Epp and Chant, 1997;
Lippincott and Li, 1998).
Sac6/fimbrin binds to and bundles actin filaments through a tandem pair of
actin binding domains, each comprised of two CH domains. Sac6 localizes to
cortical actin patches and actin cables and is important for actin
organization, endocytosis, and cell polarity in vivo
(Drubin et al., 1988;
Adams et al., 1991;
Kubler and Riezman, 1993).
Herein, we show that the S. cerevisiae transgelin homolog Scp1 is a novel component of the cortical actin cytoskeleton and a bona fide actin filament binding and cross-linking protein. The sequences in Scp1 critical for actin filament binding and cross-linking reside outside of the CH domain. Genetic interactions between SCP1 and SAC6/fimbrin and similar biochemical activities suggest that these two CH domain-containing proteins cooperate in vivo to regulate the stability and organization of the cortical actin cytoskeleton.
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MATERIALS AND METHODS |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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). To
generate AGY189, the coding regions of SAC6 and SCP1 in
AGY20 were replaced with LEU2 and HIS3, respectively. AGY189
was sporulated and resulting haploid strains of opposite mating type were
crossed to generate AGY490, AGY491, AGY492, and AGY493. For growth assays,
homozygous diploid strains carrying vectors (pRS313, pRS314, pRS315, and
pRS316) and/or plasmids (Table
2) were grown to log phase and then serially diluted fivefold,
spotted on plates, and grown for an additional 2–3 d. Latrunculin A
sensitivity of cells was measured by halo assays as described previously
(Ayscough et al.,
1997).
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Plasmid Construction
The coding region of the SCP1 gene (YOR367w), plus 397 bases of
sequence upstream of the translation start site, was amplified by polymerase
chain reaction (PCR) from wild-type yeast genomic DNA. The PCR product was
cloned into the ClaI and SmaI sites of pRS316
(Sikorski and Hieter, 1989),
generating pAG20. For additional SCP1 constructs, we introduced by
site-directed mutagenesis (QuikChange kit; Stratagene, La Jolla, CA), a
BglII site at the start codon of SCP1 in pAG20, generating
pAG3. To construct an amino terminal green fluorescent protein
(GFP)-SCP1 fusion plasmid (pAG9), we cloned GFP as a BamHI
fragment from plasmid B3355 (Fink laboratory collection) into the
BglII site of pAG3. To generate an Escherichia coli
expression amino terminal hexahistidine-SCP1 fusion construct
(pAG22), SCP1 was excised from pAG3 as a BglII-XhoI
fragment and cloned into the BamHI and XhoI sites of
pTrcHisA (Invitrogen, Carlsbad, CA). To generate SCP1
Gal-overexpression plasmids (pAG179), the BglII-XhoI SCP1
fragment was cloned into the BamHI and XhoI sites of
pRS426Gal1 (Christianson et al.,
1992). Point mutations in SCP1 (S185A and S185D) were
generated by site-directed mutagenesis as described above. To generate N136
and 136C constructs, sequences coding for the amino terminus and carboxy
terminus of Scp1 were amplified by PCR and cloned into NcoI and
HindIII sites of pProETTMHTa (Invitrogen) and pBAT4
(Peranen et al.,
1996). All mutant scp1 constructs were sequenced to
verify that no additional mutations had been introduced.
Protein Purification
Yeast actin was purified as described previously
(Goode et al., 1999).
His6-tagged Scp1 proteins were expressed in BL21/DE3 E. coli and
purified on nickel resin as per manufacturer's instructions (QIA-GEN,
Valencia, CA). Peak fractions eluted from the nickel column were pooled and
fractionated on a monoQ (5/5) column by using an AKTA FPLC (Amersham
Biosciences, Piscataway, NJ). Peak fractions were pooled, concentrated in a
Centricon 10 device (Millipore, Bedford, MA), and exchanged into HEKG5 buffer
(20 mM HEPES, pH 7.5, 1 mM EDTA, 50 mM KCl, 5% glycerol). The proteins were
aliquoted, frozen in liquid nitrogen, and stored at –80°C. Untagged
carboxyl-terminal fragment of Scp1 was expressed in E. coli. Cells
were lysed in HEKG5 buffer by using french press, and the lysate was clarified
by centrifugation at 313,000 x g at 4°C for 30 min
(high-speed supernatant; HSS). HSS was fractionated on a 1-ml HiTrap SP column
(Amersham Biosciences). Peak fractions were pooled, diluted in low salt
buffer, and fractionated on a Mono S column. Peak fractions were concentrated
and fractionated on a Superdex 75 (5/30) column (Amersham Biosciences)
equilibrated in HEKG5 buffer. Peak fractions were pooled concentrated,
aliquoted, frozen in liquid nitrogen, and stored at –80°C. Untagged
full-length Scp1 was purified from yeast overexpressing SCP1 (BJ2168
carrying pAG179). One liter of cells was grown to mid-log phase in SC-His
medium with 2% raffinose. Then, 2% galactose was added to the medium, and
cells were grown for an additional 12 h and harvested by centrifugation. The
cell pellet was resuspended in 0.3 volume of water and frozen in droplets in
liquid nitrogen. Next, the frozen yeast cells were lysed in a coffee grinder
by using liquid nitrogen, described under "Lab Protocols" on the
Goode Laboratory Web site at
www.bio.brandeis.edu/goodelab.
An HSS was generated in HEKG5 buffer supplemented with 0.5 mM dithiothreitol
(DTT) and protease inhibitors as described previously
(Goode et al., 1999).
The HSS was fractionated on a 1-ml HiTrap SP column (Amersham Biosciences),
and proteins were eluted with a linear salt gradient (50–500 mM KCl).
Scp1 eluted at approximately 200 mM KCl. Peak fractions were pooled and
concentrated to 3 ml in a Centricon 10 device and then fractionated on a
Superdex 75 (26/60) column (Amersham Biosciences) equilibrated in HEKG5
buffer. Peak fractions were pooled, concentrated as described above,
aliquoted, frozen in liquid nitrogen, and stored at –80°C. Sac6 was
purified as described above for untagged Scp1 with the following exceptions:
AAY1918 strain was used for galactose induction; after the HSS was
fractionated on a HiTrap Q column, the Sac6-containing fractions were pooled,
desalted, and fractionated on a monoQ (5/5) column. Peak fractions were
pooled, concentrated in Centricon 10 devices, and fractionated on a Superose12
(5/30) gel filtration column (Amersham Biosciences) equilibrated in HEKG5
buffer. Sac6 peak fractions were pooled, concentrated, aliquoted, frozen in
liquid nitrogen, and stored at –80°C. Tpm1 was purified as described
previously (Liu and Bretscher,
1989).
Actin Filament Binding and Cross-Linking Assays
Yeast actin was assembled as follows. Actin (50 µM) in G-buffer (10 mM
Tris, pH 7.5, 0.2 mM CaCl2, 0.2 mM DTT, 0.2 mM ATP) was thawed on
ice, precleared by centrifugation, and 20x initiation mix (10 mM ATP, 40
mM MgCl2, 1 M KCl) was added to induce polymerization. Reactions
were incubated for 1 h at 25°C. Then, actin filaments were diluted in
F-buffer (10 mM Tris, pH 7.5, 0.2 mM CaCl2, 0.2 mM DTT, 0.7 mM ATP,
2 mM MgCl2, and 50 mM KCl), purified proteins (Scp1, Sac6, and
Tpm1), and/or HEKG5 buffer was added, and the reactions were incubated at room
temperature for 1 h. For low-speed pelleting assays, reactions were
centrifuged for 10 min at 10,000 x g, 4°C. For high-speed
pelleting assays, actin filaments were pelleted by centrifugation for 30 min
at 313,000 x g in a TLA100 rotor (Beckman Coulter, Fullerton,
CA). In both assays, supernatants and pellets were fractionated on SDS-PAGE
gels, stained with Coomassie, and bands were quantified by densitometry with
NIH Image (version 1.61, available at
sippy.nimh.nih.gov).
The binding constant (Kd) of Scp1 for actin filaments was
defined as the concentration of Scp1 at which half-maximal Scp1 binding
occurred. For light scattering assays, yeast actin was thawed on ice, diluted
in G-buffer, and mixed with 20x initiation mix plus Scp1 and/or HEKG5
buffer. Light scattering was monitored overtime at 360 nm in a fluorescence
spectrophotometer (Photon Technology International, Lawrenceville, NJ) held at
a constant temperature of 25°C. Apparent viscometry of actin solutions was
measured by the falling ball assay, performed as described previously
(Pollard and Cooper, 1982).
Rabbit muscle G-actin (Cytoskeleton, Denver, CO) was clarified by
centrifugation for 30 min at 313,000 x g 4°C in a TLA100
rotor. Capillary tubes were loaded with actin (4.2 µM), initiation salts,
and varying concentrations of His6-Scp1 (0, 0.23, 0.46, 0.93, 1.4, 1.8, and
3.7 µM) and incubated at room temperature for 1 h before falling ball
measurements. For electron microscopy, 2 µl of reactions were spotted onto
freshly ionized carbon-coated grids, stained with 1% uranyl acetate, and
visualized using a Phillips EM410 transmission electron microscope.
Actin Filament Disassembly Kinetics
Yeast actin (with 1% pyrene labeled rabbit skeletal muscle actin;
Cytoskeleton) was assembled at 35 µM as described above. Actin filaments (7
µl) in F-buffer was mixed with 52.5 µl of F-buffer and 7 µl of Scp1
and/or HEKG5 buffer and incubated for 10 min at room temperature. Actin
filaments were agitated by vortexing for 10 s, and then mixed with 3.5 µl
of latrunculin A (400 µM) in a cuvette. The final reactions contained 3.5
µM actin, 20 µM latrunculin A, and variable concentrations of Scp1
(0–2 µM). The depolymerization kinetics of pyrene-labeled actin
filaments was monitored by excitation at 365 nm and emission at 407 nm in a
fluorescence spectrophotometer held at a constant temperature of 25°C.
Fluorescence Light Microscopy
Images of cells were acquired using a Nikon TE300 inverted fluorescence
microscope equipped with a Hamamatsu Orca charge-coupled device camera
controlled by Openlab software (Improvision, Lexington, MA). The localization
pattern of GFP-Scp1 fusion protein was examined in live yeast cells grown to
log phase. To disrupt the actin cytoskeleton, cultures were treated with 200
µM latrunculin A for 5 min before imaging
(Figure 2A). Colocalization of
GFP-Scp1 and actin (Figure 2B)
was performed essentially as described previously
(Warren et al.,
2002). Briefly, 1 ml of exponentially growing cells was fixed with
70% ethanol on ice for 10 min, and cells were pelleted by centrifugation at
3000 x g and resuspended in 100 µl of phosphate-buffered
saline buffer plus 1 mg/ml bovine serum albumin and 10 µl of
rhodamine-phalloidin (300 U in 1.5 ml of methanol; Molecular Probes, Eugene,
OR). After incubation on ice for 5 min, cells were washed three times in
phosphate-buffered saline buffer and mounted on a slide for imaging.
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RESULTS |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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16% of actin patches (n =
89) did not have a corresponding GFP signal. This leaves open the possibility
that some actin patches do not contain Scp1.
Deletion of SCP1 Enhances sac6 Phenotypes
To further study SCP1 in vivo function, we generated a complete
deletion of the SCP1 gene. This mutation alone had no salient
phenotype in haploid or diploid cells, but did show specific genetic
interactions with sac6. Among the many phenotypes tested for
the scp1 single mutants were growth at a full range of
temperatures, growth under various stresses (e.g., NaCl, caffeine, and
benomyl), cell morphology, bipolar budding pattern, actin cytoskeleton
organization, and endocytosis (assayed by lucifer yellow, FM4-64 uptake and
Ste6 internalization). The only detectable phenotype of scp1
was a modest but reproducible sensitivity to latrunculin A
(Table 3). Given the high
degree of functional redundancy among components of cortical actin patches
(reviewed in Pruyne and Bretscher,
2000; Goode and Rodal,
2001), we tested for synthetic genetic interactions between
SCP1 and other genes that regulate actin function. The
scp1 mutants showed synthetic defects only with
sac6, but not with abp1, aip1,
arp2-1, cap2, cof1-22, crn1,
end3, las17, pan1-4, rvs167,
sla1, sla2, srv2,
tpm1, or tpm2. Deletion of SCP1
enhanced many phenotypes of sac6, including temperature and
caffeine sensitivity (Figure
3A), salt sensitivity (our unpublished observation), and
latrunculin A sensitivity (Table
3). Deletion of SCP1 did not further enhance the actin
organization or endocytosis phenotypes of sac6 cells, which
already have depolarized actin cytoskeleton and fail to accumulate lucifer
yellow dye in the vacuole (our unpublished observations).
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The scp1 sac6 double mutant cells provided
a genetic background that permits direct testing of the Scp1 function in vivo.
Mutation of a conserved serine residue in the CLR of mammalian calponin
(Ser175) and transgelin (Ser184) disrupts actin binding in vitro
(Tang et al., 1996;
Fu et al., 2000). To
test whether the analogous residue in Scp1 (S185;
Figure 1B) is important for in
vivo function, we generated two substitutions (S185A and S185D).
scp1 sac6 cells transformed with wild-type or
mutant SCP1 constructs were analyzed for growth phenotypes. Both
wild-type SCP1 and scp1S185D suppressed the growth defects
of scp1 sac6 cells, indicating that these
constructs restore SCP1 function. In contrast, cells expressing
scp1S185A grew only slightly better than control cells carrying an
empty vector (Figure 3A). Stable expression of the mutant proteins was verified by immunoblotting (our
unpublished observations). These data indicate that the conserved serine
residue (located in the CLR) is critical for Scp1 function in vivo.
Additional Copies of SCP1 Partially Suppress the sac6 Growth
Phenotype
SCP1 expressed from a low copy plasmid suppressed the temperature
sensitivity of sac6scp1 double mutant cells
(Figure 3A). To investigate the
basis of this effect, we quantified the expression levels of actin, Sac6, and
Scp1 in cells, comparing cell extracts to standard curves of purified proteins
(actin, Sac6, and Scp1) by immunoblotting. The level of Scp1 (0.01
ng/µg total cellular protein) was considerably lower than that of Sac6
(0.15 ng/µg) and actin (1 ng/µg). From these values, we
calculated that the molar ratio of actin, Sac6, and Scp1 in cells is
65:6:1. The expression level of Scp1 in
sac6scp1 cells carrying a low copy
SCP1 plasmid was two- to threefold higher than endogenous Scp1 levels
in wild-type cells (our unpublished observations). This suggested that extra
copies of SCP1 can suppress sac6 cell growth defects.
To test this hypothesis directly, we transformed sac6 cells
with low copy plasmids expressing wild-type and mutant Scp1 proteins. As shown
in Figure 3B, a wild-type
SCP1 plasmid partially suppressed the temperature sensitivity of the
sac6 mutant. scp1S185D also partially suppressed the
sac6 phenotype, whereas scp1S185A showed no
suppression. Thus, low-level overexpression of SCP1 partially
suppresses the temperature-sensitive growth phenotype of the
sac6 mutant, and a specific mutation in SCP1
abolishes this suppression.
Scp1 Binds to and Cross-Links Actin Filaments In Vitro
To test whether Scp1 interacts directly with actin filaments in vitro, we
overexpressed Scp1 in yeast by using a galactose-inducible promoter, purified
the protein, and measured its ability to bind actin filaments in a high-speed
cosedimentation assay. As shown in Figure
4, A and B, Scp1 bound to yeast actin filaments in a
concentration-dependent manner with micromolar binding affinity
(Kd = 0.7 µM) and a molar saturation stoichiometry of
1:2 Scp1 to actin. Hexahistidine (His6)-tagged Scp1 expressed and purified
from E. coli bound to actin filaments with a similar affinity
(Figure 4C).
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Mammalian calponin family members have been shown to cross-link actin
filaments (Shapland et al.,
1993; Kolakowski et
al., 1995; Tang et
al., 1997). Using several complementary approaches, we found
that Scp1 has a similar activity. First, His6-Scp1 increased light scattering
of yeast actin filaments in a concentration-dependent manner
(Figure 5A), suggesting that
Scp1 organized filaments into larger structures (e.g., bundles or networks).
Second, we analyzed the reactions from the light scattering experiment in a
low-speed pelleting assay. In the absence of Scp1, most actin remained in the
supernatant as expected, but with increasing amounts of Scp1, actin shifted to
the pellet (Figure 5B). This
concentration-dependent increase in actin pelleting correlated with the
observed increase in light scattering
(Figure 5A). To ensure that
actin cross-linking by His6-Scp1 was not due to the tag, we tested untagged
Scp1 in the low-speed actin-pelleting assay.
Figure 5C shows that the
effects of 1 µM untagged Scp1 are nearly identical to the effects of 1
µM His6-Scp1. These results demonstrate that Scp1 cross-links actin
filaments in vitro.
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To characterize the actin cross-linking activity of Scp1 further, we used
the falling ball assay (Pollard and
Cooper, 1982) to measure the apparent viscosity of the actin
filament solution in the presence and in the absence of His6-Scp1. The
apparent viscosity of a 4 µM actin filament solution increased markedly
when Scp1 concentration exceeded 1 µM
(Figure 5D). We also examined
by electron microscopy negatively stained actin filaments in the presence and
in the absence of His6-Scp1. In the absence of Scp1, actin filaments were
distributed evenly throughout the grid
(Figure 6A). When actin was
polymerized in the presence of Scp1, actin filaments formed loose bundles
tangled into networks (Figure 6, B and
C). Scp1 cross-linked bundles seemed wavy, and the spacing between
filaments in a bundle was not uniform. In contrast, Sac6/fimbrin bundles were
straight with uniform spacing between filaments
(Figure 6D).
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The Carboxy Terminus of Scp1 Alone Can Cross-Link Actin
Filaments
To better understand the molecular mechanism of actin binding and
cross-linking by Scp1, we expressed and purified amino-terminal N(1–136)
and carboxyl-terminal C(136–200) fragments of Scp1
(Figure 1C). Although we
attempted to generate both His6-tagged and untagged constructs in E.
coli, we were able to isolate only the His6-tagged N(1–136) and
untagged C(136–200). We tested the purified proteins for actin binding
in the high-speed pelleting assays. In contrast to the full-length Scp1, the
N(1–136) fragment did not copellet with actin filaments
(Figure 7A). The
C(136–200) fragment, on the other hand, copelleted with actin filaments,
indicating that at least one actin-binding site resides in the carboxy
terminus of Scp1. We also tested the ability of the truncated proteins to
cross-link actin filaments. In a low-speed pelleting assay, actin remained in
the supernatant in the absence of Scp1 and in the presence of N(1–136)
(Figure 7B). However, actin was
found mostly in the pellet in the presence of the carboxyl-terminal fragment
or the full-length Scp1. Therefore, untagged carboxy terminus of Scp1 is
sufficient to cross-link actin filaments.
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In addition, we addressed whether a specific residue in the carboxy terminus (S185) critical for in vivo function of Scp1 (see above), was also important for actin filament binding. We purified the His6-tagged S185A and S185D mutant Scp1 proteins and compared their ability to bind and cross-link actin filaments with the wild-type Scp1. Scp1S185D bound to actin filaments in a high-speed actin pelleting assay (Figure 7C), cross-linked actin filaments in the low-speed actin pelleting assay (our unpublished observations), and increased light scattering of the actin filaments similar to wild-type Scp1 (Figure 7D). In contrast, Scp1S185A had greatly diminished actin binding and cross-linking activities (Figure 7, C and D; our unpublished observations). These results suggest that Scp1S185D retains much of the wild-type Scp1 interaction with actin. However, Scp1S185D showed reduced actin binding affinity compared with wild-type Scp1 at higher salt concentrations (150 mM KCl; our unpublished observations). Therefore, the Scp1S185D interaction with actin may be weakened, but not nearly to the extent of Scp1S185A.
Scp1, Like Fimbrin, Decreases the Rate of Actin Filament
Disassembly
Both Sac6/fimbrin (Bretscher,
1981; Adams et al.,
1991) and Scp1 (Figures
4 and
5) bind to and cross-link actin
filaments; in addition, Sac6 stabilizes actin filaments against disassembly
(see Figure 5 in Goode et al.,
1999). To address whether Scp1 similarly can stabilize actin
filaments, we compared pyrene-actin filament disassembly kinetics in the
presence and absence of His6-Scp1. In the absence of Scp1, actin filaments
disassembled rapidly, and pyrene fluorescence reached steady state by 600 s
(Figure 8A). His6-Scp1 reduced
the rate of actin filament disassembly in a concentration-dependent manner.
Similar effects were observed using untagged Scp1 (our unpublished
observations). Thus, Scp1, like Sac6/fimbrin, stabilizes actin filaments.
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Scp1 and Sac6 Compete for Actin Filament Binding In Vitro
Given that Scp1 and Sac6/fimbrin show genetic interactions and have similar
biochemical activities on actin, we investigated whether they also have
overlapping binding sites on actin filaments. We tested the ability of Scp1 to
compete with Sac6 for binding to actin filaments in a high-speed
cosedimentation assay, by using constant concentrations of Sac6 (0.5 µM)
and actin filaments (2 µM) and variable concentrations of His6-Scp1
(0–7 µM). In the absence of Scp1, nearly 90% of the Sac6 bound to
actin filaments (Figure 8, B and
C). The percentage of Sac6 bound to actin filaments decreased
proportionally with increasing concentrations of Scp1. To test the specificity
of the competition, we assayed Sac6 binding to actin in the presence of
another actin binding protein, tropomyosin (Tpm1). A range of Tpm1
concentrations (1–10 µM) had no effect on Sac6 binding to actin
filaments (our unpublished observations). Thus, Scp1 specifically competes
with Sac6 for binding to actin.
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DISCUSSION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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; Morgan and
Gangopadhyay, 2001). Herein, we have shown unambiguously that the
yeast transgelin homolog Scp1 binds directly to actin filaments, cross-links
and stabilizes actin filaments in vitro, and localizes to actin filament
structures in vivo. Furthermore, we established that the sites on Scp1
necessary and sufficient for actin cross-linking reside in the carboxy
terminus, outside the CH domain. We also provide the first in vivo evidence
for transgelin cellular function, showing that Scp1 cooperates with Sac6
(fimbrin) to organize and stabilize the actin cytoskeleton. Finally, our
mutant analysis revealed a correlation between in vivo phenotypes and in vitro
activities on actin, demonstrating that actin binding is required for Scp1 in
vivo functions.
Activities of Scp1 on Actin Filaments In Vitro
Scp1 binds directly to actin filaments with an affinity
(Kd of 0.7 µM) similar to that reported for other
members of the calponin family: 1 µM for calponin
(Lu et al., 1995;
Tang et al., 1996)
and 1.3 and 1.4 µM for transgelin
(Shapland et al.,
1993; Kobayashi et
al., 1994). Scp1 also cross-links actin filaments. Previous
studies have reported actin filament bundling for calponin
(Kolakowski et al.,
1995) and actin filament gelation for transgelin
(Shapland et al.,
1993). However, the ability of transgelin to cross-link actin
filaments has been questioned (Morgan and
Gangopadhyay, 2001), in part because the gelation activity occurs
specifically in low ionic strength buffer and is blocked by the addition of 10
mM KCl (Shapland et al.,
1993). Using four independent assays, we showed that His6-Scp1 and
untagged Scp1 each cross-link actin filaments in buffer containing 50 mM KCl.
One possible explanation for the discrepancy between previous results and ours
is that previous experiments tested transgelin and actin from different
species, whereas our experiments used transgelin (Scp1) and actin from the
same organism. This raises the possibility that other transgelins besides Scp1
also cross-link actin filaments.
By what mechanism does Scp1 cross-link actin filaments? Cross-linking
requires either the presence of two actin binding sites within a single
polypeptide chain or dimerization of an actin binding protein. All of the data
available for calponin family members suggest that they do not dimerize,
because they behave as monomers in sedimentation velocity, sedimentation
equilibrium, and gel filtration experiments
(Lees-Miller et al.,
1987b; Stafford et
al., 1995). Similarly, we found no evidence for Scp1
dimerization by using several methods: gel filtration, yeast two-hybrid assay,
and coimmunoprecipitation of HA-tagged Scp1 with untagged Scp1 (our
unpublished observations). We cannot rule out the possibility that Scp1
dimerizes (e.g., it may dimerize specifically when bound to actin). However,
based on the available data, we speculate that Scp1 (and possibly other
calponins) cross-link actin filaments via two distinct actin binding
sites.
The location of the two sites required for actin filament cross-linking was
revealed by the analysis of the mutant proteins. One actin binding site
probably resides in the CLR (Figure
1B), because specific mutation of a single residue in the CLR
(S185A) abolished actin filament cross-linking and greatly reduced actin
binding affinity of Scp1. These results are in agreement with the previous
studies that identified the analogous serine residue to be critical for actin
binding of other calponin family members
(Winder et al., 1993;
Tang et al., 1996;
Fu et al., 2000).
These data also suggest that the mechanism of actin binding by calponins is
highly conserved.
Our analysis of the truncated Scp1 constructs revealed the location of a
second site required for actin filament cross-linking. The amino-terminal Scp1
fragment His6-N(1–136) containing CH domain did not bind to actin
filaments, whereas the carboxy-terminal fragment C(136–200) not only
bound to actin filaments, but also cross-linked them. It is formally possible
that the hexa-histidine tag interfered with the actin binding of the
amino-terminal fragment, yet it seems unlikely, given that the full-length
his-tagged Scp1 bound to actin filaments. In addition, single CH domains of
mammalian calponin and transgelin are also not sufficient for in vitro binding
to actin filaments (Gimona and Mital,
1998; Fu et al.,
2000). The second actin binding site or dimerization site of Scp1
must reside in the sequences between the CH domain and the CLR. This site may
be analogous to the actin binding site S1 of calponin
(Mezgueldi et al.,
1995; Mino et al.,
1998; Figure 1A).
Although the sequence of S1 is not conserved among calponin isoforms or in
transgelins (Gimona and Mital,
1998), this region is enriched in positively charged amino acids
in all calponin family members. Mutations of the positively charged amino
acids in this region decrease actin binding affinity of calponin and
transgelin (Gong et al.,
1993; Fu et al.,
2000). Further mutational analysis of Scp1 will be required for
precise identification of the residues required for cross-linking of the actin
filaments.
Does the CH domain of Scp1 contribute to actin binding? Our data show
clearly that the CH domain is neither sufficient nor necessary for actin
filament binding by Scp1, yet Scp1 competes for actin binding with
Sac6/fimbrin, which binds actin via two tandem pairs of CH domains. This
apparent discrepancy may be explained by a recently proposed model. Based on
comparing cryo-electron microscopy reconstructions of calponin and fimbrin
decorated actin filaments, it was suggested that the CH domain of calponin may
serve as a "locator" domain, helping to position the true actin
binding motifs in calponin (reviewed in
Winder, 2003). The CH domain
of Scp1 may act similarly.
Scp1 Functions with Sac6 to Regulate the Actin Cytoskeleton In
Vivo
Our genetic and biochemical data, as well as subcellular localization,
reveal a functional relationship between Scp1 and Sac6/fimbrin. Both GFP-Scp1
(this work) and Sac6 (Drubin et
al., 1988) localize to cortical actin patches. Sac6 was also
reported to colocalize faintly with actin cables by immunofluorescence;
however, this was not observed with GFP-Sac6
(Doyle and Botstein, 1996).
Therefore, it is possible that Scp1 localizes in vivo to both actin patches
and cables, but that we have only been able to detect patch localization with
GFP-Scp1. Biochemical analyses show that Scp1 and Sac6 have similar activities
on actin. Like Sac6/fimbrin, Scp1 cross-links actin filaments in vitro. Sac6
cross-links actin filaments into tight bundles, and Scp1 cross-links actin
into loose bundles and networks. Scp1, like Sac6/fimbrin, not only organizes
actin filaments but also decreases the rate of actin filament disassembly
(filament stabilization). The shared role of SAC6 and SCP1
in stabilizing the actin cytoskeleton is supported further by the latrunculin
A sensitivities of sac6 and scp1 mutant cells.
Together, these in vitro and in vivo observations suggest that Scp1 and Sac6
cooperate in organizing and stabilizing the actin cytoskeleton.
The overlapping genetic functions of SCP1 and SAC6 may be
related to their relative abundance in cells and their ability to compete for
actin binding. Using quantitative immunoblotting, we defined the in vivo molar
ratios of actin, Sac6, and Scp1 to be 65:6:1 (actin to Sac6 to Scp1). The
higher levels of Sac6 compared with Scp1 suggest that Sac6 may provide the
more "dominant" activity on actin. This idea is supported by the
relative strengths of their respective null phenotypes. Furthermore, this
could explain why as little as two- to threefold higher expression of Scp1
partially suppresses defects in sac6 cells.
To demonstrate the importance of the Scp1–actin interaction for in
vivo functions, we have used a mutant of Scp1 that has a weak affinity for
actin filaments in vitro. scp1S185A failed to suppress loss of
SAC6 or loss of SCP1 function in a sac6
background. On the other hand, scp1S185D mutant, which retained actin
filament binding in vitro, suppressed the phenotypes associated with the loss
of SCP1 and SAC6 in vivo. These results provide strong
evidence that Scp1–actin interactions are required for in vivo functions
of Scp1 shared with Sac6.
A functional relationship between calponins and fimbrin may be conserved in
other organisms. Both protein families are widely expressed in different
vertebrate tissues and have overlapping subcellular locations. In fibroblasts,
fimbrin and calponin are both found on stress fibers
(Shapland et al.,
1988; Messier et al.,
1993; Babb et al.,
1997; Jiang et al.,
1997;), where they might function together to regulate actin
cross-linking and stabilization. In addition, fimbrin and calponin may play a
role in adhesive actin structures, linking the actin cytoskeleton to the cell
membrane. Fimbrin is found at focal adhesions and podosomes
(Messier et al.,
1993; Babb et al.,
1997), and calponin is found in dense plaques, a type of adherence
junction similar to podosomes and focal adhesions
(North et al., 1994).
Finally, it has been proposed that fimbrin may link the actin cytoskeleton to
the vimentin intermediate filament cytoskeleton, and a vimentin-binding site
has been mapped to the first CH domain of fimbrin
(Correia et al.,
1999). A similar function for calponin has been suggested by in
vitro binding studies and overlapping in vivo localization of desmin and
calponin (North et al.,
1994; Mabuchi et al.,
1996; Wang and Gusev,
1996). Thus, calponin and fimbrin may have shared in vivo
functions that are conserved across a wide range of organisms.
|
ACKNOWLEDGMENTS |
|---|
|
TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
|---|
|
Footnotes |
|---|
Abbreviations used: CH calponin homology, CLR calponin-like repeat. Supplementary video: Changes in GFP-Scp1 localization over time (consecutive frames taken at 3-s intervals).
Online version of this article contains video material for some figures.
Online version is available at
www.molbiolcell.org. 
Corresponding author. E-mail address:
gfink{at}wi.mit.edu.
|
REFERENCES |
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) and Scp1 (
) bound to
actin filaments were calculated from gel densitometry and plotted versus the
total concentration of His6-Scp1 in the reactions.