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J Biol Chem, Vol. 274, Issue 53, 37908-37914, December 31, 1999
From the Spinal muscular atrophy (SMA) is an autosomal
recessive disorder characterized by the loss of Spinal muscular atrophies
(SMAs)1 types I, II, and III
are autosomal hereditary diseases of graded severity in which loss of motoneurons leads to paralysis and subsequent atrophy of skeletal muscles, and in the most severe Werdnig-Hoffmann type I form, to death
in early infancy. The corresponding SMA disease genes have been mapped
to human chromosome 5q (1). There are two genes in close vicinity, the
telomeric SMN1 (or SMNT) and the
centromeric SMN2 (or SMNC; 2).
Although they have identical coding sequences for a 294-amino acid SMN
polypeptide, pathogenic mutations were found solely in SMN1.
Its gene product, the 40-kDa protein "survival motoneuron," SMN, is
expressed ubiquitously, and its concentration is reduced drastically in
the spinal cord of SMA patients (3, 4). There is evidence, mostly from
a yeast two-hybrid screen and from a Xenopus oocyte model
system, that the SMN protein is engaged in the assembly of spliceosomal
U snRNPs in the cytoplasm (5-7). Recently, the function of SMN has
been demonstrated by a dominant-negative mutant of SMN which inhibits
pre-mRNA splicing by blocking the formation of a mature spliceosome
(8).
The severity of SMA has been correlated with a deficient
oligomerization of mutated SMN proteins, and it has been hypothesized that the critical level of functional SMN oligomers in normal motoneurons may be controlled by SMN's binding to a motoneuron-specific factor (9). There are seven coding exons in the human SMN
gene, and SMN splice variants lacking exons 5, 7, or both are found. SMN2 expresses predominantly a In the mouse, there is only one gene coding for SMN, located on
chromosome 13, within the region of conserved synteny with human
chromosome 5q13 (15). No alternative splicing of the transcripts has
been found in the mouse. The predicted amino acid sequence of mouse SMN
is 82% identical to that of the human protein, including a conserved
putative nuclear localization signal (15). No murine mutations
homologous to human chromosome 5q SMAs have been found (16), and a
functional knockout of the gene coding for SMN causes death of early
embryos (17) suggesting, in accordance with biochemical evidence (6),
that SMN is an essential housekeeping protein (18).
Several ligand binding sites have been identified in SMN protein. Based
on a yeast two-hybrid screen using SMN as a bait, SIP-1
(SMN-interacting protein 1) was selected and shown to interact with SMN
in vivo and in vitro (6). The SMN·SIP-1
complexes are large (approximately 300 kDa) and contain additional
proteins several of which were shown to be U snRNP proteins (6). The proteins within this complex are involved in spliceosomal snRNP biogenesis (7) and in pre-mRNA splicing (8). Two of these proteins
contain an Sm domain (recognized by autoimmune sera of the Sm
serotype), SmB and SmB', and bind recombinant SMN in vitro (6). These results correlate with the localization of SMN protein in
nuclear structures called gems (5) and, assuming that SMN and SIP-1 are
involved in the recycling of U snRNP in the nucleus, also in the
cytoplasm (3, 5).
The polyproline stretch in the SMN protein contains a symmetric motif
with the sequence
Pro5-X17-Pro10-X17-Pro5
(with X specifying any amino acid residue); no similar motif
has been described for any other protein. This motif is highly
conserved between human and mouse SMN (2, 15), implying that it has an
essential function. Several polypeptides comprising proline clusters
regulate actin polymerization (19). As polyproline-rich ligands of
profilins, the mammalian proteins VASP (20), Mena (21), and p140mDia (22) have been characterized. In several mammals, two isoforms of
profilins have been identified (see references in 23) which differ
slightly in their affinities for the various ligands. In particular,
bovine profilin I (PFN I) was found to have a lower affinity for
polyproline motifs than profilin II (PFN II; 24). PFN I is expressed
early in mammalian embryogenesis (25) and is distributed widely in
various cells and tissues, whereas PFN II is not expressed in most
tissues tested but is highly concentrated in the central nervous system
and in cultured neurons (26).
Prompted by the conspicuous proline stretches in SMN, we analyzed the
possible interaction of this protein with both isoforms of profilin,
PFN I and PFN II.
A preliminary report of this work has been given (27).
Yeast Two-hybrid Assay--
cDNA fragments encoding human
SMN, SMN In Vitro Transcription/Translation and Production of Fusion
Proteins--
The coding regions of human SMN and SMN Dot Overlay Assays--
100 pmol of MBP (New England Biolabs)
and recombinant MBP-SMN fusion protein or 500 pmol of mouse PFN I and
II were immobilized on a nitrocellulose membrane using a dot blotter
with circular slots of 5-mm diameter (Biometra, Göttingen). The
transfer was checked by reversible Ponceau staining, and unspecific
binding sites were blocked with 5% non-fat milk powder in
phosphate-buffered saline (PBS; 140 mM NaCl, 10 mM Na,K phosphate, pH 7.3). In vitro translated
proteins were diluted in PBS containing 1% (w/v) BSA and 20 mM Affinity Precipitation--
Purified recombinant mouse PFN II
and BSA (as a negative control) were coupled to NHS-Sepharose 4B Fast
Flow (Amersham Pharmacia Biotech, Uppsala) with an efficiency of 10-15
µg of bound protein/µl of NHS material. Free NHS groups were
blocked with ethanolamine. Aliquots of 25 µl in vitro
transcription/translation reaction mixture were diluted in PBS and
incubated with 10 µl of conjugated Sepharose for 4 h at 4 °C.
After sedimentation, the beads were washed successively with standard
PBS, 140 mM NaCl, high salt saline, 290 mM
NaCl, and PBS with 0.2% Triton X-100. The SDS-denatured proteins of
the first supernatant and of the washed pellets were separated by
SDS-PAGE, and the gel was blotted onto nitrocellulose membrane. The
35S-labeled polypeptides were detected by autoradiography.
Tissues and Cells--
Spinal cords were dissected from freshly
killed 40-60-day-old mice (strain C57BL/6). Immunopositive gems were
only observed when the preparations were done rather swiftly until the
tissue blocks were shock frozen in liquid nitrogen-isopropane. In some cases mice were perfused under deep anesthesia with a solution of 9 g/liter NaCl, 25 g/liter polyvinylpyrrolidone (40 kDa), 0.25 g/liter
heparin, and 5 g/liter procaine-HCl, pH 7.2, to remove blood plasma.
Perfusions were done in accordance with the German law for the
protection of animals with a permit by the local authority.
HeLa cells were cultured either directly in 10-cm dishes or on glass
coverslips coated with collagen in Dulbecco's modified Eagle's medium
(Biochrom KG, Berlin) supplemented with 10% fetal calf serum (PAA
Laboratories, Cölbe, FRG), according to standard procedures.
In Situ Hybridization--
Riboprobes specific for PFN I and II
were prepared from cDNAs containing the entire coding region (PFN
I, accession number X14425; PFN
II,2), cloned in pGEM-3
(Promega). The riboprobes were generated by in vitro
transcription with SP6 (sense for PFN I, antisense for PFN II) and T7
(antisense for PFN I, sense for PFN II) polymerase with
fluorescein-conjugated UTP (in situ color kit, Amersham
Pharmacia Biotech). Spinal cord segments were fixed in 3%
paraformaldehyde in buffered saline and embedded in paraffin according
to standard procedures. Deparaffinized sections (5 µm) were
hybridized with riboprobes (400 ng/ml) overnight at 55 °C and
subsequently washed with 1 × SSC, 0.1% SDS, 0.2 × SSC,
0.1% SDS at 55 °C for 10 min followed by 0.1 × SSC, 0.1% SDS
at 55 °C for 5 min. After washing, samples were treated with RNase A
(10 µg/ml in 2 × SSC) for 15 min at 37 °C. Bound riboprobe
was detected with an anti-fluorescein antibody coupled to alkaline
phosphatase and subsequent color reaction using nitro blue
tetrazolium/5-bromo-4-chloro-3-indolyl phosphate as substrate.
Antibodies--
12 anti-profilin hybridoma clones (with
recombinant mouse PFN I and II as immunogens) have been used in the
course of this study. Several monoclonal antibodies showed isoform
specificity in immunoblots with SDS-denatured antigens but not on
sections. Some antibodies recognized diffuse PFN but not PFN in gems. A possible explanation for these differences might be epitope masking or
modification. Several antibodies recognized human and bovine PFN in
immunoblots and cultured cells but not mouse PFNs. Problems with mouse
monoclonal antibodies on mouse tissue sections, due to endogenous mouse
IgG, could in part be overcome by perfusion of the animals. Results
obtained with the following antibodies were included in this study:
monoclonal antibody 2B1 directed against human SMN (IgG; generous gift
of Dr. G. Dreyfuss, Ref. 5, and purchased from Transduction Labs,
Lexington, KY), henceforth designated mc-a-SMN; a commercial polyclonal
antibody that recognizes both PFN isoforms (Alexis Co., San Diego, CA),
here designated pc-anti-PFN; monoclonal IgG 2H11, raised against a
fusion protein of an Immunoprecipitation of Protein Complexes after in Situ
Cross-linking--
In situ cross-linking, precipitation,
and analysis of protein complexes were performed as described (31, 32)
with slight modifications. HeLa cells were grown on 10-cm dishes
(2.5 × 106/dish), rinsed in PBS, and incubated at
room temperature for 30 min with a 0.5 mM concentration of
the membrane-permeant cross-linker dithiobis(succinimidyl propionate)
(Pierce, Sankt Augustin, Germany). Excess cross-linker was quenched
with 0.2 M glycine. After additional rinsing in PBS, cells
were lysed in RIPA buffer (50 mM Tris, pH 7.2, 1% (v/v)
Triton X-100, 0.25% desoxycholate, 1 mM EGTA, 150 mM NaCl, 20 mM glycine, 2.5 mM
sodium azide, 1 µM pepstatin A, 80 µM
Pefabloc SC, 0.46 µM aprotinin; 30 min at 4 °C).
Cellular material was then scraped off the dish with a rubber
policeman, homogenized by pipetting, and centrifuged at 15,000 × g at 4 °C for 10 min. 2 µl of mc-a-SMN was added to the
supernatant, and the samples were incubated for 16 h at 4 °C.
Then 50 µl of a 50% slurry of protein G-Sepharose preblocked with
2% (w/v) BSA in RIPA buffer was added to the samples, which were then
incubated further under stirring at 4 °C for 1 h. The Sepharose
beads were collected by centrifugation and washed twice in RIPA buffer
and once with PBS before the samples were boiled in SDS sample buffer containing 20% (v/v) Immunohistochemistry--
For immunofluorescence, cryosections
and cells were fixed with methanol at SMN and Profilins Interact in the Yeast Two-hybrid System--
To
test for a direct interaction between SMN and PFN we employed the yeast
two-hybrid system. Appropriate vectors comprising cDNA fragments
encoding mouse PFN I and II and human SMN (Fig. 1A), SMN Interaction of SMN and Profilin in Mammalian Cells--
To
corroborate the results obtained in the yeast two-hybrid system we
performed coimmunoprecipitations with HeLa cell extracts. Cells were
treated with the membrane-permeant cross-linker dithiobis(succinimidyl propionate) before lysis, in order to stabilize protein complexes within the living cells (31, 32). The complexes were immunoprecipitated with mc-a-SMN and protein G-Sepharose and processed for SDS-PAGE and
immunoblotting. As shown in Fig. 2, the
precipitates contained both proteins, SMN and profilin, indicating that
SMN and profilin form complexes under the competitive conditions in the
cytosol of cells.
SMN and Profilins Interact in Vitro--
To characterize further
the interaction between SMN and profilin we performed solid phase
binding assays on membranes. In vitro translated,
radioactively labeled SMN and mouse profilins, a recombinant fusion
protein (MBP-SMN) comprising SMN and the MBP of E. coli as a
fusion partner, and recombinant mouse profilins were used in this
assay. As shown in Fig. 3A,
in vitro translated SMN bound to immobilized MBP-SMN but not
to MBP alone. Recombinant PFN II bound strongly to immobilized MBP-SMN,
whereas the interaction with mouse PFN I was rather weak. In the
converse experiment, in vitro translated SMN also bound
strongly to immobilized PFN II but weakly to PFN I. The significance of
the SMN polyproline stretches for this interaction was tested in
competition experiments. The addition of peptides consisting of 50-60
proline residues (poly-Pro) inhibited the complex formation between
membrane-adsorbed MBP-SMN and in vitro translated PFN II. As
seen in Fig. 3B, a 25-fold molar excess of poly-Pro over SMN
virtually abolished the interaction.
Lastly, affinity precipitation with Sepharose-coupled proteins was
performed. PFN II covalently coupled to Sepharose beads was incubated
with in vitro translated
[35S]methionine-labeled SMN. Bound and free SMN were
separated by centrifugation and detected by SDS-gel electrophoresis and
autoradiography. As shown in Fig. 3C, Sepharose-coupled
recombinant PFN II bound SMN, whereas control BSA-Sepharose did not.
Again, SMN/PFN II binding was sensitive to the presence of poly-Pro: a
5-fold molar excess over SMN completely abolished the interaction.
However, in contrast to the results obtained with the yeast two-hybrid system, in vitro translated SMN
The data from the yeast two-hybrid experiments and the in
vitro data allow the conclusion that SMN binds PFN II stronger
than PFN I. Because mouse PFN II is characteristic for central nervous system tissue (26) we examined the expression of the mRNAs for both
profilin isoforms and SMN in the spinal cord.
PFNs I and II mRNAs Are Highly Expressed in the Spinal
Cord--
To analyze the expression pattern of PFNs in the spinal
cord, the organ affected in SMA, in situ hybridizations were
performed using mouse PFN I- and PFN II-specific riboprobes (Fig.
4). PFN I mRNA was present in a
variety of cell types, including motoneurons and interneurons of the
gray as well as in astrocytes of the white matter, whereas PFN II
mRNA expression was restricted to motoneurons in the anterior horn
and some interneurons. Hence, motoneurons appeared especially rich in
the mRNA of both PFN isoforms.
Colocalization of PFNs and SMN--
On the protein level, the
distribution of profilins and SMN was analyzed by immunohistochemistry
(Fig. 5). HeLa cells were stained for PFN
and SMN as examples of non-neuronal cells, using a monoclonal antibody
specific for PFN I (mc-a-PFN I, Fig. 5, A-C). A similar
distribution, diffuse in the cytoplasm and concentrated in nuclear
gems, was observed for PFN I and SMN. Whereas this distribution is well
known for SMN (5), the localization of PFN in gems, i.e.
nuclear dots that come in pairs or in quadruplets, is a novel finding.
Not all cells contained gems in their nuclei, but all gems inspected
were positive for both proteins, SMN and PFN I. We further analyzed
mouse spinal cord because the spinal cord is the central nervous system
region affected in SMA patients. Spinal cord sections were stained with
a variety of anti-profilin antibodies, in single as well as in
double-labeled experiments, in combination with anti-SMN. Examples are
shown in Fig. 5, D-I. High levels of PFN were seen in large
anterior horn neurons using both monoclonal (Fig. 5, D-F)
and polyclonal anti-PFNs (Fig. 5, G-I).
In the many of these neurons, profilins were seen to colocalize with
SMN in gems, and, like SMN, they were also distributed diffusely in the
cytoplasm of the cell bodies (Fig. 5).
Again, wherever gems were seen on spinal cord sections, they were
labeled for both SMN and PFN. Similar observations were made (data not
shown) on a motoneuron-derived mouse cell line, NSC-19 (35).
In this study we show that SMN and profilins are capable of
forming complexes under a variety of experimental conditions, including
coimmunoprecipitation, the yeast two-hybrid system, and in
vitro assays. We demonstrate that this interaction is mediated by
the polyproline stretch in SMN and the corresponding polyproline binding site in profilins. Our data expand the previously known functional domain structure of SMN by a profilin-binding site, which
comprises the polyproline stretches in the COOH-terminal half of SMN.
Within the region of the SMN sequence delineated by amino acid residues
244-248 (the COOH-terminal Pro5 motif), there is an
overlap between the domains responsible for complex formation with the
spliceosomal protein SmB (amino acids 240-267), the oligomerization
domain in exon 6, and the profilin interaction domain. This suggests
that profilin binding may regulate the interactions with these proteins.
Although the SMN Our cytochemical studies indicate that large neurons are particularly
rich in profilins. As we have shown both on the mRNA and on the
protein level, PFN II is expressed predominantly in motoneurons that
are the primary targets for neurodegeneration in SMA patients, whereas
PFN I is expressed in many different cell types. In all cells and
tissues examined, profilins were found diffusely distributed in the
cytoplasm and diffusely or as dot-like structures or gems in the
nucleus. The same distribution was observed for the SMN protein in HeLa
cells, in mouse spinal cord (this work and Ref. 38), in neuroblastoma
(38), in a motoneuron-like mouse cell line (this work), and in spinal
cord tissue biopsies from human fetuses (3). A role of SMN in gem formation is suggested by the correlation of gem number in explanted fibroblasts with the severity of SMA symptoms in patients (4). Furthermore, SIP-1, a small protein that is involved in snRNP biogenesis, interacts with SMN and is also localized in gems, suggesting that SMN, SIP-1, and profilins are components of the same
complex. In this context, it is noteworthy that coprecipitation of an
unidentified 15-kDa polypeptide from HeLa cell lysates with either SMN
or SIP-1 antibodies has been reported previously (6). We suspect this
polypeptide to be profilin.
The identification of profilins as components of a physiologically
important nuclear structure defines these proteins as members of a
growing list of microfilament-associated proteins located in the
cytoplasmic and in the nuclear compartment, with discrete functions in
both locations. Such proteins comprise It has been shown that SMN is essential for mRNA splicing (8).
However, the etiology of the chromosome 5q spinal muscular atrophies,
in particular its neuron-specific primary pathology, is not yet
understood. The correlation between self-association of SMN protein (3,
8) and the severity of the disease strongly suggests that
oligomerization of SMN is necessary for SMN's function, at least in
motoneurons. Oligomerization and cytoplasmic/nuclear transport of SMN,
in turn, might be modulated by profilins, especially by neuronal PFN II.
Thus our results are suggestive for the understanding of how a defect
in the ubiquitous protein SMN would cause neurodegeneration while
leaving other cell types unaffected (the wasting of skeletal muscle is
a secondary consequence of neurodegeneration). Following this argument,
PFN II might be considered as a possible target of mutations causing
SMA. Genetic knockout or other manipulations of the profilin II gene of
mice should provide further insights into the role of PFN II in
neuronal survival.
We thank Drs. J. Melki (Illkirch) and S. Lefebvre (Paris) for kindly providing the SMN and SMN *
This work was supported in part by the Volkswagen
Foundation, by the Deutsche Forschungsgemeinschaft, and by the Fonds
der chemischen Industrie.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
¶
To whom correspondence should be addressed. Fax:
49-521-106-5654; E-mail: h.jockusch@biologie.uni-bielefeld.de.
2
W. Witke, personal communication.
3
B. M. Jockusch, unpublished data.
The abbreviations used are:
SMA(s), spinal
muscular atrophy(ies);
SMN, survival motoneuron;
PFN, profilin;
sn, small nuclear;
SIP, SMN-interacting protein;
MBP, maltose-binding
protein;
PAGE, polyacrylamide gel electrophoresis;
PBS, phosphate-buffered saline;
BSA, bovine serum albumin;
poly-Pro, peptides consisting of 50-60 proline residues.
A Role for Polyproline Motifs in the Spinal Muscular Atrophy
Protein SMN
PROFILINS BIND TO AND COLOCALIZE WITH SMN IN NUCLEAR GEMS*
,,,, and Department of Cell Biology, Zoological
Institute, Technical University of Braunschweig, D-38092 Braunschweig,
Germany, and the § Department of Developmental Biology and
Molecular Pathology, W7, University of Bielefeld,
D-33501 Bielefeld, Germany
ABSTRACT
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DISCUSSION
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-motoneurons in the
spinal cord followed by atrophy of skeletal muscles. SMA-determining candidate genes, SMN1 and SMN2, have been
identified on human chromosome 5q. The corresponding SMN protein is
expressed ubiquitously. It is coded by seven exons and contains
conspicuous proline-rich motifs in its COOH-terminal third (exons 4, 5, and 6). Such motifs are known to bind to profilins (PFNs), small
proteins engaged in the control of actin dynamics. We tested whether
profilins interact with SMN via its polyproline stretches. Using the
yeast two-hybrid system we show that profilins bind to SMN and that this binding depends on its proline-rich motifs. These results were
confirmed by coimmunoprecipitation and by in vitro binding studies. Two PFN isoforms, I and II, are known, of which II is characteristic for central nervous system tissue. We show by in situ hybridization that both PFNs are highly expressed in mouse spinal cord and that PFN II is expressed predominantly in neurons. In
motoneurons, the primary target of neurodegeneration in SMA, profilins
are highly concentrated and colocalize with SMN in the cytoplasm of the
cell body and in nuclear gems. Likewise, SMN and PFN I colocalize in
gems of HeLa cells. Although SMN interacts with both profilin isoforms,
binding of PFN II was stronger than of PFN I in all assays employed.
Because the SMN genes are expressed ubiquitously, our findings suggest
that the interaction of PFN II with SMN may be involved in
neuron-specific effects of SMN mutations.
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DISCUSSION
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7 truncated variant that
is probably not capable of exerting all biological functions of SMN.
This explains why the telomeric SMN1 gene is indispensable
for normal survival of motoneurons in humans (4). Pathogenic mutations involve deletions, frameshift and missense mutations in exons 5, 6, and
7 of SMN1 as well as the conversion of SMN1 to
SMN2 which drastically reduces exon 7 expression (2,
10-14).
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7 (gift of Dr. Judith Melki, Illkirch), and mouse profilins
I and II (gift of Dr. Walter Witke, Monterotondo, Italy) were subcloned
into the yeast expression plasmids pGBT9 in-frame to the GAL4 DNA
binding domain and into pGAD424 in-frame to the GAL4 activating domain,
respectively. Deletion fragments SMN-N (encoding amino acids
1-188), SMN-C (encoding 188-294), and SMN7-C (encoding
188-278) were inserted into the vectors pGBT9 and pGAD424 using
synthetic oligodeoxynucleotides as linkers. For all constructs, the
correct reading frames were confirmed by sequencing. The preparation of
all media and reagents and all manipulations of the yeast strains HF7c
and SFY as well as the 
-galactosidase filter assay were performed
according to the Matchmaker protocol (CLONTECH, Heidelberg).
7 and mouse
PFN II were cloned into the vector pcDNA3 (Invitrogen, Groningen).
The [35S]methionine-labeled proteins were synthesized by
in vitro transcription/translation using the TNT-coupled
reticulocyte lysate system (Promega, Heidelberg) according to the
manufacturer's protocol. The maltose-binding protein-SMN fusion
protein (MBP-SMN) was expressed in the pMal-c2 bacterial expression
system (New England Biolabs, Schwalbach/Ts, FRG) in Escherichia
coli strain DH5' and purified using amylose affinity
chromatography according to the manufacturer's manual. The elution
fractions were analyzed by SDS-PAGE and immunoblot (a-MBP antibody, New
England Biolabs) and concentrated using Ultrafree-4 centrifugation
tubes (Millipore, Eschborn, FRG). For the expression of recombinant
mouse PFN II the T7 RNA polymerase expression system (28) was used. The
E. coli strain BL21(DE3) pLysS was transformed with the
expression plasmid pMW172/PFN II, containing the coding region of mouse
PFN II. The expressed protein was purified by poly-(L-proline) affinity chromatography as described
previously (29). Eluted fractions were pooled and dialyzed against 10 mM Tris/HCl, pH 7.6, 2 mM CaCl2,
1.25 mM dithiothreitol. The purity of the protein
preparations was better than 95%, as judged by Coomassie Blue-stained
SDS-gel profiles.
-mercaptoethanol. The membrane was incubated in this solution at 4 °C overnight. After intensive washing with PBS
containing 0.1% (v/v) Triton X-100, bound proteins were detected by autoradiography.
-actinin domain with bovine PFN I, which reacts
specifically with PFN I of many mammalian species, but not with rodents
(30), designated mc-a-PFN I; and a monoclonal IgG raised against
recombinant mouse PFN II, 5C6, here designated mc-a-PFN II. For
pc-a-PFN (Alexis) the specificity was verified on Western blots of
extracts from cultured cells and tissues including mouse spinal cord;
only a ~15-kDa band was stained. Monoclonal antibody 2H11 has been
described extensively (30). mc-a-PFN II was tested for its isoform
specificity by enzyme-linked immunosorbent assay and Western blotting
on extracts of E. coli expressing recombinant PFN I and PFN
II, respectively, and stained a band of ~15 kDa band only in the
presence of PFN II.
-mercaptoethanol, to cleave the cross-linker. Finally, samples were analyzed by SDS-PAGE and immunoblotting, using
standard procedures. For control precipitations, we used the monoclonal
antibody 4A6, which does not react with any vertebrate protein but
specifically recognizes an epitope present exclusively in profilins of
birch-related plants (33, 34).
20 °C for 6 min. Monoclonal
antibodies were used as undiluted tissue culture supernatants. Goat
anti-mouse IgG, conjugated with Cy3 (red, Dianova, Hamburg) served as a
second antibody. For double staining, Fab fragments of Cy2-conjugated (green) goat anti-mouse IgG (Dianova) were used to saturate the anti-SMN before incubation with mc-a-PFN II and Cy3-conjugated goat
anti-mouse IgG. Fluorescent images were photographed on a Zeiss
Axiophot fluorescence microscope. Color slides were scanned and images
processed using Adobe Photoshop (version 5.0).
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7, NH2-
and COOH-terminal deletion fragments of SMN, and a COOH-terminal
deletion fragment of SMN7 were generated (Fig. 1B).
SMN-N, encoding amino acids 1-188, and SMN-C, encoding amino acids
188-294, were obtained by cleavage at the NcoI site at base
pair 565 within the coding region of the SMN gene. The COOH-terminal
deletion fragment contained the proline-rich region with the
P5, P10, P5 motifs. The results of
the yeast two-hybrid screens are shown in Table
I. SMN protein interacted strongly with
itself (5, 9), with PFN II, and less well with PFN I. SMN-SMN
interactions were shown to be mediated by the COOH-terminal third of
SMN. These findings correspond to the location of the recently
determined oligomerization domain of SMN, a 30-amino acid region
between residues 249 and 278 (9; Fig. 1A). The same fragment, which contains 54% proline residues between amino acids 190 and 294, was found to be responsible for PFN binding. SMN7 and
SMN7-C did not interact with any of the partners (Table I).
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Fig. 1.
Functional domains in the SMN polypeptide and
constructs used for protein-protein interaction studies.
Panel A, the full-length SMN protein is shown as a
bar with exons separated by vertical lines and
numbered above; black boxes symbolize proline-rich motifs.
Boxes below refer to interaction sites with ligand proteins:
SIP-1 (6); SmB, a protein of the U snRNP complex (6); PFN I and PFN II
(this work); SMN, self-association (9). Panel B, SMN 7
truncated form (natural splice isoform) and deletion fragments used in
the yeast two-hybrid system.
Interactions between SMN and its fragments with profilins I and II in
the yeast two-hybrid system
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Fig. 2.
SMN·PFN complex formation in HeLa cells as
shown by in situ cross-linking and subsequent
coimmunoprecipitation. HeLa cells were treated with the
membrane-permeant cross-linker dithiobis(succinimidyl propionate) (31,
32). SMN and bound proteins were immunoprecipitated (IP)
with mc-a-SMN antibody; mc-a-birch pollen profilin, not reactive with
mammalian profilins (33, 34), served as unspecific control.
Precipitated proteins were detected by immunoblot (IB) with
mc-a-PFN I or mc-a-SMN as indicated. LC, IgG, light
chain.
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Fig. 3.
Interaction of SMN with mouse PFN isoforms
in vitro. Panels A and B, solid phase
overlay assays. Panel A, comparison of SMN binding by PFN I
and II. 100 pmol of MBP and MBP-SMN fusion protein or 500 pmol of
recombinant mouse PFN I and mouse PFN II per spot were immobilized on a
membrane and were incubated with 35S-labeled in
vitro translated proteins in the overlay. Bound protein was
detected by autoradiography. Panel B, effect of
poly-L-proline on the interaction of PFN II with SMN. 100 pmol of MBP-SMN fusion protein per spot was immobilized and incubated
with in vitro translated mouse PFN II in the presence of
increasing concentrations of poly-L-proline
(poly-Pro). Panel C, affinity precipitation of
in vitro translated SMN and SMN 7 with PFN II bound to
beads and effects of poly-L-proline. Translation efficiency
and purity of [35S]methionine-labeled proteins were
checked by PAGE and autoradiography (Total). 120 µg of
mouse PFN II was coupled on 10 µl of NHS-HiTrap material. The
material was incubated with in vitro translated
35S[Met-labeled SMN and SMN7. BSA, negative control.
Poly-Pro, a 5-fold excess of poly-L-proline over coupled
mouse PFN II. Samples of the supernatants (S) and pellets
(P) were separated by SDS-PAGE and blotted.
35S-labeled SMN was detected by autoradiography. Different
positions on the gel are the result of interference with
electrophoretic mobility by salt in supernatants.
7 did bind to
Sepharose-coupled PFN II.
View larger version (177K):
[in a new window]
Fig. 4.
PFN I and II mRNA expression in mouse
spinal cord sections. Panels A and B,
cross-sections of adult mouse cervical spinal cord (dorsal,
up; lateral, left) hybridized with antisense
probes against PFN I (panel A) and PFN II (panel
B), respectively. The border between gray (G in
panel C) and white (W) matter is delineated by
dashed lines, revealing that PFN I is expressed in a variety
of cells in both areas, whereas PFN II expression is predominant in the
neurons within the gray matter. Panel C, a corresponding
section incubated with a PFN II sense probe (negative control).
Panel D, enlarged part of the ventral horn of the section in
panel B, showing hybridization of PFN II probe with a group
of motoneurons. Panel E, parallel section stained with
cresyl violet (Nissl) to show cell bodies of motoneurons.
Bar in panel A, 100 µm for A,
B, and C. Bar in panel D,
50 µm for D and E.
View larger version (114K):
[in a new window]
Fig. 5.
Immunocytochemical localization by
double-staining of PFNs (Cy3, red) and SMN (Cy2,
green). Panels A-C,
cultured HeLa cells; panels D-I, frozen sections from the
ventral region of mouse spinal cord. Panels A, D,
and G, profilin staining with antibodies mc-a-PFN I
(panel A, 2H11; Ref. 30), mc-a-PFN II (panel D,
5C6), and pc-a-PFN (panel G, Alexis). Panels B,
E, and H, SMN staining with mc-a-SMN (2B1; Ref.
5). Panels C, F, and I, double
exposures, to show colocalization (yellow). In all cases,
there is a diffuse staining of the cytoplasm for profilin and SMN. In
the non-neuronal HeLa cells (panels A-C), a
nuclear gem in a quadruplet configuration is indicated by
arrowheads. In panels D-F, a gem in a twin
("gemini") configuration in the nucleus of a motoneuron is
indicated by arrowheads. In panels G-I, gems are
indicated by arrowheads in quadruplet (upper
left) and in twin (lower right) configurations.
Dark area to the lower left is white matter (see
Fig. 4). In all cases, gems are stained for both profilin and SMN
(yellow in panels C, F, and
I). Bars in panel A (valid for
panels A-C) and panel G (valid for
panels D-I), 10 µm.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
7 deletion fragment still contains all identified
binding motifs in the COOH-terminal region of the molecule, i.e. for SmB, SMN, and profilin binding, we found that this
fragment failed to interact with itself as well as with PFN II in the
yeast two-hybrid system. The fact that SMN7-C gave the same negative result might emphasize the importance of exon 7 for these interactions. However, we cannot exclude misfolding or degradation of this short fragment. Liu and Dreyfuss (5), however, mention an interaction between
SMN and two SMN cDNA clones that lack exon 7 in their two-hybrid
experiments. Because this notion is not documented by experimental
data, it is difficult to explain why these results are at variance with
ours. In contrast to our finding in the yeast two-hybrid system,
SMN7 did bind to PFN II in solution, as seen by affinity
precipitation with radioactively labeled proteins and a sensitive
detection system. The discrepancy between the data obtained with the
yeast two-hybrid system and those from in vitro binding
studies may reflect relevant but gradual differences in the ability of
SMN and SMN7 to bind profilin in the competitive environment of the
cytoplasm. Alternatively, it could be caused by a diminished
translation efficiency, aberrant folding, or increased sensitivity to
degradation of SMN7 compared with SMN, which in itself might also be
relevant for the etiology of spinal muscular atrophy. Although a
variety of proline-rich ligands for the corresponding binding site in
profilins has been identified (23), not all proteins with polyproline
stretches interact with profilins. For example, the proline cluster
containing protein CAP (36) does not bind to profilins in
vitro,3 whereas its
isolated polyproline peptide does so (20, 37). Moreover, the difference
in affinity for proline-rich ligands between profilin I and II, as
reported for VASP (20), has also been seen with SMN. These observations
support the notion that the interaction between SMN and PFNs is not an
unspecific consequence of the presence of polyproline stretches in
SMN.
-catenin (39) plakoglobin
(40), vinculin (41), and actin (42). Except for -catenin (43), the
precise role of these proteins in the nucleus has yet to be elucidated.
ACKNOWLEDGEMENTS
7 cDNAs,
Dr. W. Witke for the PFN II cDNA, Dr. G. Dreyfuss (Philadelphia)
for a generous gift of the monoclonal antibody against SMN, Dr. U. Fischer (München) for helpful discussions, and Angela Perz
(Bielefeld) for excellent technical assistance.
FOOTNOTES
ABBREVIATIONS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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C. Andreassi, J. Jarecki, J. Zhou, D. D. Coovert, U. R. Monani, X. Chen, M. Whitney, B. Pollok, M. Zhang, E. Androphy, et al. Aclarubicin treatment restores SMN levels to cells derived from type I spinal muscular atrophy patients Hum. Mol. Genet., November 1, 2001; 10(24): 2841 - 2849. [Abstract] [Full Text] [PDF]
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J. Lu and T. D. Pollard Profilin Binding to Poly-L-Proline and Actin Monomers along with Ability to Catalyze Actin Nucleotide Exchange Is Required for Viability of Fission Yeast Mol. Biol. Cell, April 1, 2001; 12(4): 1161 - 1175. [Abstract] [Full Text]
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W. Witke, J. D. Sutherland, A. Sharpe, M. Arai, and D. J. Kwiatkowski Profilin I is essential for cell survival and cell division in early mouse development PNAS, March 7, 2001; (2001) 51515498. [Abstract] [Full Text]
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S. Jablonka, M. Bandilla, S. Wiese, D. Buhler, B. Wirth, M. Sendtner, and U. Fischer Co-regulation of survival of motor neuron (SMN) protein and its interactor SIP1 during development and in spinal muscular atrophy Hum. Mol. Genet., March 1, 2001; 10(5): 497 - 505. [Abstract] [Full Text] [PDF]
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M. D. Hebert and A. G. Matera Self-association of Coilin Reveals a Common Theme in Nuclear Body Localization Mol. Biol. Cell, December 1, 2000; 11(12): 4159 - 4171. [Abstract] [Full Text]
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 A. Lambrechts, A. Braun, V. Jonckheere, A. Aszodi, L. M. Lanier, J. Robbens, I. Van Colen, J. Vandekerckhove, R. Fässler, and C. Ampe Profilin II Is Alternatively Spliced, Resulting in Profilin Isoforms That Are Differentially Expressed and Have Distinct Biochemical Properties Mol. Cell. Biol., November 1, 2000; 20(21): 8209 - 8219. [Abstract] [Full Text]
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U. R. Monani, D. D. Coovert, and A. H.M. Burghes Animal models of spinal muscular atrophy Hum. Mol. Genet., October 1, 2000; 9(16): 2451 - 2457. [Abstract] [Full Text] [PDF]
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 J. Janke, K. Schluter, B. Jandrig, M. Theile, K. Kolble, W. Arnold, E. Grinstein, A. Schwartz, L. Estevez-Schwarz, P. M. Schlag, et al. Suppression of Tumorigenicity in Breast Cancer Cells by the Microfilament Protein Profilin 1 J. Exp. Med., May 8, 2000; 191(10): 1675 - 1686. [Abstract] [Full Text] [PDF]
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A Di Nardo, R Gareus, D Kwiatkowski, and W Witke Alternative splicing of the mouse profilin II gene generates functionally different profilin isoforms J. Cell Sci., January 11, 2000; 113(21): 3795 - 3803. [Abstract] [PDF]
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N. Kurihara, C. Menaa, H. Maeda, D. J. Haile, and S. V. Reddy Osteoclast-stimulating Factor Interacts with the Spinal Muscular Atrophy Gene Product to Stimulate Osteoclast Formation J. Biol. Chem., October 26, 2001; 276(44): 41035 - 41039. [Abstract] [Full Text] [PDF]
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J. Wang and G. Dreyfuss Characterization of Functional Domains of the SMN Protein in Vivo J. Biol. Chem., November 21, 2001; 276(48): 45387 - 45393. [Abstract] [Full Text] [PDF]
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P. J. Young, P. M. Day, J. Zhou, E. J. Androphy, G. E. Morris, and C. L. Lorson A Direct Interaction between the Survival Motor Neuron Protein and p53 and Its Relationship to Spinal Muscular Atrophy J. Biol. Chem., January 18, 2002; 277(4): 2852 - 2859. [Abstract] [Full Text] [PDF]
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W. Witke, J. D. Sutherland, A. Sharpe, M. Arai, and D. J. Kwiatkowski Profilin I is essential for cell survival and cell division in early mouse development PNAS, March 27, 2001; 98(7): 3832 - 3836. [Abstract] [Full Text] [PDF]
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