Center for Neuronal Survival, Montreal
Neurological Institute, McGill University, Montreal, Quebec H3A 2B4,
Canada,1 and Cell Biology Program,
Memorial Sloan-Kettering Cancer Center, New York, New York
100212
Received 18 October 2000/Returned for modification 12 December
2000/Accepted 19 December 2000
Brain factor 1 (BF-1) is a winged-helix transcriptional repressor
that plays important roles in both progenitor cell differentiation and
regional patterning in the mammalian telencephalon. The aim of this
study was to elucidate the molecular mechanisms underlying BF-1
functions. It is shown here that BF-1 interacts in vivo with global
transcriptional corepressors of the Groucho family and also associates
with the histone deacetylase 1 protein. The ability of BF-1 to mediate
transcriptional repression is promoted by Groucho and inhibited by the
histone deacetylase inhibitor trichostatin A, suggesting that BF-1
recruits Groucho and histone deacetylase activities to repress
transcription. Our studies also provide the first demonstration that
Groucho mediates a specific interaction between BF-1 and the basic
helix-loop-helix protein Hes1 and that BF-1 potentiates transcriptional
repression by Hes1 in a Groucho-dependent manner. These findings
suggest that Groucho participates in the transcriptional functions of
BF-1 by acting as both a corepressor and an adapter between BF-1 and
Hes1. Taken together with the demonstration that these proteins are
coexpressed in telencephalic neural progenitor cells, these results
also suggest that complexes of BF-1, Groucho, and Hes factors may be
involved in the regulation of progenitor cell differentiation in the telencephalon.
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INTRODUCTION |
In the vertebrate central nervous
system (CNS), differentiated neuronal and glial cells derive from
proliferating progenitors located in the ventricular zone of the neural
tube. The mechanisms that regulate the commitment of these progenitor
cells to the neuronal fate are under the control of either positive or
negative regulators. Proteins that promote neuronal differentiation
include a family of related DNA-binding proteins containing
the basic helix-loop-helix (bHLH) motif. These factors, generally
referred to as the proneural proteins (reviewed in reference
31), are transcriptional activators that promote the
expression of genes that contribute to the regulatory cascade of events
leading to the formation of postmitotic neurons (15, 20, 33, 36, 37).
Negative regulators of neuronal differentiation comprise a number of
structurally distinct proteins that act together to antagonize the
activities of the proneural proteins. Important members of this
functional class include components of the Notch signaling pathway,
like the transmembrane receptor Notch, extracellular ligands of Notch,
and intracellular factors that mediate responses to Notch activation
(reviewed in references 3 and 52). Notable among the
latter are the bHLH DNA-binding proteins of the Hairy/Enhancer of split
(Hes) family (1, 14, 26, 27, 39, 40) and the
transcriptional corepressors of the Groucho/transducin-like Enhancer of
split (TLE) family (11, 18, 32, 47, 55). Hes and
Groucho/TLE proteins are thought to form transcription repression
complexes that inhibit proneural gene activity in response to Notch
activation (18, 23, 28, 40, 41). Within these complexes,
Hes proteins provide a specific DNA-binding function while Groucho/TLEs
provide a transcription repression function.
In contrast to the progress made in understanding the mechanisms that
regulate neuronal determination, relatively little is known about the
events that control the establishment of the correct temporal and
spatial patterns of neuronal differentiation along the anteroposterior
axis of the CNS. Recently, the discovery of a number of genes that are
expressed in restricted patterns within the neural tube has provided
ways to begin to investigate the mechanisms controlling regional
differentiation in the CNS. In this regard, the winged-helix
transcription factor brain factor 1 (BF-1) (48) (recently
renamed Foxg1 [30]) was identified as a protein whose
expression in the developing murine brain is restricted to the
telencephalon and the nasal half of the retina and optic stalk. In
these tissues, BF-1 is expressed in both mitotic neural
progenitor cells and postmitotic neurons (22, 48). A
closely related protein, termed BF-2, is expressed in the immediately adjacent region, the rostral diencephalon (22). Targeted
disruption of BF-1 function by homologous recombination
causes hypoplasia of the cerebral hemispheres in mouse embryos. This
phenotype appears to be caused by the premature differentiation of
neural progenitor cells, resulting in an early depletion of the
progenitor cell population (24, 53). The forebrain of
BF-1
/ embryos also displays dorsoventral
patterning defects, suggesting that BF-1 may be involved in the
regulation of both progenitor cell differentiation and local patterning
events (53). A role for BF-1 in regulating the transition
of progenitor cells to postmitotic neurons in the forebrain is also
suggested by the analysis of the Xenopus BF-1 homolog,
XBF-1. Like its murine counterpart, XBF-1 is specifically expressed in
precursor cells of anterior neural structures (5). Ectopic
expression of high levels of XBF-1 in posterior neural plate cells
inhibits neuronal differentiation (5), in agreement with
the notion that BF-1 proteins may represent anterior-specific factors
involved in the regulation of neuronal differentiation.
Although little is presently known about the molecular mechanisms
underlying BF-1 function, transient transfection studies have shown
that BF-1 proteins can mediate transcriptional repression (7,
35). In this regard, several observations have raised the
possibility that the repression functions of BF-1 may involve interactions with general transcriptional corepressors of the Groucho/TLE family. First, BF-1 and TLE genes are
coexpressed in neural progenitor cells of the mammalian telencephalon
(11, 53-55), and at least one TLE family member, TLE1, is
involved in the regulation of forebrain development in vivo
(55). Second, TLE proteins interact with other factors
containing the winged-helix motif, like hepatic nuclear factor 3
(51). Third, studies of Xenopus embryos have
shown that the phenotypes caused by ectopic expression of full-length
XBF-1 can be phenocopied by fusion proteins of the DNA-binding domain
of XBF-1 and the repression domain of the Engrailed protein
(5). Similarly, the embryonic phenotypes caused by ectopic
expression of the related Xenopus protein, XBF-2, can be
phenocopied by fusion proteins of the XBF-2 DNA-binding domain and the
repressor domain of either Engrailed or Hairy (38). These
chimeric proteins are likely to function in association with
Groucho/TLE proteins, since both the Engrailed and Hairy repression
domains were shown to mediate interactions with Groucho/TLEs (14,
29, 43, 50). Taken together, these observations suggest that the
recruitment of Groucho/TLE corepressors may be a mechanism normally
utilized by BF-1 to repress transcription.
Here we describe experiments designed to test the possible involvement
of TLE proteins in the transcriptional functions of murine BF-1. Our
results are consistent with a model in which BF-1 recruits TLEs and
histone deacetylases to repress transcription. Moreover, TLEs may act
as adapters between BF-1 and the Hes family member Hes1. These findings
suggest that BF-1, Hes1, and TLE proteins may form transcription
repression complexes that may coordinate the regulation of cell cycle
progression and cell differentiation during the development of the
mammalian forebrain.
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MATERIALS AND METHODS |
Plasmids.
The following is a summary of the names and
origins of the constructs used in these studies. Additional information
on cloning strategies and oligonucleotide primers used in PCR
experiments is available upon request. Vent DNA polymerase was used,
and PCR products were routinely sequenced before subcloning into the
appropriate vectors. For expression of glutathione
S-transferase (GST) fusion proteins in bacteria, the
constructs pGEX2-TLE1(1-135) (Gln-rich region [Q domain] of TLE1),
pGEX1-TLE1(290- 461) (Ser/Pro-rich region [SP domain] of TLE1),
pGEX3-TLE3(490-774) (tandem WD40 repeat [WDR] domain of TLE3), and
pGEX1-Hes1(3-281) (the entire Hes1 sequence except for the first two
amino acids) were generated as described previously (18, 19,
39). pGEX3-BF-1 was obtained by first using site-directed
mutagenesis to create a PvuII site at the 5' end of the
BF-1 coding sequence. This was followed by cloning a
PvuII fragment into the blunted BamHI site of
pGEX-3X. For expression of GST fusion proteins in mammalian cells,
plasmid pEBG-Hes1(3-281) was obtained as described previously
(39), while construct pEBG-Hes1(
276-281) (truncated
Hes1 lacking the last six amino acids, WRPWRN) was obtained by
subcloning the appropriate PCR product into the filled-in
BamHI site of pEBG. pEBG-TLE1(1-770) (full-length TLE1) was
generated by subcloning the entire TLE1 coding region into the
filled-in BamHI site of pEBG. pEBG-Engrailed1 (full-length
Engrailed1) was generated by subcloning a filled-in BamHI
fragment into the filled-in BamHI site of pEBG.
For in vitro translation reactions, plasmid pglob-BF-1(1-481)
(full-length BF-1) was generated by digestion with PvuII and
XhoI, followed by ligation to the pT7glob
vector, containing the -globin gene 5' untranslated sequence.
Plasmid pglob-BF-1(1-336) was obtained by digesting
pglob-BF-1(1-481) with HincII, while construct
pglob-BF-1(120-481) was generated using BAL 31 nuclease; subsequent
restriction digestion of this plasmid with SfiI generated
construct pglob-BF-1(120-275). Plasmid pcDNA3-GAL4bd-BF-1(241-336)
(fusion protein of the DNA-binding domain of GAL4 [GAL4bd] and amino
acids 241 to 336 of BF-1) was obtained by digesting the BF-1
cDNA with XmaI (followed by filling in with T4 DNA
polymerase) and HincII and subcloning into the EcoRV site of pcDNA3-GAL4bd (18, 19). The
expression vector pCMV2-FLAG-BF-1(1-481) was generated by subcloning a
PvuII/XhoI fragment of the BF-1 cDNA
into the EagI and SalI sites of pCMV2-FLAG. Constructs pCMV2-FLAG-Hes1(1-281), pCMV2-FLAG-Hes1(276-281)
(39), pcDNA3-TLE1(1-770) (19), p6B-CMV-Luc
(luciferase gene under the control of the cytomegalovirus [CMV]
promoter linked to six BF-1 binding sites) (35) and
p6N-Act-Luc (luciferase gene under the control of the -actin
promoter linked to six Hes1 binding sites) (44) have been
described previously. The histone deacetylase 1 (HDAC1) expression
plasmid pT7-HA-HDAC1 was kindly provided by X. J. Yang (McGill University).
Interaction assays in transfected cells and Western blotting
analysis.
Human 293 or rat ROS17/2.8 cells were grown and
transfected using the SuperFect reagent (Qiagen) as described
previously (39). Coprecipitation assays using plasmids
pEBG-TLE1(1-770), pEBG-Hes1(3-281), pEBG-Hes1(276-281),
pEBG-Engrailed1 (or pEBG as control), and pCMV2-FLAG-BF-1(1-481) and
immunoprecipitation experiments with anti-FLAG (Sigma) or
anti-hemagglutinin (HA) (Boehringer) epitope antibodies were performed
as described previously (25, 39). Polyclonal antibodies
against BF-1 were obtained by immunizing rabbits with the peptide
CTHQNQGSSSNPLIH, containing the last 14 amino acids of BF-1
and an amino-terminal Cys residue to permit linking to keyhole limpet
hemocyanin. Antibodies were purified from serum by 40% ammonium
sulfate precipitation, followed by affinity purification on a BF-1
peptide-Sepharose column. Western blotting studies were performed as
described elsewhere (18, 25, 39, 42) with antibodies
against BF-1, TLE1 (25, 54, 55), GST (Santa Cruz
Biotechnology), FLAG epitope, or HDAC1 (Santa Cruz Biotechnology) or
with pan-TLE monoclonal antibodies (42, 47). Rabbit
polyclonal antibodies against Hes1 were kindly provided by J. Feder
(Bristol-Myers Squibb) and used for Western blotting as described
previously (6, 8).
Coimmunoprecipitation of BF-1 and TLE from mouse embryonic
telencephalon.
The telencephalon from embryonic day 15 mouse
embryos was dissected as described elsewhere (17, 46).
Tissue was rinsed in ice-cold Hanks' balanced salt solution, followed
by homogenization and whole-cell lysis (25). Lysates were
subjected to immunoprecipitation with either anti-TLE1 serum or
preimmune serum as described previously (25), and
immunoprecipitated material was analyzed by sodium dodec
l
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and Western
blotting with anti-BF-1 and pan-TLE antibodies.
Primary cultures of telencephalic neural progenitor cells.
Neural progenitor cell cultures were obtained from telencephalic
cortices dissected from embryonic day 12.5 mouse embryos exactly as
described previously (17, 46). Cell lysates were prepared
after 24 h in vitro when ~90% of the cultured cells were mitotic (as indicated by bromodeoxyuridine incorporation studies [reference 46 and data not shown]).
In vitro fusion protein interaction assays.
Incubations of
in vitro-translated proteins and bacterially purified GST fusion
proteins were performed as described elsewhere (18, 39).
Transcription assays.
ROS17/2.8 or 293 cells were
transfected using the SuperFect reagent as described previously
(39). The amount of DNA transfected was adjusted using
plasmid pcDNA3 so that the total amount of DNA used in each
transfection was the same (3.0 µg). Transcription studies were
performed with 500 ng of reporter plasmid p6B-CMV-Luc or
p6N-Act-Luc. Effector plasmids included pCMV2-FLAG-BF-1(1-481) (10 ng), pcDNA3-TLE1(1-770) (400 ng), pCMV2-FLAG-Hes1(1-281) (25 ng), and
pCMV2-FLAG-Hes1(276-281) (25 ng). In each case, 250 ng of
pCMV--galactosidase plasmid DNA was cotransfected to provide a means
of normalizing the assays for transfection efficiency. Results were
expressed as mean value ± standard deviation (SD) and were tested
for statistical significance by the one-tailed Student's t
test for paired differences.
EMSA.
The oligonucleotide probes used in electrophoretic
mobility shift assays (EMSAs) contained either two Hes1 binding sites
(N box [44]) (top strand,
5'-CTAGACGCCACGAGCCACAAGGATTG-3'; bottom strand, 5'-CTAGCAATCCTTGTGGCTCGTGGCGT-3') or one BF-1
binding site (B2 probe [(35)]) (top strand,
5'-TCGAGCTCCAATGTAAACAGAGCAG-3'; bottom strand,
5'-CTGCCTGCTCTGTTTACATTGGAGC-3') (binding sites are
italicized). Probes were labeled at both ends by filling in with
Klenow DNA polymerase in the presence of [
-32P]dCTP.
EMSA-s were performed as described elsewhere (45), using BF-1 prepared by in vitro translation.
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RESULTS |
In vivo interaction between BF-1 and TLE proteins.
Previous
studies have implicated vertebrate BF-1 family members in
transcriptional repression (5, 35). The biological effects
of full-length BF-1 can be phenocopied with fusion proteins of the BF-1
DNA-binding domain and the Engrailed transcription repression domain
(5). The Engrailed repressor domain mediates interactions
with Groucho/TLE proteins (29, 50), suggesting that BF-1
may act as a transcriptional repressor together with Groucho/TLEs. This
possibility is consistent with the previous demonstration that mouse
BF-1 is coexpressed with TLE genes in neural
progenitor cells of the telencephalon (11, 48, 53-55). To
begin to determine whether TLE proteins might act as corepressors with
BF-1, we examined whether these molecules could interact in vivo. Mouse
embryos were collected 15 days postcoitum; the telencephalon was
dissected, followed by homogenization, preparation of a whole-cell
lysate, and immunoprecipitation with previously described (25,
54, 55) anti-TLE1 antibodies. Western blotting analysis
showed that TLE proteins were immunoprecipitated by these antibodies (Fig. 1A, lane 2) but not by
preimmune serum (Fig. 1A, lane 3). More importantly, BF-1 was
coimmunoprecipitated by the anti-TLE1 antibodies (Fig. 1B, lane 2) but
not by preimmune serum (Fig. 1B, lane 3). These findings show that BF-1
interacts with TLE proteins in vivo.
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FIG. 1.
Interaction of BF-1 and TLE proteins in vivo. Mouse
embryonic telencephalon was dissected and homogenized; a whole-cell
lysate prepared and used for immunoprecipitation (IP) with either
anti-TLE1 rabbit serum (lane 2) or preimmune rabbit serum (lane 3).
Immunoprecipitated material was subjected to SDS-PAGE on a 7% gel
together with 1/10 of the input lysate (lane 1), followed by Western
blotting (WB) with either rat pan-TLE monoclonal antibodies (A) or
rabbit anti-BF-1 polyclonal antibodies (B). (A) The secondary
antibodies used to detect the rat pan-TLE antibodies cross-react weakly
with the rabbit immunoglobulin G heavy chain (IgG HC). Here and in
succeeding figures, positions of size standards are indicated in
kilodaltons
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An interaction between BF-1 and TLE was also observed when
protein-protein interaction assays were performed with transfected human embryonic kidney 293 cells. Cells were cotransfected with expression plasmids for mouse BF-1 and a fusion protein of GST and
full-length TLE1 (a plasmid expressing GST alone was used as control).
Twenty-four hours later, cells were homogenized and the GST proteins
were isolated on glutathione-Sepharose beads. Western blotting analysis
of the fractions bound to the beads using anti-BF-1 antibodies showed
that BF-1 coprecipitated with GST-TLE1 (Fig.
2A, lane 2) but not with GST (Fig. 2A,
lane 4), indicative of an interaction between BF-1 and TLE1. Both GST
and GST-TLE1 were stable and expressed at equivalent levels (Fig. 2B).
Coimmunoprecipitation assays were performed next. Cells were transfected with GST-TLE1, with or without a FLAG epitope-tagged BF-1
protein (FLAG-BF-1). Cell homogenates were subjected to
immunoprecipitation with anti-FLAG antibodies, and the
immunoprecipitated proteins were tested for the presence of TLE1
immunoreactivity by Western blotting with anti-TLE1 antibodies.
GST-TLE1 was immunoprecipitated when cells were cotransfected with
FLAG-BF-1 (Fig. 2C, lane 1) but not when they were cotransfected with
the empty FLAG expression plasmid (Fig. 2C, lane 2) or when
immunoprecipitations were performed with irrelevant monoclonal
antibodies (not shown). Endogenous TLE1 as well as previously described
proteolytic fragments thereof (25) (Fig. 2C, lane 1) were
also immunoprecipitated. Reprobing with anti-FLAG antibodies confirmed
that FLAG-BF-1 coimmunoprecipitated with TLE1 (Fig. 2D, lane 1).
Together, these results demonstrate that BF-1 interacts with TLE
proteins.
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FIG. 2.
Interaction of BF-1 and TLE1 in mammalian cells. (A and
B) Transfection-coprecipitation assays. Human 293 cells were
cotransfected with plasmids encoding full-length BF-1 (lanes 1 to 4)
and either a fusion protein of GST and full-length TLE1 (lanes 1 and 2)
or GST alone (lanes 3 and 4). Cell homogenates were collected and
incubated with glutathione-Sepharose beads. The material that remained
bound to the beads after extensive washing was subjected to SDS-PAGE
(lanes 2 and 4). One-tenth of each input homogenate collected prior to
incubation with glutathione-Sepharose beads was also subjected to gel
electrophoresis (lanes 1 and 3). After transfer to nitrocellulose,
Western blotting (WB) was performed sequentially with either anti-BF-1
(A) or anti-GST (B) antibodies. (C and D) Coimmunoprecipitation
studies. 293 cells were cotransfected with plasmids encoding the
indicated combinations of proteins and peptides. Cell homogenates were
subjected to immunoprecipitation (IP) with anti-FLAG epitope
antibodies, and the material that was bound to the beads after
extensive washing was subjected to SDS-PAGE, transfer to
nitrocellulose, and Western blotting with anti-TLE1 antibodies (C) and
then with anti-FLAG antibodies (D). (C) GST-TLE1 coimmunoprecipitates
with FLAG-BF-1 (lane 1, closed arrow); endogenous TLE1 proteins (lane
1, arrowhead) and previously described proteolytic products thereof
(25) (lane 1, open arrow) also coimmunoprecipitate with
FLAG-BF-1. (D) After incubation with the anti-TLE1 antibodies, the
nitrocellulose was not stripped before incubation with the anti-FLAG
antibodies so that the same bands visible in panel C are still visible
in panel D. The large arrow points to the position of migration of
FLAG-BF-1 (lane 1). The immunoglobulin G heavy chain is indicated (IgG
HC).
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Next, we asked whether BF-1 and TLE proteins could interact directly
and, if so, which respective domains mediate their association. In
vitro protein-protein interaction assays were performed using fusion
proteins of GST and individual TLE domains purified from bacteria (Fig.
3) and full-length BF-1 [BF-1(1-481)]
prepared by in vitro translation. BF-1(1-481) bound to the
carboxy-terminal WDR domain of TLE (Fig. 4A, lane 4). A weaker
interaction with the amino-terminal Q domain of TLE1 was also observed
(Fig. 4A, lane 2). A truncated form of
BF-1 lacking the last 145 amino acids [BF-1(1-336)] retained the
ability to interact with these two domains (Fig. 4B, lanes 2 and 4).
Similarly, deletion of the first 119 amino acids did not abolish
binding of BF-1 to TLE (Fig. 4C). Longer exposures revealed that
removal of this amino-terminal region was correlated with a weak
interaction of BF-1(120-481) with the SP domain of TLE1 (partly
visible in Fig. 4C, lane 3), although the significance of this
observation remains to be determined. Contrary to BF-1(120-481), a
truncated BF-1 form containing a further carboxy-terminal deletion,
BF-1(120-275), was unable to interact with either TLE domain (Fig.
4D). These combined observations suggest that amino acids 276 to 336 of
BF-1 are involved in TLE binding. In agreement with this possibility, a
fusion protein of BF-1(241-336) and GAL4bd was competent to interact
with the WDR domain of TLE (Fig. 4E, lane 4). A much weaker interaction with the Q domain was also observed (Fig. 4E, lane 2). GAL4bd does not
interact with any of these TLE domains (18, 19). Taken
together, these results demonstrate that BF-1 interacts with TLEs and
that, barring the presence of a bridging protein in the rabbit
reticulocyte lysate, this interaction is direct.
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FIG. 3.
Expression of individual TLE domains in bacterial cells.
(A) Schematic representation of the domain structure of TLE proteins
and truncated derivatives thereof (47). The amino terminus
of all Groucho/TLE proteins contains a Q domain that mediates
protein-protein interactions and transcriptional repression, followed
by a GP domain, an internal region involved in nuclear localization
(CcN domain), and an SP domain involved in transcriptional repression.
The carboxy-terminal half of Groucho/TLE proteins is highly conserved
and contains a WDR domain that mediates protein-protein interactions.
Also shown are deletion derivatives of TLE1 and TLE3 used in this
study, named according to the residues contained in each protein. (B)
Analysis of individual GST-TLE fusion proteins by SDS-PAGE. Roughly
equivalent amounts of GST-TLE1(1-135) (lane 2), GST-TLE1(290-461)
(lane 3), GST-TLE3(490-774) (lane 4), or GST (lane 5) were visualized
by staining with Coomassie blue.
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FIG. 4.
Interaction of BF-1 with separate TLE domains.
Shown on the left are schematic representations of the in
vitro-translated 35S-labeled BF-1 proteins used in these
assays. The hatched box indicates the location of the winged-helix
domain (WHD). Lane 1 of each corresponding SDS-PAGE gel shown on the
right was loaded with 40% of the amount of in vitro-translated protein
used in the binding assays (Input). Lanes 2 to 5 show the products of
the pull-down experiments performed in the presence of ~1.0 µg of
the indicated fusion proteins. (E) Amino acids 241 to 336 of BF-1 were
expressed as a fusion protein with GAL4bd. The material that was
recovered on glutathione-Sepharose beads was subjected to SDS-PAGE and
autoradiography. Gels were loaded leaving empty lanes between
individual samples, except between lanes 2 and 3 in panel A.
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Functional interaction between BF-1 and TLE proteins.
To
determine whether BF-1 and TLE proteins could functionally interact, we
asked whether the latter might be involved in the transcriptional
functions of BF-1. Previous studies have shown that Groucho/TLEs are
global transcriptional corepressors that can act as adapters between
DNA-binding proteins and histone deacetylases (2, 9, 10, 14, 18,
34, 39). We therefore examined the effects of TLE proteins on
BF-1-mediated repression by first testing whether overexpressing TLE1
would potentiate repression by BF-1. Rat ROS17/2.8 cells, which contain
endogenous TLE proteins (39), were transfected with a
previously described (35) reporter construct containing
the luciferase gene under the control of a CMV promoter linked to six
tandem copies of a BF-1 binding site. Transfection of this reporter
plasmid (p6B-CMV-Luc) alone resulted in basal expression of the
luciferase gene (Fig. 5, lane 1).
Cotransfection of a BF-1 expression plasmid led to a repression of
basal transcription (Fig. 5, lane 3). Importantly, cotransfection of a
TLE1 expression plasmid resulted in a significant potentiation of the
repressive effect of BF-1 (Fig. 5, cf. lanes 3 and 5). Neither BF-1 nor
TLE1 repressed basal transcription from the CMV promoter alone (Fig. 5,
lanes 7-9). These results are consistent with the direct interaction between TLE and BF-1 proteins demonstrated above and suggest that TLE
proteins may promote BF-1-mediated transcriptional repression.
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FIG. 5.
Effect of TLE and histone deacetylase activities on
transcriptional repression by BF-1. ROS17/2.8 cells were transfected
with the reporter construct p6B-CMV-Luc (500 ng; lanes 1 to 6) and the
indicated expression vectors in the absence (lanes 1, 3, and 5) or
presence (lanes 2, 4, and 6) of TSA (400 nM). Expression vectors used
were pCMV2-FLAG-BF-1 (10 ng per transfection; lanes 3 to 6) and
pcDNA3-TLE1 (400 ng; lanes 5 and 6). The basal activity of the reporter
construct in the absence of BF-1 was considered 100%. Luciferase
activities were expressed as the mean ± SD of at least four
independent experiments performed in duplicate. BF-1 mediates
transcriptional repression (lane 3; *, P = 0.00011),
and this effect is enhanced by TLE1 (lane 5; *, P = 0.00923) and relieved by TSA (lanes 4 and 6). Neither BF-1 (lane
8) nor TLE1 (lane 9) had a repressive effect on a control reporter
(pCMV-Luc; 500 ng) containing the CMV promoter but no BF-1 binding
sites.
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Next, we asked whether transcriptional repression by BF-1 was reduced
in the presence of the histone deacetylase inhibitor trichostatin A
(TSA) (49). TSA treatment had no significant effect on the
activity of the CMV promoter (Fig. 5, cf. lanes 1 and 2) but reduced
the repressive activity of BF-1 (Fig. 5, cf. lanes 3 and 4), suggesting
that histone deacetylases are involved in repression by BF-1. The
inhibitory effect of TSA on BF-1 was partly alleviated by
overexpression of TLE1 (Fig. 5, cf. lanes 4 and 6). This observation is
in agreement with the suggestion that Groucho/TLEs may be able to
mediate transcriptional repression also independently of histone
deacetylases (9).
Based on the effect of TSA on repression by BF-1, we tested further
whether BF-1 might associate with histone deacetylases in cultured
cells. We focused on HDAC1, which has been shown previously to interact
with Groucho/TLE proteins (10). 293 cells were transfected with BF-1, with or without a HA epitope-tagged HDAC1 protein (Fig. 6A).
Immunoprecipitation experiments with anti-HA antibodies showed that
both BF-1 (Fig. 6B, lane 1) and
endogenous TLEs (Fig. 6C, lane 1) were coimmunoprecipitated with HDAC1
(Fig. 6D, lane 1), indicating that these proteins can interact with
each other in vivo. To determine whether BF-1 might interact with HDAC1
directly, in vitro-translated HDAC1 was incubated with bacterially
purified GST-BF-1 proteins. Isolation of GST-BF-1 did not result in a
coisolation of HDAC1 (Fig. 6E). We also failed to detect an interaction
between BF-1 and HDAC1 in far-Western blotting studies (data not
shown). Taken together, these results suggest that BF-1 can recruit
complexes containing TLE and HDAC1 proteins to repress transcription.
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FIG. 6.
Interaction of BF-1 and HDAC1 in transfected cells. (A
to D) 293 cells were cotransfected with plasmids encoding full-length
BF-1 (lanes 1 and 2) and either HA epitope-tagged HDAC1 (lane 1) or
empty pCMV2-HA vector (lane 2). (A) Cell homogenates were subjected to
Western blotting (WB) analysis with anti-BF-1 antibodies. (B to D) Cell
homogenates were subjected to immunoprecipitation (IP) with anti-HA
epitope antibodies, and the material that was bound to the beads after
extensive washing was subjected to SDS-PAGE, transfer to
nitrocellulose, and Western blotting (WB) with anti-BF-1 antibodies
(B), pan-TLE antibodies (C), or anti-HDAC1 antibodies (D). (E) In vitro
pull-down assays. In vitro-translated 35S-labeled HDAC1
(lane 1; 15% of the amount used in each reaction) was incubated in the
presence of ~2.0 µg of either GST alone (lane 2) or GST-BF-1 (lane
3). The material that was recovered on glutathione-Sepharose beads was
subjected to SDS-PAGE and autoradiography. No specific binding of HDAC1
to GST-BF-1 was observed, even after prolonged autoradiography.
|
|
Association of BF-1 and Hes1.
Our present and previous
(18, 40) findings show that TLE proteins can interact with
both BF-1 and Hes1. Moreover, TLE, BF-1, and Hes1 are coexpressed in
telencephalic neural progenitor cell cultures (Fig.
7). We therefore asked whether, due to
their shared ability to interact with TLEs, BF-1 and Hes1 might form a
complex. Since we were unable to immunoprecipitate Hes1 from telencephalic neural progenitor cells with either anti-TLE or anti-Hes1
antibodies (data not shown), protein-protein interaction assays were
performed with transfected cells. ROS17/2.8 cells were cotransfected
with BF-1 and either GST, a fusion protein of GST and Hes1
[GST-Hes1(3-281)], or a fusion protein of GST and a truncated form
of Hes1 [GST-Hes1(276- 281)] that lacked the last six amino
acids, WRPWRN, necessary for TLE binding (14, 40) (Fig.
8A). After affinity isolation of the GST
proteins, Western blotting analysis showed that BF-1 coisolated with
GST-Hes1(3-281) (Fig. 8B, lane 2) but not with GST-Hes1(276- 281)
(Fig. 8B, lane 4) or GST (Fig. 8B, lane 6). Similarly, endogenous TLE
proteins coprecipitated with Hes1(3-281) (Fig. 8C, lane 2) but not
with Hes1(276-281) (Fig. 8C, lane 4). BF-1 and Hes1 did not
interact directly with each other in in vitro protein-protein
interaction assays in which GST-Hes1 was isolated from bacteria (which
do not express TLEs) and BF-1 was prepared by in vitro translation using a reticulocyte system devoid of TLEs (39) (Fig. 8D).
Under the same conditions, GST-Hes1 interacted with in vitro-translated TLE proteins (Fig. 8E). In agreement with previous studies
(18), the TLE-Hes1 interaction was relatively weak in
vitro compared to similar assays in transfected cells (cf. Fig. 8C and
E). These results suggest that BF-1 and Hes1 can associate in mammalian cells and that their interaction is not direct but mediated by TLE
proteins.
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FIG. 7.
Expression of BF-1, TLE, and Hes1 in telencephalic
neural progenitor cells. The telencephalon was dissected from embryonic
day 12.5 mouse embryos, and primary cultures of cortical progenitor
cells were established as described elsewhere (46). After
24 h in vitro, whole-cell lysates were prepared and subjected to
Western blotting analysis with antibodies against TLE (A), BF-1 (B), or
Hes1 (C).
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|
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FIG. 8.
Interaction of BF-1 and Hes1 in mammalian cells. (A to
C) Transfection-coprecipitation assays. ROS17/2.8 cells were
cotransfected with plasmids encoding full-length BF-1 (lanes 1 to 6)
and either a fusion protein of GST and full-length Hes1
[GST-Hes1(3-281); lanes 1 and 2], a fusion protein of GST and
Hes1(276-281) (lanes 3 and 4), or GST alone (lanes 5 and 6). Cell
homogenates were collected and incubated with glutathione-Sepharose
beads. The material that remained bound to the beads after extensive
washing was subjected to SDS-PAGE (lanes 2, 4, and 6). One-twentieth of
each input homogenate collected prior to incubation with
glutathione-Sepharose beads was also subjected to gel electrophoresis
(lanes 1, 3, and 5). After transfer to nitrocellulose, Western blotting
was performed with either anti-GST (A), anti-BF-1 (B), or pan-TLE
monoclonal (C) antibodies. (D and E) In vitro pull-down assays. In
vitro-translated 35S-labeled BF-1 (lane 1 in panel D; 40%
of the amount used in each reaction) or TLE1 (lane 1 in panel E; 20%
of the amount used in each reaction) was incubated in the presence of
~1.0 µg of either GST-Hes1(3-281) (lane 2) or GST alone (lane 3).
The material that was recovered on glutathione-Sepharose beads was
subjected to SDS-PAGE and autoradiography. No specific binding of BF-1
to GST-Hes1 was observed, even after prolonged autoradiography.
|
|
To determine the specificity of the BF-1-Hes1 interaction, we tested
whether other proteins known to interact with TLE family members might
also associate with BF-1. Similar protein-protein interaction studies
were performed by cotransfecting cells with BF-1 and either a fusion
protein of GST and Engrailed1 or GST alone (Fig. 9C). Endogenous TLE
proteins were coprecipitated with GST-Engrailed1 (Fig. 9A, lane 3) but
not with GST (Fig. 9A, lane 4). In contrast, BF-1 did not associate
with GST-Engrailed1 (Fig. 9B, lane 3).
The lack of an association between Engrailed and BF-1 suggests further
that the BF-1-Hes1 interaction is specific.
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FIG. 9.
Interaction of Engrailed1 with TLEs but not BF-1. (A and
B) ROS17/2.8 cells were cotransfected with plasmids encoding
full-length BF-1 (lanes 1 to 4) and either a fusion protein of GST and
Engrailed1 (lanes 1 and 3) or GST alone (lanes 2 and 4). Cell
homogenates were collected and incubated with glutathione-Sepharose
beads. The material that remained bound to the beads after extensive
washing was subjected to SDS-PAGE (lanes 3 and 4). One-twentieth of
each input homogenate collected prior to incubation with
glutathione-Sepharose beads was also subjected to gel electrophoresis
(lanes 1 and 2). After transfer to nitrocellulose, Western blotting
(WB) was performed with either pan-TLE monoclonal (A) or anti-BF-1 (B)
antibodies. (C) GST-Engrailed1 (lane 1) and GST (lane 2) proteins
isolated on glutathione-Sepharose beads.
|
|
Potentiation of Hes1-mediated transcriptional repression by
BF-1.
To examine the interaction of BF-1 and Hes1 further, we next
tested whether BF-1 could modulate the transcription repression function of Hes1. 293 cells were transfected with the previously described (44) p6N-Act-Luc reporter construct,
containing the luciferase gene under the control of a basally active
-actin promoter linked to six tandem copies of a Hes1 binding site.
Cotransfection of limited amounts of full-length Hes1 resulted in a
partial repression of basal transcription (Fig.
10A, cf. lanes 1 and 2). Importantly, the repressor activity of Hes1 was significantly enhanced by BF-1 (Fig.
10A, lane 3), while BF-1 had no effect on reporter gene expression in
the absence of Hes1 (Fig. 10A, lane 6). In contrast, equal amounts of
Hes1(276-281) did not mediate transcriptional repression (Fig. 10A,
lane 4), in agreement with the notion that removal of the TLE-binding
domain impairs the ability of Hes proteins to repress transcription
(40). The presence of BF-1 did not promote repression by
Hes1(276-281) (Fig. 10A, lane 5), consistent with the finding that
BF-1 and Hes1(276-281) do not associate with each other in
transfected cells. These results show that BF-1 can potentiate the
ability of Hes1 to mediate transcriptional repression and that this
effect is dependent on the presence of the TLE-binding domain of Hes1.
The six tandem N boxes present in the p6N-Act-Luc reporter construct
do not contain any sequence resembling the consensus BF-1 binding site
(35), suggesting that the potentiating effect of BF-1 on
Hes1 was not due to a direct binding of BF-1 to the reporter construct.
To confirm this possibility, EMSAs were performed using previously
described oligonucleotide probes containing either one copy of the BF-1
binding site (BF-1 probe [35]) or two tandem copies of
the N-box (Hes1 probe [44]). As previously described
(35), the electrophoretic mobility of the BF-1 probe was
retarded in the presence of BF-1 (Fig. 10B, lane 2); this retardation
was not observed when an excess of unlabeled probe was present (Fig.
10B, lane 3). In contrast, no DNA-protein complexes were observed when
the Hes1 probe was incubated in the presence of BF-1 (Fig. 10B, lane
4). Together, these results are consistent with a model in which BF-1
can associate with Hes1 through TLE proteins and participate in
Hes1-mediated repression in the absence of its own DNA-binding sites.
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FIG. 10.
Potentiation of Hes-1-mediated transcriptional
repression by BF-1. (A) Transient transfection-transcription assays.
293 cells were transfected with reporter construct p6N-Act-Luc (500 ng) and expression vectors encoding the indicated proteins. Expression
vectors used were pFLAG-Hes1(1-281) (25 ng), pFLAG-Hes1(276-281)
(25 ng), and pCMV2-FLAG-BF-1 (10 ng). The basal activity of the
reporter constructs in the absence of any cotransfected protein was
considered 100%. Luciferase activities were expressed as the mean ± SD, of at least four independent experiments performed in duplicate.
BF-1 enhances transcriptional repression by Hes1(1-281) (lane 3; *,
P = 0.0049) but has no effect on
Hes1(276-281) (lane 5). (B) EMSAs. BF-1 was prepared by
in vitro translation and incubated in the presence of either the
radiolabeled BF-1 oligonucleotide probe (lane 2), the radiolabeled BF-1
probe plus a 200-fold molar excess of unlabeled BF-1 probe (lane 3), or
the radiolabeled Hes1 probe (lane 4). Lane 1 was loaded with the BF-1
probe alone. The arrow points to the DNA-protein complex that was
observed when BF-1 was incubated with the BF-1 probe alone but not in
the presence of an excess of unlabeled probe.
|
|
| |
DISCUSSION |
Functional interaction between BF-1 and Groucho/TLE
proteins. In an effort to elucidate the molecular mechanisms that underlie the functions of BF-1, we have examined the possibility that
this factor is involved in the regulation of gene expression together
with Groucho/TLE family members. Our studies have provided the first
demonstration that BF-1 and TLE proteins can physically interact with
each other in vivo. Their interaction appears to be direct, since it
was also observed in binding assays using bacterially purified TLE
proteins and in vitro-translated BF-1 preparations. Two separate TLE
domains, the amino-terminal Q domain and the carboxy-terminal WDR
region, are involved in BF-1 binding. This finding is in agreement with
previous investigations showing that these two domains mediate
protein-protein interactions with a number of other factors, including
RUNX (39), NK-3 (10), and UTY
(19) proteins. These observations suggest that the use of
multiple protein-protein interaction domains is a strategy regularly
utilized by Groucho/TLEs, perhaps to achieve a specificity that may not
be provided by each interaction domain alone. Our studies have shown
further that a short region of BF-1, located immediately after the
winged-helix domain, is involved in TLE binding. Interestingly, we have
noticed that this region contains a sequence,
YWPMSPFLSLH, that is conserved among all BF-1
family members (5) and is characterized by two adjacent
aromatic residues followed by the motif PFLSL (underlined). This
arrangement of aromatic residues separated by one or two proline
residues is reminiscent of the bona fide Groucho/TLE-binding motif
WRP(W/Y) found in Hes and RUNX family members. Importantly, a similar
sequence, YAFNHPFSINN, is
present in the CRII region that mediates the interaction of TLEs with
the winged-helix protein hepatic nuclear factor 3 (51).
Thus, it is possible that these short sequences may perform the common
task of mediating the interaction of these winged-helix proteins with TLEs.
The present investigations have also demonstrated that the ability of
BF-1 to mediate transcriptional repression is promoted by TLEs. This
finding is in line with the previous demonstration that Groucho/TLEs
provide a transcriptional corepressor function to other DNA-binding
proteins (2, 10, 14, 18, 34, 40). It is also consistent
with the demonstration that ectopic expression of XBF-1 in developing
Xenopus embryos has effects that can be phenocopied by the
ectopic expression of a fusion protein of BF-1 and the transcription
repression domain of Engrailed (5). Since the Engrailed
repression region was shown to act as a Groucho/TLE-binding domain
(29, 50), those findings also suggest that BF-1 and TLE
proteins repress transcription together. Additional support to this
possibility derives from our present observation that BF-1 can
potentiate transcription repression mechanisms that require TLE
function. More specifically, BF-1 enhances repression mediated by Hes1
but has no effect on a truncated form of Hes1 that lacks the ability to
interact with TLEs (see below for further discussion). Taken together,
these results are consistent with the notion that BF-1 and TLE proteins
form transcription repression complexes together.
BF-1 also associates with HDAC1 in mammalian cells. This interaction is
not direct and may be mediated by TLE proteins, which can bind to both
BF-1 and HDAC1. Importantly, BF-1-mediated transcriptional repression
is reduced by an inhibitor of histone deacetylase activities. Thus, we
propose that BF-1 can recruit TLEs and histone deacetylases to repress
transcription, a possibility consistent with previous studies showing
that histone deacetylases are involved in transcriptional repression mediated by Groucho/TLE proteins (9, 10). It
remains to be determined, however, whether the recruitment of
histone deacetylase activity represents the general mechanism
normally utilized by BF-1 to repress transcription or whether other
mechanisms may also be utilized. For instance, it will be important to
determine whether Groucho/TLE proteins are always involved in
repression by BF-1 or whether the latter can also repress transcription
independently of the former. Moreover, Groucho/TLEs may contribute to
BF-1 mediated repression in ways that may not always involve the
recruitment of histone deacetylases.
Interaction of BF-1 and Hes1 proteins through TLE
corepressors.
Our studies have also provided the first evidence of
an interaction between BF-1 and Hes1. These proteins can associate with each other in transfected cells, and their interaction is dependent on
the ability of Hes1 to bind to TLEs, suggesting that the latter act as
adapters between BF-1 and Hes1. This association appears to be specific
because other proteins that bind to TLEs, like Engrailed, do not
associate with BF-1 in the presence of TLEs. These findings suggest
that in addition to acting as transcriptional corepressors, TLE
proteins may contribute to the transcriptional functions of BF-1 by
acting as adapters between BF-1 and Hes1. The modular structure of
Groucho/TLEs, particularly the presence of tandem WD40 repeats capable
of providing multiple protein-protein interaction surfaces, appears to
be suited to this task. Our studies have shown further that BF-1
enhances the ability of Hes1 to repress transcription in transfected
cells. This function appears to be mediated by TLEs, because BF-1 does
not promote the transcription repression function of a
carboxy-terminally truncated Hes1 protein that lacks the WRPW motif
required for TLE binding. Interestingly, the potentiating effect of
BF-1 on Hes1-mediated repression does not require binding of BF-1 to
DNA, because it can occur even in the absence of BF-1 binding sites.
Taken together, these observations suggest that complexes of BF-1, TLE,
and Hes1 proteins may be involved in the regulation of overlapping sets
of genes. This possibility is consistent with the results of separate
lines of studies that have recently implicated both BF-1 and Hes1 in
the regulation of the expression of cell cycle inhibitors of the
Cip/Kip family (6, 21), although the involvement of the
WRPW motif of Hes1 in these events remains to be determined.
Implications for the function of BF-1 during telencephalon
development.
Previous studies have shown that BF-1 is an important
regulator of the progenitor-to-neuron transition in the mammalian
telencephalon. In the absence of BF-1, telencephalic
progenitor cells differentiate prematurely, leading to early depletion
of the progenitor population (53). These findings suggest
that BF-1 promotes cell proliferation and/or inhibits cell
differentiation in the telencephalon. BF-1 does not appear to have a
direct growth-promoting activity, however, since disruption of
BF-1 function in BF-1/ mice has a
demonstrable effect on the proliferation of neuroepithelial cells only
after embryonic day 10.5, even though BF-1 is expressed in
these cells at earlier stages (53). It is possible that
BF-1 may act as a regulator of the activities of growth-regulatory signals. Support to this hypothesis derives from the finding that the
loss of BF-1 leads to ectopic expression of BMP4
in the telencephalic neuroepithelium (13, 53). This
observation suggests that BF-1 may, at least in part, facilitate
proliferation by inhibiting BMP4 expression, since BMP4 was
shown to inhibit telencephalic progenitor cell proliferation
(16). In addition, recent studies in Xenopus
have suggested that XBF-1 may be a direct regulator of the
p27Xic1 gene, the amphibian counterpart of the
mammalian cell cycle inhibitor p27Kip1
(21).
Based on our present demonstration that BF-1 forms transcription
repression complexes with TLE and Hes1 proteins, we propose that BF-1
may control telencephalon development by coordinating the control of
cell proliferation with the timing of differentiation in the
neuroepithelium. In both invertebrates and vertebrates, Hes and
Groucho/TLE proteins act as negative regulators of neuronal differentiation by preventing progenitor cells from differentiating prematurely (12, 23, 26-28, 41). The finding that BF-1
interacts with and enhances the transcription repression activity of
Hes1 suggests that BF-1 may contribute to the regulation of the timing of neuronal differentiation together with Hes1 and TLE proteins. This
possibility is consistent with the demonstration that
Hes1/ mice display a forebrain phenotype
very similar to that of BF-1/ mice, namely,
premature differentiation of precursor cells with consequent depletion
of the progenitor cell population (27). In the future, it
will be important to determine whether BF-1 is involved in the
regulation of the expression of genes that are thought to be targets of
the transcriptional inhibitory functions of Hes proteins, like the
proneural gene Mash1 (8, 27).
A functional interaction between BF-1 and Hes1 may also help explain
the results of studies of Xenopus embryos showing that ectopic expression of high doses of XBF-1 causes suppression
of neuronal differentiation in the injected area in a cell autonomous way (5). It is conceivable that the BF-1-Hes1 interaction
may be favored in cells expressing high doses of BF-1. As a result, the
inhibitory function of Hes1 during neuronal differentiation may be
promoted due to the potentiation of its transcription repression activity, leading to suppression of neuronal differentiation within the
areas of high BF-1 expression. It remains to be determined, however,
whether a similar situation may occur at lower BF-1
concentrations. Studies in Xenopus showed that
microinjection of low doses of XBF-1 does not cause
suppression of neuronal differentiation but instead leads to the
formation of supernumerary neurons within the injected area
(5). This observation suggests that at low concentrations,
BF-1 may not be able to enhance Hes1 activity but may still be able to
suppress the growth-inhibitory function of p27Kip1 and/or
other antiproliferation factors. This would lead to increased proliferation without an antineurogenic effect, eventually resulting in
supernumerary neurons when the progenitor cells differentiate. These
observations suggest that changes in BF-1 protein levels may have
important repercussions during the progenitor-to-neuron transition and
underscore the importance of the mechanisms that regulate
BF-1 expression and function.
In summary, we propose that Groucho/TLE proteins are involved in BF-1
activity both by providing a corepressor function and by acting as
adapters between BF-1 and Hes proteins. The establishment of
transcription complexes containing BF-1 and Hes proteins may provide a
way to integrate the functions of these factors, thereby coordinating
the decision of precursor cells to exit the cell cycle and initiate the
neuronal differentiation program.
We thank R. Lo for invaluable help during these studies, K. McLarren and D. Grbavec for assistance, F. Miller and J. Toma for help
during the culture of cortical progenitor cells, J. Feder and M. Caudy
for providing anti-Hes1 antibodies, X.-J. Yang for advice and for
providing the HDAC1 expression plasmid, and G. Karpati for providing
access to a luminometer.
This work was supported by Medical Research Council of Canada grant
GR-14971 to S.S. and by NIH RO1 grants HD29584 and EY11124 to E.L.
S.S. is a Scholar of the Fonds de la Recherche en Sante du Quebec and a
Killam Scholar of the Montreal Neurological Institute.
| 1.
|
Akazawa, C.,
Y. Sasai,
S. Nakanishi, and R. Kageyama.
1992.
Molecular characterization of a rat negative regulator with a basic helix-loop-helix structure predominantly expressed in the developing nervous system.
J. Biol. Chem.
267:21879-21885.
|
| 2.
|
Aronson, B. D.,
A. L. Fisher,
K. Blechman,
M. Caudy, and J. P. Gergen.
1997.
Groucho-dependent and -independent repression activities of Runt domain proteins.
Mol. Cell. Biol.
17:5581-5587.
|
| 3.
|
Artavanis-Tsakonas, S.,
M. D. Rand, and R. J. Lake.
1999.
Notch signaling: cell fate control and signal integration in development.
Science
284:770-776.
|
| 4.
|
Bae, S.,
Y. Bessho,
M. Hojo, and R. Kageyama.
2000.
The bHLH gene Hes6, an inhibitor of Hes1, promotes neuronal differentiation.
Development
127:2933-2943.
|
| 5.
|
Bourguignon, C.,
J. Li, and N. Papalopulu.
1998.
XBF-1, a winged helix transcription factor with dual activity, has a role in positioning neurogenesis in Xenopus competent ectoderm.
Development
125:4889-4900.
|
| 6.
|
Castella, P.,
S. Sawai,
K. Nakao,
J. A. Wagner, and M. Caudy.
2000.
HES-1 repression of differentiation and proliferation in PC12 cells: role for the helix 3-helix 4 domain in transcription repression.
Mol. Cell. Biol.
20:6170-6183.
|
| 7.
|
Chang, H. W.,
J. Li,
D. Kretzschmar, and P. K. Vogt.
1995.
Avian cellular homolog of the qin oncogene.
Proc. Natl. Acad. Sci. USA
92:447-451.
|
| 8.
|
Chen, H.,
A. Thiagalindam,
H. Chopra,
M. W. Borges,
J. N. Feder,
B. D. Nelkin,
S. B. Baylin, and D. G. Ball.
1997.
Conservation of the Drosophila lateral inhibition pathway in human lung cancer: a hairy-related protein (HES-1) directly represses achaete-scute homolog-1 expression.
Proc. Natl. Acad. Sci. USA
94:5355-5360.
|
| 9.
|
Chen, G.,
J. Fernandez,
S. Mische, and A. J. Courey.
1999.
A functional interaction between the histone deacetylase rpd3 and the corepressor Groucho in Drosophila development.
Genes Dev.
13:2218-2230.
|
| 10.
|
Choi, C. Y.,
Y. H. Kim,
H. J. Kwon, and Y. Kim.
1999.
The homeodomain protein NK-3 recruits Groucho and a histone deacetylase complex to repress transcription.
J. Biol. Chem.
274:33194-33197.
|
| 11.
|
Dehni, G.,
Y. Liu,
J. Husain, and S. Stifani.
1995.
TLE expression correlates with mouse embryonic segmentation, neurogenesis, and epithelial determination.
Mech. Dev.
53:369-381.
|
| 12.
|
Delidakis, C.,
A. Preiss,
D. A. Hartley, and S. Artavanis-Tsakonas.
1991.
Two genetically and molecularly distinct functions involved in early neurogenesis reside within the Enhancer of split locus of Drosophila melanogaster.
Genetics
129:803-823.
|
| 13.
|
Dou, C. L.,
S. Li, and E. Lai.
1999.
Dual role of brain factor 1 in regulating growth and patterning of the cerebral hemispheres.
Cereb. Cortex
9:543-550.
|
| 14.
|
Fisher, A. L.,
S. Ohsako, and M. Caudy.
1996.
The WRPW motif of the Hairy-related basic helix-loop-helix repressor proteins acts as a four-amino-acid transcription repression and protein-protein interaction domain.
Mol. Cell. Biol.
16:2670-2677.
|
| 15.
|
Fode, C.,
G. Gradwohl,
X. Morin,
A. Dierich,
M. Le Meur,
C. Goridis, and F. Guillemot.
1998.
The bHLH protein NEUROGENIN2 is a determination factor for epibranchial placode-derived sensory neurons.
Neuron
20:483-494.
|
| 16.
|
Furuta, Y.,
D. W. Piston, and B. L. M. Hogan.
1997.
Bone morphogenetic proteins (BMPs) as regulators of dorsal forebrain development.
Development
124:2203-2212.
|
| 17.
|
Ghosh, A., and M. E. Greenberg.
1995.
Distinct roles for bFGF and NT-3 in the regulation of cortical neurogenesis.
Neuron
15:89-103.
|
| 18.
|
Grbavec, D.,
R. Lo,
Y. Liu, and S. Stifani.
1998.
Transducin-like Enhancer of split 2, a mammalian homologue of Drosophila Groucho, acts as a transcriptional repressor, interacts with Hairy/Enhancer of split proteins, and is expressed during neuronal development.
Eur. J. Biochem.
258:339-349.
|
| 19.
|
Grbavec, D.,
R. Lo,
Y. Liu,
A. Greenfield, and S. Stifani.
1999.
Groucho/transducin-like Enhancer of split (TLE) family members interact with the yeast transcriptional co-repressor SSN6 and mammalian SSN6-related proteins: implications for evolutionary conservation of transcription repression mechanisms.
Biochem. J.
337:13-17.
|
| 20.
|
Guillemot, F.,
L. C. Lo,
J. E. Johnson,
A. Auerbach,
D. J. Anderson, and A. L. Joyner.
1993.
Mammalian achaete-scute homolog 1 is required for early development of olfactory and autonomic neurons.
Cell
75:463-476.
|
| 21.
|
Hardcastle, Z., and N. Papalopulu.
2000.
Distinct effects of XBF-1 in regulating the cell cycle inhibitor p27XIC1 and imparting a neural fate.
Development
127:1301-1314.
|
| 22.
|
Hatini, V.,
W. Tao, and E. Lai.
1994.
Expression of winged helix genes, BF-1 and BF-2, define adjacent domains within the developing forebrain and retina.
J. Neurobiol.
25:1293-1309.
|
| 23.
|
Heitzler, P.,
M. Bourouis,
L. Ruel,
C. Carteret, and P. Simpson.
1996.
Genes of the Enhancer of split and achaete-scute complexes are required for a regulatory loop between Notch and Delta during lateral signaling in Drosophila.
Development
122:161-171.
|
| 24.
|
Huh, S.,
V. Hatini,
R. C. Marcus,
S. C. Li, and E. Lai.
1999.
Dorsal-ventral patterning defects in the eye of BF-1-deficient mice associated with a restricted loss of shh expression.
Dev. Biol.
211:53-63.
|
| 25.
|
Husain, J.,
R. Lo,
D. Grbavec, and S. Stifani.
1996.
Affinity for the nuclear compartment and expression during cell differentiation implicate phosphorylated Groucho/TLE1 forms of higher molecular mass in nuclear functions.
Biochem. J.
317:523-531.
|
| 26.
|
Ishibashi, M.,
K. Moriyoshi,
Y. Sasai,
K. Shiota,
S. Nakanishi, and R. Kageyama.
1994.
Persistent expression of helix-loop-helix factor HES-1 prevents mammalian neural differentiation in the central nervous system.
EMBO J.
13:1799-1805.
|
| 27.
|
Ishibashi, M.,
S. L. Ang,
K. Shiota,
S. Nakanishi,
R. Kageyama, and F. Guillemot.
1995.
Targeted disruption of mammalian hairy and Enhancer of split homolog 1 (HES-1) leads to up-regulation of neural helix-loop-helix factors, premature neurogenesis, and severe neural tube defects.
Genes Dev.
9:3136-3148.
|
| 28.
|
Jennings, B.,
A. Preiss,
C. Delidakis, and S. Bray.
1994.
The Notch signaling pathway is required for Enhancer of split bHLH protein expression during neurogenesis in the Drosophila embryo.
Development
120:3537-3548.
|
| 29.
|
Jimenez, G.,
Z. Paroush, and D. Ish-Horowicz.
1997.
Groucho acts as a corepressor for a subset of negative regulators, including Hairy and Engrailed.
Genes Dev.
11:3072-3082.
|
| 30.
|
Kaestner, K.,
W. Knochel, and D. Martinez.
2000.
Unified nomenclature for the winged helix/forkhead transcription factors.
Genes Dev.
14:142-146.
|
| 31.
|
Kageyama, R.,
M. Ishibashi,
K. Takebayashi, and K. Tomita.
1997.
bHLH transcription factors and mammalian neuronal differentiation.
Int. J. Biochem. Cell Biol.
29:1389-1399.
|
| 32.
|
Koop, K. E.,
L. M. MacDonald, and C. G. Lobe.
1996.
Transcripts of Grg4, a murine groucho-related gene, are detected in adjacent tissues to other murine neurogenic gene homologues during embryonic development.
Mech. Dev.
59:73-87.
|
| 33.
|
Lee, J. E.,
S. M. Hollenberg,
L. Snider,
D. L. Turner,
N. Lipnick, and H. Weintraub.
1995.
Conversion of Xenopus ectoderm into neurons by NeuroD, a basic helix-loop-helix protein.
Science
268:836-844.
|
| 34.
|
Levanon, D.,
R. E. Goldstein,
Y. Bernstein,
H. Tang,
D. Goldenberg,
S. Stifani,
Z. Paroush, and Y. Groner.
1998.
Transcriptional repression by AML1 and LEF-1 is mediated by the TLE/Groucho corepressors.
Proc. Natl. Acad. Sci. USA
95:11590-11595.
|
| 35.
|
Li, J.,
H. W. Chang,
E. Lai,
E. Parker, and P. K. Vogt.
1995.
The oncogene Qin codes for a transcriptional repressor.
Cancer Res.
55:5540-5544.
|
| 36.
|
Ma, Q.,
C. Kintner, and D. J. Anderson.
1996.
Identification of neurogenin, a vertebrate neuronal determination gene.
Cell
87:43-52.
|
| 37.
|
Ma, Q.,
Z. Chen,
I. del Barco Barrantes,
J. L. de la Pompa, and D. J. Anderson.
1998.
neurogenin1 is essential for the determination of neuronal precursors for proximal cranial sensory ganglia.
Neuron
20:469-482.
|
| 38.
|
Mariani, F. V., and R. M. Harland.
1998.
XBF-2 is a transcriptional repressor that converts ectoderm into neural tissue.
Development
125:5019-5031.
|
| 39.
|
McLarren, K. W.,
R. Lo,
D. Grbavec,
K. Thirunavukkarasu,
G. Karsenty, and S. Stifani.
2000.
The mammalian basic helix loop helix protein HES-1 binds to and modulates the transactivating function of the Runt-related factor Cbfa1.
J. Biol. Chem.
275:530-538.
|
| 40.
|
McLarren, K. W.,
F. Theriault, and S. Stifani.
2001.
Association with the nuclear matrix and interaction with Groucho and RUNX proteins regulate the transcription repression ability of the basic helix loop helix factor Hes1.
J. Biol. Chem.
276:1578-1584.
|
| 41.
|
Ohtsuka, T.,
M. Ishibashi,
G. Gradwohl,
S. Nakanishi,
F. Guillemot, and R. Kageyama.
1999.
Hes1 and Hes5 as Notch effectors in mammalian neuronal differentiation.
EMBO J.
18:2196-2207.
|
| 42.
|
Palaparti, A.,
A. Baratz, and S. Stifani.
1997.
The Groucho/Transducin-like Enhancer of split transcriptional repressors interact with the genetically defined amino-terminal silencing domain of histone H3.
J. Biol. Chem.
272:26604-26610.
|
| 43.
|
Paroush, Z.,
R. L. Finley,
T. Kidd,
S. M. Wainwright,
P. W. Ingham,
R. Brent, and D. Ish-Horowicz.
1994.
Groucho is required for Drosophila neurogeneis, segmentation, and sex determination and interacts directly with hairy-related bHLH proteins.
Cell
79:805-815.
|
| 44.
|
Sasai, Y.,
R. Kageyama,
Y. Tagawa,
R. Shigemoto, and S. Nakanishi.
1992.
Two mammalian helix-loop-helix factors structurally related to Drosophila hairy and Enhancer of split.
Genes Dev.
5:2620-2634.
|
| 45.
|
Shanmugan, K.,
M. S. Featherstone, and H. U. Saragovi.
1997.
Residues flanking the HOX YPWM motif contribute to cooperative interactions with PBX.
J. Biol. Chem.
272:19081-19087.
|
| 46.
|
Slack, R. S.,
H. El-Bizri,
J. Wong,
D. J. Belliveau, and F. D. Miller.
1998.
A critical temporal requirement for the retinoblastoma protein family during neuronal determination.
J. Cell Biol.
140:1497-1509.
|
| 47.
|
Stifani, S.,
C. M. Blaumueller,
N. J. Redhead,
R. E. Hill, and S. Artavanis-Tsakonas.
1992.
Human homologs of a Drosophila Enhancer of split gene product define a novel family of nuclear proteins.
Nat. Genet.
2:119-127.
|
| 48.
|
Tao, W., and E. Lai.
1992.
Telencephalon-restricted expression of BF-1, a new member of the HNF-3/fork head gene family, in the developing rat brain.
Neuron
8:957-966.
|
| 49.
|
Taunton, J.,
C. A. Hassig, and S. L. Schreiber.
1996.
A mammalian histone deacetylase related to the yeast transcriptional regulator Rpd3p.
Science
272:408-411.
|
| 50.
|
Tolkunova, E. N.,
M. Fujioka,
M. Kobayashi,
D. Deka, and J. B. Jaynes.
1998.
Two distinct types of repression domain in Engrailed: one interacts with the Groucho corepressor and is preferentially active on integrated target genes.
Mol. Cell. Biol.
18:2804-2814.
|
| 51.
|
Wang, J. C.,
M. Waltner-Law,
K. Yamada,
H. Osawa,
S. Stifani, and D. K. Granner.
2000.
Transducin-like Enhancer of split proteins, the human homologs of Drosophila Groucho, interact with hepatic nuclear factor 3.
J. Biol. Chem.
275:18418-18423.
|
| 52.
|
Weinmaster, G.
1997.
The ins and outs of Notch signaling.
Mol. Cell. Neurosci.
9:91-102.
|
| 53.
|
Xuan, S.,
C. A. Baptista,
G. Balas,
W. Tao,
V. C. Soares, and E. Lai.
1995.
Winged helix transcription factor BF-1 is essential for the development of the cerebral hemispheres.
Neuron
14:1141-1152.
|
| 54.
|
Yao, J.,
Y. Liu,
J. Husain,
R. Lo,
A. Palaparti,
J. Henderson, and S. Stifani.
1998.
Combinatorial expression patterns of individual TLE proteins during cell determination and differentiation suggest non-redundant functions for mammalian homologs of Drosophila Groucho.
Dev. Growth Differ.
40:133-146.
|
| 55.
|
Yao, J.,
Y. Liu,
R. Lo,
I. Tretjakoff,
A. Peterson, and S. Stifani.
2000.
Disrupted development of the cerebral hemispheres in transgenic mice expressing the mammalian Groucho homologue Transducin-like Enhancer of split 1 in postmitotic neurons.
Mech. Dev.
93:105-115.
|
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Abstract
Introduction
