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Menin Promotes the Wnt Signaling Pathway in PancreaticEndocrine Cells
Gao Chen, Jingbo A, Min Wang, Steven Farley, Lung-Yi Lee, Lung-Ching Lee,and Mark P. Sawicki
David Geffen School of Medicine at University of California at Los Angeles and the GreaterLos Angeles VA Medical Center, Los Angeles, California
AbstractMenin is a tumor suppressor protein mutated in
patients with multiple endocrine neoplasia type 1. We
show that menin is essential for canonical Wnt/B-
catenin signaling in cultured rodent islet tumor cells.
In these cells, overexpression of menin significantly
enhances TCF gene assay reporter activity in response
to B-catenin activation. Contrastingly, inhibition of
menin expression with Men1 siRNA decreases TCF
reporter gene activity. Likewise, multiple endocrine
neoplasia type 1 disease associated missense
mutations of menin abrogate the ability to increase TCF
reporter gene activity. We show that menin physically
interacts with proteins involved in the canonical Wnt
signaling pathway, including B-catenin, TCF3 (TCFL1),
and weakly with TCF4 (TCFL2). Menin overexpression
increases expression of the Wnt/B-catenin downstream
target gene Axin2, which is associated with increased
H3K4 trimethylation of the Axin2 gene promoter.
Moreover, inhibition of menin expression by siRNA
abrogates H3K4 trimethylation and Axin2 gene
expression. Based on these studies, we hypothesized
that Wnt signaling could inhibit islet cell proliferation
because loss of menin function is thought to increase
endocrine tumor cell proliferation. TGP61 rodent
islet tumor cells treated with a glycogen synthase
kinase 3B inhibitor that increases Wnt pathway
signaling had decreased cell proliferation compared
with vehicle-treated cells. Collectively, these
data suggest that menin has an essential role in
Wnt/B-catenin signaling through a mechanism that
eventually affects histone trimethylation of the
downstream target gene Axin2, and activation of
Wnt/B-catenin signaling inhibits islet tumor cell
proliferation. (Mol Cancer Res 2008;6(12):1894–907)
IntroductionMultiple endocrine neoplasia type 1 (MEN1) is an
autosomal dominant disease characterized by the development
of parathyroid hyperplasia, pancreatic islet cell tumors, and
anterior pituitary endocrine tumors (1). Besides these classic
tumors, several other endocrine and nonendocrine tumors may
develop, including lipomas, dermatofibromas, collagenomas,
ependymomas, meningiomas, schwannomas, carcinoids, adre-
nal cortical tumors, and thyroid tumors. The MEN1 gene is
highly conserved and encodes for a 67-kDa nuclear protein,
called menin, which has been implicated in DNA metabolism
and transcription regulation (2). MEN1 patients have trunca-
tion mutations and missense mutations that are predicted to
inactivate menin function consistent with a tumor suppressor
protein (3). Homozygous knockout mice (Men1�/�) die
in utero (E11.5-13.5) with multiple developmental defects,
suggesting that menin that has an essential role in early
development (4). Similar to MEN1 patients, heterozygous
knockout mice (Men1�/+) develop normally, but the adult mice
eventually grow endocrine tumors (5).
To determine how the loss of menin promotes endocrine
tumor development, most investigations have focused on the
role of menin in transcription regulation. Menin interacts with
several transcription factors including members of the activator
protein-1 (JunD), transforming growth factor-h/bone morpho-
genetic protein (RUNX2, SMAD1, SMAD3, and SMAD5), and
nuclear factor-nB (p65, p50, and p52) signal transduction
pathways (6-11). More recently, menin was identified in MLL
and MLL2 histone methyltransferase complexes and found
essential for the histone methyltransferase activity (12-16).
Pancreas development, in particular islets, is mediated by
expression of a specific program of growth factors including the
Wnt proteins (17-24). In general, Wnt proteins regulate
development through actions on cell proliferation, differentia-
tion, cell fate decisions, apoptosis, axial polarity, axonal
guidance, and adhesion (25). In the canonical Wnt pathway,
the extracellular Wnt ligand (20 different genes in mammalian
cells) binds the cell surface receptor frizzled (10 FZD genes in
mammalian cells) and the coreceptor LRP5/6 (low density
lipoprotein receptor–related proteins 5 and 6). This initiates a
cascade of intracellular mediators that results in h-catenin
stabilization and subsequent h-catenin nuclear localization to
regulate target gene transcription (26). In the absence of Wnt
ligand, h-catenin is phosphorylated in a cytoplasmic complex
with casein kinase 1, glycogen synthase kinase 3h (GSK3h),
axin 1, and the tumor suppressor adenomatous polyposis coli.
Phosphorylated h-catenin is ubiquitylated and targeted for
degradation by the proteasome. Wnt binds the Fzd receptor and
Received 12/14/07; revised 8/4/08; accepted 8/25/08.Grant support: NIH grant R01CA095148 and VA Merit grants (M.P. Sawicki).The costs of publication of this article were defrayed in part by the payment ofpage charges. This article must therefore be hereby marked advertisement inaccordance with 18 U.S.C. Section 1734 solely to indicate this fact.Note: Supplementary data for this article are available at Molecular CancerResearch Online (http://mcr.aacrjournals.org/).Requests for reprints: Mark P. Sawicki, David Geffen School of Medicine, CHS72-215, Los Angeles, CA 90095-6904. Phone: 310-268-3298; Fax: 310-268-3026. E-mail: [email protected] D 2008 American Association for Cancer Research.doi:10.1158/1541-7786.MCR-07-2206
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stops phosphorylation of h-catenin. The hypophosphorylated
h-catenin translocates to the nucleus where it associates with
the T-cell – specific transcription factor/lymphoid enhancer
binding factor 1 (TCF/LEF) family transcription factors and
regulates Wnt responsive genes expression.
Components of the Wnt pathway regulate pancreas deve-
lopment, although the mechanism is not fully understood.
Numerous members of the Wnt pathway are expressed during
the development of the mouse pancreas and in the adult organ
(27). In particular, activated (dephosphorylated) h-catenin and
the parahox protein Pdx-1, which signals pancreas lineage
development, are both expressed in the pancreas epithelium
during development (20). Pdx-1 promoter directing Wnt
misexpression in a transgenic mouse model results in pancreas
agenesis (28). A h-catenin conditional knockout mouse,
however, loses normal pancreatic acinar tissue development,
but islet development is preserved (22). Whereas it is clear that
Wnt signaling and h-catenin are important for pancreas
development, its role in pancreatic endocrine tumor develop-
ment is unknown.
Based on the role of menin in multiple cell signaling
pathways and the broad role of Wnt signaling in tumor
development, we hypothesized that menin may be important for
Wnt/h-catenin signaling in endocrine tumors. In this report, we
investigate the role of menin in Wnt/h-catenin signaling in a
mouse islet cell line. These data suggest menin is important for
regulation of Wnt signaling in the endocrine pancreas through a
mechanism that involves histone H3K4 trimethylation.
ResultsExpression of Endogenous b-Catenin, TCF3, and TCF4 inEndocrine and Nonendocrine Cell Lines and the Effect ofMenin Overexpression
Canonical Wnt pathway protein expression in endocrine
tumor cell lines has not been previously reported. Therefore, we
first determined the expression of activated (dephosphorylated)
h-catenin in selected islet tumor endocrine (TGP-61 and
InR1G9) and nonendocrine cell lines (HEK 293T). Endogenous
h-catenin protein was expressed in all three cell lines (Fig. 1A).
The amount of activated h-catenin protein expression, however,
was variable, with highest expression in the mouse islet tumor
cell line TGP-61 (29), slightly less in human embryonic kidney
cells HEK 293T (30), and barely detectable in the hamster islet
cell line InR1G9 (31). We then examined the expression of two
of the TCF/LEF family members. TCF3 (also called TCF7L1)
and TCF4 (also called TCF7L2) were both highly expressed in
TGP-61 cells, but TCF4 was predominantly expressed in both
HEK 293T and InR1G9 cells. Whereas the expression patterns
of TCF4 and TCF3 differ in these cell lines, these proteins are
functionally similar (25). Overexpression of menin did not
affect the expression of TCF4, TCF3, or activated (dephos-
phorylated) h-catenin in any of the cell lines studied. In cells
expressing fluorescent epitope–tagged h-catenin, TCF3, and
TCF4, menin overexpression did not affect the nuclear
localization of these proteins (Fig. 1B). These data suggest
that proteins important for canonical Wnt signaling are
expressed in these cell lines, in particular the mouse islet
tumor cell line TGP-61, and their expression is not altered by
exogenous menin. Specifically, the amount of activated
(dephosphorylated) h-catenin is not altered by menin over-
expression.
Menin Is Essential for b-Catenin Activation of a TCFResponsive Reporter
To determine whether menin is involved with Wnt/h-catenin
signaling, we studied mouse TGP-61 islet tumor cells trans-
fected with a TCF responsive luciferase reporter vector
(Super8XTOPflash, M50) containing eight TCF/LEF binding
sites or a control vector (Super8XFOPflash, M51) that has
mutant TCF/LEF binding sites (32). As expected, over-
expression of either wild-type h-catenin or the constitutively
activated phosphorylation mutant h-catenin (S37A; ref. 33)
increased TCF reporter gene assay activity (Fig. 2A). Menin
alone did not activate the reporter gene, but cotransfection of
menin and either h-catenin or activated h-catenin (S37A)
strongly stimulated the reporter gene activity severalfold above
that seen with either h-catenin or h-catenin (S37A) alone. One
possible explanation for the increased reporter activity with
menin overexpression could be altered h-catenin expression,
but Western blot analysis shows similar expression of h-catenin
when menin is co-overexpressed with h-catenin or h-catenin
(S37A; Fig. 2A, right). To determine whether menin was
affecting the reporter promoter through a mechanism not
involving the TCF response elements, similar experiments were
done comparing the response of the control reporter gene,
Super8XFOPflash (plasmid M51 labeled ‘‘F’’ in Fig. 2B),
which has mutant TCF binding sites, with the response from the
nonmutated reporter Super8XTOPflash (plasmid M50 labeled
‘‘T’’ in Fig. 2B). Menin and h-catenin did not activate the
negative control reporter gene Super8XFOPflash that has
mutant TCF binding sites (Fig. 2B). Expression of the
overexpressed proteins is shown in Fig. 2B (right), indicating
that the transfections of multiple plasmids did not significantly
interfere with each other. We then wondered whether Wnt/h-
catenin signaling was dependent on menin function. We tested
this hypothesis by decreasing menin expression with transfec-
tion of mouse specific menin-optimized siRNA (TGP61 is a
mouse derived cell line). Several different menin siRNAs were
tested (see Materials and Methods) with the most effective
siRNA chosen for subsequent experiments. Decreased menin
expression significantly inhibited reporter gene activity in
response to transfected h-catenin (label ‘‘M’’ in Fig. 2C)
compared with control siRNA (label ‘‘C’’ in Fig. 2C). Western
blot analysis confirmed that menin protein expression was
reduced by the siRNA transfection (Fig. 2C, right). Similar
studies in human embryonic kidney (HEK 293T) cells showed
that menin more modestly augmented reporter gene activity in
the presence of h-catenin (data not shown).
We then wondered whether disease-associated menin muta-
tions would lose the ability to augment Wnt/h-catenin–mediated
signaling. All of the disease-associated menin missense and
COOH-terminal deletion mutants studied (mutants illustrated in
Fig. 3A) lost the ability to stimulate h-catenin–mediated reporter
gene activity (Fig. 3B and C) consistent with a role for menin in
canonical Wnt/h-catenin–mediated signaling. The menin trun-
cation mutants (meninDB-E) had lower expression compared
with wild-type menin (Fig. 3C, right). To adjust for this effect,
we transfected more plasmid DNA and increased expression of
Menin Is Essential for Wnt Signaling
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the truncated proteins, but this further decreased reporter activity
as if truncated menin was acting in a dominant negative fashion
(data not shown). Overexpression of the missense mutants was
comparable to wild-type menin overexpression (Fig. 3C, right).
Like the menin deletion mutants, there was loss of TCF gene assay
reporter activity augmentation with these menin missense mutants
compared with overexpression of wild-type menin (Fig. 3C, left).
The COOH Terminus of Menin Interacts with b-Catenin,TCF3, and Weakly with TCF4
Because Wnt signaling is mediated by h-catenin binding
members of the TCF/LEF transcription factor family at target
gene promoters (34), we wondered whether menin interacted
with either h-catenin, TCF3, or TCF4. Because exogenously
overexpressed proteins may aggregate and produce artificial
interactions detected by immunoprecipitation, endogenous
menin/h-catenin interactions were investigated (Fig. 4A).
HEK 293T cells were treated with vehicle or a GSK3hinhibitor IX (BIO) to activate the canonical Wnt signaling
cascade, and endogenous menin/h-catenin coimmunoprecipita-
tion was done. Treatment with the GSK3h inhibitor increased
expression of activated h-catenin (see Fig. 4A, bottom).
Immunoprecipitation with anti–activated h-catenin that recog-
nizes h-catenin dephosphorylated on Ser37 or Thr41 confirmed
that endogenous menin coimmunoprecipitated with activated
h-catenin with GSK3h inhibitor treatment. This does not prove
that h-catenin dephosphorylation is necessary for the menin
interaction, but more likely that nuclear localization increases
FIGURE 1. Expression and colocalization of menin, h-catenin, and TCF3/4 in endocrine and nonendocrine cell lines. A. Western blot shows proteinexpression of endogenous h-catenin, activated (dephospho)h-catenin, and TCF3/4 in various cell lines transfected with either empty vector or pCMV-SPORT-menin (designated � and +, respectively). Forty-eight hours after transient transfection with either control vector or a menin-expressing plasmid(pCMV-Sport-menin), plated cells (HEK 293T, TGP-61, and InR1G9) were harvested and the protein lysate was immunoblotted and probed with antibodies toh-catenin, activated h-catenin (recognize h-catenin dephosphorylated on Ser37 or Thr41), and TCF3/4. Anti-menin antibody was used to confirmoverexpression of menin in the pCMV-Sport-menin – transfected cells, and anti –h-tubulin was used to show equal protein loading. For each protein detectedsuch as menin, all images from different cell lines were from the same Western blot and exposure, but the images were separated for publication purposes.B. TGP-61 mouse pancreas islet tumor cells expressing fluorescent epitope– tagged expression constructs show colocalization of menin with h-catenin andTCF3/4. ECFP images are pseudocolored red to distinguish these images from Hoechst dye nuclear staining. ECFP-h-catenin is predominantly nuclear dueto overwhelming the proteasome degradation pathway by high levels of ECFP-h-catenin protein expression, but some cytoplasmic protein is still visualized.All images were obtained with 63� objective.
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FIGURE 2. Menin promotes TCF luciferase reporter gene activity by activation of the Wnt/h-catenin pathway in TGP-61 mouse islet cells. All experimentswere done with triplicate (n = 3) transfections, with the results graphed as the mean F SD. In all of the experiments, the amount of plasmid DNA transfectedwas kept constant by adding empty vector DNA as needed for each sample. All samples were transfected with the control vector pRL-hTK (Renilla luciferase)to adjust the results for transfection efficiency. A. Overexpression of menin promotes TCF luciferase gene reporter activity when cotransfected withh-catenin. The TCF luciferase reporter vector M50 (Super8XTOPflash) was cotransfected with pCMV-SPORT-menin alone, pCMV-SPORT-h-catenin alone,pCMV-SPORT-h-catenin/pCMV-SPORT-menin, or activated h-catenin mutant (S37A)/pCMV-SPORT-menin. The control sample was transfected with thereporter vector M50 with added empty pCMV-SPORT plasmid DNA. TCF reporter gene assay activity was measured by the Dual Luciferase Assay(Promega) and the results of the firefly luciferase/Renilla luciferase (FL/RL ) ratio are graphed for each sample set. Expression of transfected constructs foreach experiment is shown on the right. Protein loading was confirmed by h-tubulin expression. B. The augmentation of TCF luciferase gene reporter activityby menin is abrogated by mutation of the TCF enhancer elements of the gene reporter. To prove that activation of the TCF luciferase gene reporter wasspecifically due to the TCF enhancer, TGP-61 cells were transfected with the TCF reporter vector Super8XTOPflash (M50; label ‘‘T’’ in B) or mutant reportervector Super8XFOPflash (M51; label ‘‘F’’ in B) either alone or cotransfected with h-catenin– or h-catenin/menin–expressing plasmids as above. Expressionof transfected constructs for each experiment is shown on the right. Protein loading was confirmed by h-tubulin expression. C. Menin expression knockdownabrogates the TCF luciferase gene reporter response to overexpressed activated h-catenin. To show that menin knockdown inhibited h-catenin activation ofthe TCF gene reporter (M50), TGP-61 cells were transfected with either siRNA (Dharmacon) specifically optimized for mouse menin ‘‘M’’ or control ‘‘C’’ siRNA24 h prior the transfection with the reporter vector M50 and either empty vector or activated h-catenin mutant (S37A)–expressing plasmid. Control samplehas reporter vector and siRNA. Expression of transfected constructs for each experiment is shown on the right. Protein loading was confirmed by h-tubulinexpression.
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the likelihood of interaction because endogenous and overex-
pressed menin is largely located within the nucleus. Similar
interaction between endogenous menin and h-catenin was shown
in TGP61 cells by coimmunoprecipitation (data not shown).
Based on these data, menin could either directly complex with
h-catenin or indirectly interact as part of a large complex. We
tested this hypothesis by performing in vitro pull-down assays.
For these interaction experiments, an NH2-terminal deletion
FIGURE 3. Mutant menin loses its ability to promote Wnt/h-catenin signaling. All experiments were done with triplicate (n = 3) transfections, with theresults graphed as the mean F SD. In all of the experiments, the amount of plasmid DNA transfected was kept constant by adding empty vector DNA asneeded for each sample. All samples were transfected with the control vector pRL-hTK (Renilla luciferase) to adjust the results for transfection efficiency. A.Diagram illustrates human MEN1 gene structure, disease-associated missense mutants, COOH-terminal deletion mutants, and NH2-terminal deletionmutants used in this article. Exons are numbered 1 to 10. Exon 10 is shortened for illustration purposes. Disease-associated menin missense mutants aredesignated above the gene structure. The COOH-terminal menin deletion mutants are designated by the amino acid that is mutated to a stop codon within themenin protein. The NH2-terminal deletion menin mutants show the amino acid residues expressed by the expression vector. B. Menin COOH-terminaldeletion mutants lose the ability to promote TCF luciferase gene assay reporter activity in TGP61 cells. TGP-61 cells were transfected with the reporter vectorM50 and cotransfected with pSport-h-catenin with or without pSport-menin in the presence of different menin COOH-terminal deletion mutants (meninDB-E).TCF reporter gene assay activity was measured by the Dual Luciferase Assay (Promega) and the results of the firefly luciferase/Renilla luciferase ratio aregraphed for each sample set. Western blot analysis (B, right ) shows decreased expression of the transfected menin deletion mutants compared withoverexpressed wild-type menin. Increasing the deletion mutant menin plasmid expression by increasing the amount of transfected plasmid (meninDB-E)further decreased reporter activity (data not shown). Protein loading was confirmed by h-tubulin expression. C. Menin missense point mutants lose the abilityto promote TCF gene assay reporter activity in TGP61. TGP-61 cells were transfected with the reporter vector M50 and cotransfected with pSport-h-cateninwith or without pSport-menin or missense menin mutants (P12L, L22R, H139Y, A160P, A176P, and L286P). Right, corresponding Western blot for thetransfected proteins. Protein loading was confirmed by h-tubulin expression.
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mutant, meninD5s (contains amino acids 477-610), was expressed
as a glutathione S-transferase (GST) fusion protein in bacteria,
purified by immobilized glutathione gel, and incubated with
in vitro transcribed-translated (TnT) h-catenin, TCF4, and TCF3
(Fig. 4B). The proteins bound to the NH2-terminal deletion mutant
and analyzed by Western blot analysis revealed specific pull-down
of h-catenin, TCF3, and TCF4 by GST-meninD5s. These proteins
were not seen with the GST control protein. Menin, therefore,
directly interacts with h-catenin, TCF3, and TCF4.
To define the menin interaction region, menin and h-catenin
were coexpressed in HEK 293T cells and coimmunoprecipitated
(Fig. 5A). Full-length menin specifically coimmunoprecipitated
with h-catenin. To determine the region of the menin protein that
binds to h-catenin, HEK 293T cells were cotransfected with
different menin deletion mutants (see diagram Fig. 3A). The
coimmunoprecipitation studied showed that h-catenin binds to
the COOH-terminal region of menin (Fig. 5A). COOH-terminal
menin truncation mutants (meninDB-D), on the other hand,
largely lost the ability to interact with h-catenin (Fig. 5B). The
longest of these COOH-terminal deletion mutants, meninDE,
weakly interacted with h-catenin. The majority of naturally
occurring disease-associated truncation mutations, therefore,
would be predicted to lose the ability to interact with h-catenin.
We then wondered whether menin interacted with other members
of the h-catenin transcription complex and showed that menin
could bind TCF3 or weakly with TCF4 either directly or as part
of a larger complex by coimmunoprecipitation in HEK 293T
cells (Fig. 5C).
Menin Regulates Wnt Downstream Target Axin2 GeneExpression
Because menin significantly increased TCF reporter gene
activity in the presence of activated h-catenin, we wondered
whether endogenous gene expression was likewise affected
in TGP-61 cells. To identify a target gene modulated by
Wnt/h-catenin signaling in TGP-61 cells, we studied the mRNA
expression of several known downstream target genes: c-MYC,
NKX2-2, Taspase, PDX1, LEF, MET, CDX1, HNF3B, HDAC9,
LMX1 , and AXIN2 (35).1 TGP-61 cells transfected with
FIGURE 4. Menin interacts with h-catenin,TCF3, and TCF4. A. Endogenous menin interactswith h-catenin, shown by coimmunoprecipitationanalysis. HEK 293T cells (control) or cells treatedwith GSK3h inhibitor IX (5 Amol/L), to activate Wntsignaling by inhibiting h-catenin phosphorylationand proteasome degradation, were harvested andlysed in radioimmunoprecipitation assay buffer.Bottom, Western blot for the input lysates used inthe coimmunoprecipitation. The GSK3h inhibitorincreased expression of activated (dephosphory-lated) h-catenin. The immunoprecipitation andcoimmunoprecipitation are shown on top. Anti –activated h-catenin antibody (recognize h-catenindephosphorylated on Ser37 or Thr41) was used forimmunoprecipitation (IP ) and samples were West-ern blotted (IB ) with either anti –activated h-catenin or anti-menin antibody (top ). The immu-nopreciptiation of activated (dephosphorylated)h-catenin is clearly shown (top , lower Westernblot). Coimmunoprecipitation for the endogenousmenin and h-catenin proteins (top , upper Westernblot) is maximal when h-catenin is activated withthe GSK3h inhibitor. Control antibody for theimmunoprecipitation was mouse IgG (JacksonImmunoResearch Laboratories). B. The meninCOOH terminus interacts with h-catenin, TCF3,and TCF4 in vitro as shown by GST pull-downassay. GST-tagged meninD5s (contains meninCOOH terminus) was expressed in bacteria andimmobilized on glutathione-coated agarose beads.In vitro transcribed and translated (TnT Systemfrom Promega) and biotin-labeled (Transcend fromPromega) h-catenin, TCF3, and TCF4 were usedfor pull-down assay and analyzed by Westernblotting. Input represents 10% of the TnT productto control for the amount of protein used to showinteraction. Biotinylated TnT products weredetected by the Transcend Non-RadioactiveTranslation Detection System from Promega(labeled TNT in figure).
1 See www.stanford.edu/~rnusse/wntwindow.html.
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expression constructs for menin and h-catenin (S37A) showed
increased Axin2 gene expression in response to h-catenin in both
TGP-61 and HEK 293T cells (Fig. 6A). There was no effect on
b-actin gene (loading control) expression. Similarly, Axin2
protein expression was increased in response to increased
h-catenin and menin/h-catenin expression (Fig. 6B). Expression
of other Wnt regulated genes tested was not affected by Wnt
signaling in these particular cell lines. This is not surprising
FIGURE 5. The COOH terminus of menin interacts with h-catenin, TCF3, and TCF4, shown by coimmunoprecipitation analysis. A. The menin COOHterminus interacts with h-catenin. Western blots (IB ; immunoblot antibody) were done on cell lysates or immunoprecipitates (IP ; immnuoprecipitate antibody).HEK 293T cells were cotransfected with plasmids expressing FLAG-h-catenin and either full-length His-menin or NH2-terminal deletion mutants meninD2-D6and coimmunoprecipitated to show interaction between the menin COOH terminus and h-catenin. The lower two Western blots show expression of thetransfected expression constructs. The upper two Western blots show the results from immunoprecipitation. Menin D6 has low levels of expression butimmunoprecipitates well. B. Deletion of the menin COOH terminus abrogates its ability to interact with h-catenin. HEK 293T cells were cotransfected withplasmids expressing FLAG-h-catenin and HA-menin and the COOH-terminal deletion mutants (HA-meninDB-DE). Immunoprecipitation shows interactionbetween full-length menin and h-catenin. There is a weaker interaction between h-catenin and menin DE (which contains one nuclear localization signal). Theother menin deletion mutants do not interact strongly. C. The menin COOH terminus interacts with TCF3/4. HEK 293T cells were cotransfected with plasmidsexpressing HA-menin and HA-meninD5 transfected alone or with FLAG-h-catenin, FLAG-h-catenin (S37A), FLAG-TCF3, and FLAG-TCF4, respectively,showing that the COOH terminus of menin could interact with all of them, albeit weakly with TCF4. Asterisks represent immunoglobin (IgG) proteins from theimmunoprecipitation.
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because the Wnt signaling response is likely tissue specific
and the particular target genes for endocrine cell types are
unknown. Based on the reporter gene assay data, we hypothe-
sized that decreased menin expression would block h-catenin–
induced Axin2 transcription. Indeed, h-catenin–induced Axin2
gene transcription was repressed by siRNA knockdown of menin
expression in TGP-61 cells (Fig. 6C and D). To further confirm
the role of menin in Wnt signaling, we performed Western blot
analysis of SW480 colon cancer cells with constitutively active
h-catenin (due to adenomatous polyposis coli mutation) after
siRNA knockdown of menin expression. Compared with control
transfected SW480 cells, menin siRNA–transfected SW480
cells had decreased Axin2 gene expression similar to our findings
in TGP61 cells (Supplementary Fig. S1). These data suggest that
at least one endogenous canonical Wnt/h-catenin signaling target
gene (Axin2) is dependent on menin expression.
Menin Is Essential for Histone H3K4 Trimethylation in theMouse Axin2 Gene Promoter in Response to Wnt/b-Catenin SignalingAxin2 gene expression is regulated by the Wnt/h-catenin
signaling pathway in TGP-61 mouse islet tumor cells and
menin is essential for this signaling (see above), but the exact
molecular role for menin is unknown. Because menin is known
to bind MLL histone methyltransferase complexes (13, 15), we
hypothesized that menin could be involved in histone H3K4
trimethylation at the Axin2 gene promoter in response to Wnt/
h-catenin signaling. Using the chromatin immunoprecipitation
assay with an antibody to trimethylated histone 3 lysine 4 (anti-
H3K4) and DNA amplification by PCR for the proximal Axin2
promoter (genomic regions designated T2 and T3; ref. 36;
Fig. 7A), we showed increased histone H3 K4 trimethylation in
the h-catenin (S37A)–transfected TGP-61 islet tumor cells
compared with empty vector– transfected cells (Fig. 7B).
Histone H3K4 trimethylation was further increased when the
active h-catenin (S37A) was cotransfected with the menin
expression vector (Fig. 7B). To determine if menin was essential
for Axin2 gene promoter H3K4 trimethylation, Men1 siRNA
knockdown was done. Menin protein expression was reduced
and an associated decrease in Axin2 promoter histone H3K4
trimethylation was also seen (Fig. 7C). Hence, menin is directly
or indirectly essential for Axin2 gene promoter histone H3K4
trimethylation in response to Wnt/h-catenin signaling.
Increased Wnt/h-catenin signaling decreases TGP61 islet
tumor cell proliferation in vitro . Based on the above studies, we
hypothesized that increased Wnt signaling could inhibit islet
FIGURE 6. Menin is important for Wnt/h-catenin endogenous Axin2 gene expression. A. Wnt/h-catenin signaling and menin overexpression increaseendogenous Axin2 gene expression. Agarose gels show RT-PCR semiquantitative Axin2 gene expression results after activation of the Wnt/h-cateninsignaling pathway. HEK-293T and TGP-61 cells were transfected with control expression vector, pSPORT-CMV-h-catenin expression vector, or pSPORT-CMV-h-catenin and pSPORT-CMV-menin expression vectors. Forty-eight hours later, total RNA was extracted and analyzed by RT-PCR using Axin2primers. h-Actin primers were used to confirm equal loading of RNA into the RT-PCR reactions. B. Western blot analysis of Axin2 protein expressioncorresponding to the experiment done in A. Western blot with anti –h-tubulin antibody was used as a control for protein gel loading. C. Menin knockdownabrogates the ability of Wnt/h-catenin signaling to increase endogenous Axin2 gene expression. Agarose gels showing semiquantitative RT-PCR geneexpression results after Men1 siRNA transfection and activation of the Wnt/h-catenin signaling pathway. TGP-61 cells were first transfected with eithercontrol or Men1 specific siRNA. Twenty-four hours later, the cells were transfected with control expression vector or pSPORT-CMV-h-catenin expressionvector. RT-PCR was done 48 h later, using Axin2, Men1, b-catenin , or b-actin primers as indicated. D. Western blot analysis of Axin2, menin, and h-cateninprotein expression corresponding to the experiment done in C. Western blot with anti –h-tubulin antibody was used as a control for protein gel loading.
Menin Is Essential for Wnt Signaling
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cell proliferation because loss of menin function is thought to
increase endocrine tumor cell proliferation. Indeed, TGP61 islet
tumor cells transfected with menin siRNA show increased cell
proliferation compared with control transfected cells (Supple-
mentary Fig. S2). To determine whether Wnt signaling affects
TGP16 rodent islet tumor cell proliferation, TGP61 cells were
treated with a GSK3h inhibitor (BIO, Calbiochem) that
increases Wnt pathway signaling by decreasing h-catenin
proteasome–mediated degradation (Fig. 8A). Western blot
analysis shows that GSK3h inhibitor treatment increased
activated h-catenin expression compared with vehicle-treated
cells. In addition, cell counting at 0, 24, 48, and 72 hours
showed decreased cell proliferation compared with vehicle-
treated cells (Fig. 8B). Flow cytometry analysis suggests that
this is due to an increase in G2-M phase arrested cells
(Supplementary Fig. S3).
DiscussionIn this study, we show that menin is essential for Wnt/h-
catenin signaling in a mouse islet tumor cell line. The molecular
mechanism involves a direct interaction between h-catenin and
the COOH terminus of menin at the target gene promoter
(Axin2 in this study) and resultant histone H3K4 trimethylation.
Menin COOH-terminal truncation mutants lose their ability to
interact with h-catenin and their ability to increase TCF gene
reporter activity, which is consistent with a requirement for
inactivation of Wnt signaling during islet tumor development.
Although these studies show that histone H3K4 trimethylation
FIGURE 7. Menin is important for histone H3 K4 trimethylation in the mouse Axin2 gene promoter in response to Wnt/h-catenin signaling. A. Diagramillustrating the genomic organization of the mouse Axin2 gene 5¶ upstream region. Locations of TCF/LEF consensus binding elements (T2-T8) are depicted.B. Overexpression of menin increases Wnt/h-catenin signaling–associated Axin2 gene promoter H3K4 trimethylation. Top, agarose gels with PCR productsfrom the chromatin immunoprecipitation assay. TGP-61 cells were transfected with empty expression vector (UV ), active h-catenin (S37A ) expressionvector, or h-catenin (S37A)/menin expression vectors as shown. Forty-eight hours later, the chromatin immunoprecipitation assay was done with a trimethylspecific anti-H3K4 antibody. The T2/T3 promoter region was PCR amplified as depicted in the gene diagram above. Bottom, input DNA loading for the PCR.C. Menin expression knockdown abrogates Axin2 gene promoter H3K4 trimethylation in response to Wnt/h-catenin signaling. Agarose gels with PCRproducts from the chromatin immunoprecipitation assay showing the effect of Men1 siRNA on H3K4 methylation of the Axin2 gene promoter region T2/T3 inresponse to Wnt/h-catenin signaling are shown. TGP61 cells were first transfected with either control or specific Men1 siRNA. Twenty-four hours later, cellswere then transfected with control expression vector (UV ) or a h-catenin (S37A ) expression vector. Chromatin immunoprecipitation assays were done 48h later with either anti – trimethyl H3K4 antibody or anti-menin antibody. The fixed cells were also lysed and analyzed by Western blotting (IB ) with anti-meninantibody and anti –h-tubulin antibody to show reduced expression of menin with Men1 siRNA.
Chen et al.
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is affected at the Axin2 promoter, we do not know whether this
is a direct or indirect effect.
Because menin is inactivated in MEN1-associated endo-
crine tumors, we hypothesize that canonical Wnt signaling
could be diminished in these tumors. This contradicts the
typical role of Wnt activation in several malignancies such as
colon cancer (25, 37, 38) and recent data suggesting that
Wnt signaling is important for h-cell proliferation (39, 40).
Most tumors with Wnt signaling abnormalities reported
reveal activation of this pathway, but a few tumors such as
salivary gland tumors have inactivation of the Wnt pathway
(41). Menin inactivation could contribute to tumorigenesis by
disabling the canonical Wnt pathway. Indeed, activation of
Wnt/h-catenin signaling in TGP61 cells resulted in decreased
cell proliferation. This hypothesis is supported by mouse
models showing that Wnt/h-catenin inactivation results in the
loss of pancreas acinar cell development, but promotes or at
least preserves pancreas islet development (22). None of
these transgenic models of Wnt signaling/h-catenin signaling
develop endocrine tumors, suggesting that Wnt signaling may
not be critical for MEN1-associated tumor development. A
Men1 knockout mouse model, however, showed that h-
catenin is predominantly cytoplasmic, rather than nuclear, in
the islet tumors (42).
Men1 homozygous knockout mice, however, do have
craniofacial bone development abnormalities, and menin has
been proposed to have a direct role in bone development
(reviewed in ref. 43). Because Wnt/h-catenin has also been
implicated in bone development, it is possible that menin is
critical for proper osteoblast differentiation, in part, through
Wnt signaling and h-catenin/menin transcriptional activation of
RUNX2, the master regulator of bone formation (see review in
ref. 44).
In the absence of Wnt signaling, TCF/LEF transcription
factors form a complex with Groucho/Grg/transducin-like
enhancer-of-split proteins and thereby function as a transcrip-
tion repressor (reviewed in ref. 26). With Wnt signaling, h-
catenin displaces Groucho from the TCF/LEF complex and
thereby activates transcription. The mechanism for transcription
activation is hypothesized to involve interaction with coac-
tivators such as the histone acetylase, cyclic AMP-responsive
element binding protein–binding protein, and brahma-related
gene 1, which is a component of the SWI/SNF family of the
ATP-dependent chromatin remodeling complexes. Histone
methylation is also thought to be involved (45). Because menin
interacts with both h-catenin and the histone methyltransferase
complex, we hypothesize that menin is important for recruit-
ment of MLL histone methyltransferase to the h-catenin/TCF
activator complex at the gene promoter.
Interestingly, parafibromin, which is the tumor suppressor
protein mutated in hyperparathyroidism-jaw tumor syndrome 2,
also binds h-catenin and regulates Wnt target gene transcription
FIGURE 8. Proliferation of TGP61 cells is reduced by GSK3h inhibitor treatment. TGP61 cells were plated in triplicate for each time point and treated witheither vehicle or GSK3h inhibitor IX (BIO from Calbiochem) as described in Materials and Methods. Cell cultures were split for counting and Western blotanalysis. A. Western blot was done to determine the endogenous expression of activated h-catenin, menin, and h-tubulin after treatment with GSK3hinhibitor (5 Amol/L BIO, Calbiochem). Activated (dephosphorylated) h-catenin was detected with an antibody that recognizes h-catenin dephosphorylated onSer37 or Thr41 (Upstate). Western blot with anti –h-tubulin antibody was used as a control for protein gel loading. B. Graph of TGP61 cell proliferation(triplicate cultures) shows cell counting at 0, 24, 48, and 72 h after plating. E, cells treated with GSK3h inhibitor (5 Amol/L BIO); ., vehicle-treated cells.Points, mean cell count for triplicate cultures; bars, SD.
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through a mechanism thought to involve the PAF1 complex
(Paf1, Cdc73, Leo1, Ctr9, and Rtf1; ref. 46). Hence, MEN1 and
hyperparathyroidism-jaw tumor syndrome 2 may share a
similar signaling pathway mechanism involving histone
methylation and Wnt signaling.
We found that Axin2 expression is regulated in our mouse
islet tumor cell culture model for studying menin function. This
is not surprising because Axin2 is considered a possible
universal Wnt/h-catenin target, perhaps as part of autoregulation
of this pathway (25). It will be important to identify islet-specific
targets, if they exist, and further to understand the role of Wnt
signaling in islet cell biology as well as tumor development.
Materials and MethodsReagents and Cell Lines
Hamster islet tumor cells InR1G9 (kind gift from Dr. Craig
Smith) and human embryonic kidney cells (HEK 293T from
American Type Culture Collection) were cultivated in DMEM
(Mediatech, Inc.) supplemented with 10% fetal bovine serum
(Omega, Inc.), 2 mmol/L L-glutamine, 100 units/mL penicillin,
and 100 Ag/mL streptomycin (Omega). Mouse islet tumor cells
(TGP-61 from American Type Culture Collection) were
cultivated in 50% DMEM/50% F12K medium (Mediatech)
supplemented with 10% fetal bovine serum and L-glutamine/
penicillin/streptomycin. The rat monoclonal anti-hemagglutinin
antibody (12CA5) was purchased from Roche Applied Science.
The monoclonal anti-FLAG (M2) antibody was purchased from
Sigma-Aldrich. The rabbit polyclonal anti-menin antibody
(BL342) and the goat anti-GST antibody were purchased from
Bethyl Laboratories. The mouse monoclonal anti-His G
antibody was purchased from Invitrogen Corp. The antimouse
Axin2 antibody (ab32197) was purchased from Abcam. The
TCF/LEF reporter plasmid Super8XTOPflash (M50) and its
control mutant plasmid Super8XFOPflash (M51) were kind gifts
from Dr. Randall T. Moon. The human MEN1 full-length wild-
type and missense mutation expression constructs in the vector
pCMV-SPORT were a kind gift from Dr. Sunita Agarwal.
siRNA and TransfectionsiRNAs were purchased from Dharmacon RNA Technol-
ogies. Mouse Men1 siRNA SMARTpools were optimized to
find the best suppressor of menin expression (optimum mouse
Men1 siRNA sequence: GCUAAGACCUACUACCAGGUU)
determined by reverse transcription-PCR (RT-PCR) and
Western blot analysis. Non-Specific Control-V siRNA was
used as a siRNA control. Cells were transfected using
Oligofectamine (Invitrogen) transfection reagent. For experi-
ments requiring inhibition of Wnt signaling, the cells were
mock treated with vehicle or treated by GSK3h inhibitor IX
(Calbiochem) 5 Amol/L for 1 h before harvesting the cells.
Reduction of mouse Men1 mRNA expression was confirmed
by RT-PCR and mouse menin protein expression was
confirmed by Western blot analysis.
Construction of Expression PlasmidsRecombinant expression plasmids were constructed as
described (47). Briefly, a full-length MEN1 cDNA was isolated
by screening a human PBL E phage cDNA library (Clontech
Laboratories, Inc.), probed with a random primed radiolabeled
probe (Boehringer Mannheim), and PCR amplified (PCR
Advantage, Clontech Laboratories) using the 500-bp genomic
fragment from the first exon of human menin. The open reading
frame of this full-length E phage cDNA clone (internal lab
designated clone E$-menin-1.2.3) was high-fidelity PCR
amplified (PCR Advantage) with primers 5 ¶-gaatt-
cATGGGGCTGAAGGCC (small case: EcoRI restriction site)
and 5¶-TCAGAGGCCTTTGCG, and then TA cloned into
vector pCR2.1 (Invitrogen). Fidelity of the PCR DNA
amplification and cloning was confirmed by fully sequencing
the entire pCR2.1-menin (internal lab clone E4.1) insert in both
directions. The pcDNA3.1/HisC-menin construct was created
by subcloning the MEN1 open reading frame fragment from
pCR2.1-menin into the EcoRI site of the pcDNA3.1/HisC
expression vector (Invitrogen). An expression construct for
hemagglutinin epitope– tagged menin (pcDNA3.1-HA-menin)
was created by PCR DNA amplification of full-length
MEN1 open reading frame (pCR2.1-menin) using primers
5¶-gaattcGCCATGTACCCATACGATGTTCCAGATTACGCT-
TACCCATACGATGTTCCAGATTACGCTGGGCT-
GAAGGCCGCC (2xHA epitope underlined; EcoRI site shown
in small case) and 5¶-CCggatccTTCAGAGGCCTTTGCG
(small case: BamHI site not used for this construct). The
2xHA-menin PCR fragment was TA cloned back into pCR2.1
(pCR2.1-HA-menin). The EcoRI-EcoRI fragment from
pCR2.1-HA-menin was subcloned into the EcoRI site of
pcDNA3.1 (Invitrogen).
Hemagglutinin epitope–tagged menin COOH-terminal de-
letion mutants, pcDNA3.1-HA-meninDB (delete amino acids
263-610), meninDC (delete amino acids 341-610), meninDD
(delete amino acids 460-610), and meninDE (delete amino acids
527-610), were generated from pCR2.1-HA-menin (see above)
by site-directed mutagenesis (48) and subcloning into the
expression vector pcDNA3.1.
The menin NH2-terminal deletion mutants pcDNA3.1/HisC-
meninD2 (delete amino acids 1-197), meninD3 (delete amino
acids 1-276), meninD4 (delete amino acids 1-382), and
meninD5 (delete amino acids 1-443) were generated from
pCR2.1-menin (see above) by subcloning respectively the
blunted HincII-BamHI fragment, blunted BstEII-BamHI frag-
ment, blunted KpnI-BamHI fragment, blunted BstXI-BamHI
fragment, and blunted AvrII-BamHI fragment into pcDNA3.1/
HisC. The pcDNA3.1HisB-meninD6 (delete amino acids 1-526)
mutant was created by PCR DNA amplification using the primer
5¶-CgaattcCCGAGGCCCTGAAGG (small case: EcoRI site)
and vector BGH reverse primer 5¶-TAGAAGGCACAGTC-
GAGG, and then the PCR fragment was cloned into the
pcDNA3.1HisB vector (Invitrogen).
The GST-menin NH2-terminal deletion mutant pGEX4T2-
meninD5s (delete amino acids 1-476) was created by subclon-
ing the SmaI-NotI fragment of pcDNA3.1-menin into the
bacteria expression vector pGEX4T2 (GE Healthcare Bio-
Sciences Corp.) SalI-blunted/NotI restriction sites.
Two menin missense mutant expression constructs, pCMV-
SPORT-Men-P12L and pCMV-SPORT-Men-L22R, were gen-
erated from pCMV-SPORT-menin (kind gift from Dr. Sunita
Agarwal) using the splice overlap extension method (48) with
the primers P12Lf (5¶-GACGCTGTTCCTGCTGCGCTC),
Chen et al.
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P12Lr (5¶-GAGCGCAGCAGGAACAGCGTC), L22Rf (5¶-GGTGCGCCGGTTTGCTGCCGA), and L22Rr (5¶-GCAG-
CAAACCGGCGCACCACG; underlined and boldfaced letter
is the mutated nucleotide).
The cDNA coding for wild-type h-catenin was obtained from
IMAGE clone 6151332 (Invitrogen), and the constitutively
active missense mutant pCMV-SPORT-h-catenin (S37A) was a
kind gift from Dr. Eric Vilain. The open reading frames of wild-
type h-catenin and mutant S37A were subcloned into the
mammalian expression vectors p3XF10 (Sigma-Aldrich) and
pECFP-N1 (Clontech Laboratories) by PCR-TA (Invitrogen)
cloning using the following primers: for p3XF10-h-catenin,
HCATf 5¶-ggtaccATGGCTACTCAAGCTGATTTG (small case:
Kpn I site) and HCATr 5¶-tctagaTTACAGGTCAGTAT-
CAAACCA (small case: XbaI site); for pECFP-h-catenin,
CATNOr 5¶-gatatcCCAGGTCAGTATCAAACCAGGC (small
case: EcoRV site). The full-length cDNAs for TCF3 (also called
TCF7L1) and TCF4 (also called TCF7L2) were purchased from
Invitrogen (IMAGE clones 6141641 and 5533185, respectively)
and PCR-TA cloned into plasmids p3XF10, pcDNA3.1/HisB,
pEYFP-C1 (Clontech Laboratories), and pECFP-N1 using the
following PCR primers: TCF3f, 5¶-gaattcCACCATGCCC-
CAGCTCG (small case: EcoRI site); TCF3r, 5¶-gatatcT-
TAGTGGGCAGACTTGGTG (small case: EcoRV site);
TCF3Nr, 5¶-gatatcCGTGGGCAGACTTGGTGACC (small
case: EcoRV site); TCF4f, 5¶-gaattcAAAAATGCCGCAGCT-
GAAC (small EcoRI case site); and TCF4r, 5¶-gatatcTAG-
TAAGCTTCCATCTGAAGA (small case: EcoRV site).
GST Pull-Down AssayPull-down protein interaction studies were done according to
the manufacturer’s recommendations (ProFound Pull-Down
GST Protein:Protein Interaction Kit, Pierce Biotechnology).
Briefly, the competent bacteria (BL21 strain) were transformed
with either pGEX4T2 or pGEX4T2-meninD5s plasmids and
grown under selective conditions to produce the ‘‘bait’’ protein.
One colony from each transformants was scraped and grown in
suspension at 28jC overnight. Bacteria were diluted into fresh
media the next day, and the protein expression was isopropyl-h-
D-1-thiogalactopyranoside induced when the bacterial culture
attained an A600 z0.6. Induced bacteria were isolated by
centrifugation and lysed in the provided buffer. GST-tagged
proteins were immobilized on the glutathione-coated agarose
beads according to the manufacturer’s protocol. Biotinylated
(Transcend Non-Radioactive Translation Detection System
from Promega) full-length h-catenin, TCF3, and TCF4 proteins
were made by in vitro transcription/translation reaction of
pSPORT-h-catenin (construct from Invitrogen), pcDNA3.1/
HisB-TCF3, and pcDNA3.1/HisB-TCF4 following the manu-
facturer’s recommendations (Promega, TnT Quick Coupled
Transcription/Translation Systems) and added as ‘‘prey’’ to the
complex of beads with immobilized GST epitope–tagged
‘‘bait.’’ The bead complexes were washed and the bound
‘‘prey’’ proteins were eluted for SDS-PAGE and further
analysis by Western blot.
Transient TransfectionCulture dishes (100 mm) were seeded with either 2 � 106
HEK 293T cells, 1 � 106 TGP-61 cells, or 2 � 106 InR1G9
cells 24 h before transfection. Cells were transfected with
different plasmids using Effectene Transfection Reagent
(Qiagen, Inc.). For HEK 293T cells, 2 to 4 Ag of plasmid and
15 AL of Effectene/Ag plasmid were used for each transfection.
For TGP-61 and InR1G9 cells, 4 to 6 Ag of plasmid and 25 AL
of Effectene/Ag plasmid were used for each transfection.
Cotransfection with empty vector DNA was done as needed
to keep the amount of transfected DNA consistent between
samples in each experiment.
Total Cell Protein ExtractionPlated cells were washed twice in cold 1� PBS (without
calcium) buffer and then lysed in radioimmunoprecipitation
assay buffer containing 50 mmol/L Tris-HCl (pH 7.4),
200 mmol/L NaCl, 1 mmol/L EDTA, 1% NP40, 0.5% sodium
deoxycholate, 0.5% SDS, 2 mmol/L NaVO4, 2 mmol/L NaF,
and 1 mmol/L phenylmethylsulfonyl fluoride supplemented
with Complete Protease Inhibitor Cocktail as recommended by
the manufacturer (Roche Applied Science). After a 30-min
incubation on ice, the cell lysate was sonicated twice on ice
(8 s), centrifuged (13,000 rpm at 4jC) for 15 min, and the
supernatant was stored at �80jC for Western blotting.
Coimmunoprecipitation and Western Blot AnalysisAfter 48 h posttransfection, the plated cells were harvested
for protein as above. The protein lysates were precleared with
protein G-Sepharose 4B (Sigma-Aldrich) for 30 min and then
incubated for 2 h with rat monoclonal anti-hemagglutinin or
mouse monoclonal anti-HisG. Untransfected cells were treated
similarly but immunoprecipitated with anti–activated h-catenin
antibody (Upstate clone 8E7). Immune complexes were
captured with protein G-Sepharose 4B beads for an additional
hour, centrifuged, washed four times in radioimmunoprecipita-
tion assay buffer, and then solubilized in SDS sample buffer.
Proteins were analyzed on precast 4% to 12% gel (Invitrogen)
and immunoblotted with mouse monoclonal anti-FLAG
antibody. The immune complexes were detected by horserad-
ish-conjugated secondary antibody and developed by enhanced
chemiluminescence (Amersham Pharmacia Biotech). Images
were digitized with Quantity One Software (Bio-Rad) using the
Bio-Rad Versadoc Imaging System Model 3000. The images
were prepared for publication with Adobe Photoshop and
Illustrator software.
Luciferase AssaysAll luciferase assay experiments were done in triplicate, with
data reported as mean F SD. Twenty-four-well plates were
seeded with 3 � 104 TGP-61 cells 24 h before transfection.
Cells were transfected with different plasmids (including M50,
M51, and pRL-hTK) using Effectene Transfection Reagent. An
equal amount of transfected plasmid DNAwas ensured between
different samples in each experimental group by adding empty
control vector plasmid DNA as needed. Twenty-four hours after
transfection, the medium was changed to fresh medium
containing 5% charcoal stripped serum. Twenty-four hours
later, the cells were lysed in 1� PLB, and luciferase assays
were done using the Dual-Luciferase Reporter Assay System as
recommended by the manufacturer (Promega). SDS-PAGE
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sample buffer was added to the remaining lysate, and Western
blotting was done to ensure every transfected plasmid was
expressed for each samples.
Chromatin Immunoprecipitation AssayThe chromatin immunoprecipitation assays were done
following the protocol described with some minor modifica-
tions (49). Briefly, after different transfections and treatments,
37% formaldehyde (Fisher Scientific) was added directly to
culture medium in the plate to a final concentration of 1% to
cross-link the proteins to the DNA. After incubation for 10 min
at 37jC, cells were washed twice using ice-cold PBS
containing protease inhibitor cocktail. Cells were scrapped
from the plate and harvested into 1.5-mL Eppendorf tubes and
then briefly centrifuged. Cell pellets were lysed in 800-AL SDS
lysis buffer containing 1% SDS, 10 mmol/L EDTA, and
50 mmol/L Tris-HCl (pH 8.1) with freshly added protease
inhibitor cocktail. After a 10-min incubation on ice, the lysates
were sonicated thrice for 10 s on ice and centrifuged. Then the
supernatant (200 AL) was diluted with 1,800 AL of chromatin
immunoprecipitation dilution buffer containing 0.01% SDS,
1.1% Triton X-100, 1.2 mmol/L EDTA, 16.7 mmol/L Tris-HCl
(pH 8.1), and 167 mmol/L NaCl, with freshly added protease
inhibitor cocktail. An aliquot of diluted sample (200 AL) was
saved as input control DNA and, after adding 8 AL of 5 mol/L
NaCl, reverse cross-linked at 65jC overnight. The remaining
samples were precleared with 50 AL of salmon sperm DNA/
protein G-Sepharose-50% slurry for at least 30 min at 4jC with
agitation. The supernatant fractions were collected and either
anti – trimethyl-H3K4 (Upstate USA, Inc.) or anti-menin
antibody was added for immunoprecipitation with rotation at
4jC overnight followed by adding 50 AL of salmon sperm
DNA/protein G-Sepharose slurry for 1 h at 4jC with rotation to
collect the immunocomplex. For a negative control, a no-
antibody immunoprecipitation was done by incubating the
supernatant fraction with 50 AL of salmon sperm DNA/protein
G-Sepharose slurry for 1 h at 4jC before washing the beads.
The samples were washed and eluted, and the DNA was
extracted with a commercial DNA extraction kit (Qiagen). The
DNA was eluted in 30 AL Tris (pH 8.5) buffer, PCR amplified
with AccuPrime Taq polymerase (Invitrogen), and analyzed by
electrophoresis on agarose gel. The primers used to amplify the
mouse Axin2 promoter region, designated as T2/3, were mt23F,
5 ¶-GCGGCGGGATCACTGGCT, and mt23R , 5 ¶-TCCTCCGGGCGCTTCCAAC (36).
RT-PCRHEK 293T cells and TGP-61 cells were plated in a six-well
plate 24 h before transfection. Cells were transfected with
different expression plasmids using Effectene Transfection
Reagent. Two days later, the total RNA was extracted with
Trizol (Invitrogen). The first cDNA was synthesized using the
1st cDNA Synthesis Kit (GE Healthcare Lifesciences), and
followed by RT-PCR with Taq DNA polymerase (Invitrogen).
The primers used were 5LEF1, 5¶-GCCGAGATCAGTCATC-
CCGA; 3LEF1, 5¶-CACCACGGGCACTTTATTTGAT; 5TAS-
PASE, 5¶-AACGAGCTTGTCAGAAGGCAATT; 3TASPASE,
5¶-CCACCCTTTCTGCCAGCTCTA; 5NKX2-2, 5¶-CTGAC-
CAACACAAAGACGGGG; 3NKX2-2, 5¶-GCCGCTCCAGC-
TCGTAGG; 5hMET, 5¶-GATCAACTCATTAGCTGTGGC;
5mMET, 5¶-GCAGCAGCAAAGCCAAT; 3MET, 5¶-TGAA-
AAGTCTGAGCATCTAGAGT; 5HDAC9, 5¶-GGAGCC-
CATCTCACCTTTAGACC; 3HDAC9, 5¶-TGCCACTGCC-
CTTTCTCGTC; 5AXIN2, 5¶-GCCGATTGCTGAGAGGA-
ACTG; 3AXIN2, 5¶-AAAGTTTTGGTATCCTTCAGGTT-
CAT; 5CMYC, 5¶-CAGGAACTATGACCTCGACTACGACT;
3CMYC, 5¶-TGTCTTGGCCAGCC; 5PDX1, 5¶-GGAGCAG-
TACTACGCGGCCA; 3PDX1, 5¶-TGGCCTTTCCACG-
CGTGA; 5LMX1A, 5¶-CCAAGTCTGTCTGCGAGGGC;
3LMX1A, 5¶-TGCAGGGCTTGGAGGATACTTC; 5HNF-3B,
5¶-GCCGGCCTGGGGATGAA; 3HNF-3B, 5¶-TGTTGGGG-
CTCTGCTGGATG; 5CDX1, 5¶-CAGGGCCCAGCATGCG;
and 3CDX1, 5¶-TCTTACCGCTGCCACCGC.
Microscopy Analysis
Forty-eight hours after transfection with fluorescent protein
expression constructs, TGP-61 cells grown on coverslips were
washed twice with cold PBS (Sigma) and fixed with 0.5%
paraformaldehyde for 30 min. Fixed cells were washed twice more
with cold PBS and incubated with 1 ng/mL bisbenzimide H 33258
(Sigma). Coverslips were mounted on slides using Vectashield
(Vector Labs) and viewed under a microscope (Leica DMIL) with
appropriate band-pass filters (Chroma) for ECFP, EYFP, and
Hoechst stain using a 63� objective. Images were captured with a
Hamamatsu Orca II cooled charge-coupled device camera and data
were analyzed with Metamorph (Molecular Devices) software to
create merged images. The final images were assembled in Adobe
Photoshop and Illustrator software to create the publication images.
Cell CountingAll cell counting experiments were done in triplicate, with data
reported as mean F SD. TGP61 cells (2.4 � 105) were plated on
six-well plates. The following day, the medium was changed to
fresh medium containing 5% charcoal-stripped serum. One set of
cells were trypsinized and counted on a hemacytometer, and the
remaining cells were treated with vehicle (DMSO) or 5 Amol/L
GSK3h inhibitor for 1, 2, and 3 d. Each day, the medium was
changed with fresh medium containing 5% charcoal-stripped
serum and treatment was continued with GSK3h inhibitor.
Flow CytometryAdherent cells were detached and collected with 0.25%
trypsin (Sigma). Cells were pelleted by centrifugation and
resuspended in propidium iodide staining buffer (sodium citrate
250 mg, 0.75 mL Triton X-100, propidium iodide 25 mg,
RNase A 5 mg, and distilled H2O to final volume of 250 mL)
and stored in the dark at 4jC until flow cytometry (<1 h). Cells
were then passed through a FACScan cytometer (Becton-
Dickinson) controlled with CellQuest software and the data
were analyzed with the ModFit software.
Statistical AnalysisMicrosoft Excel software was used for data management
(calculating mean and SD) and creating graphs. All luciferase
assays were done with triplicate plasmid transfections, with data
presented as mean F SD.
Chen et al.
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Disclosure of Potential Conflicts of InterestNo potential conflicts of interest were disclosed.
AcknowledgmentsWe thank Drs. Gregory Brent, Dean Yamaguchi, Steven Pandol, Ilya Gukovsky,and Matthias Stelzner at the West Los Angeles VA and David Geffen School ofMedicine at University of California at Los Angeles for valuable scientificdiscussions. We are grateful for critical reagents provided by Drs. Sunita Agarwal(National Institutes of Diabetes, Digestive and Kidney Diseases, Bethesda, MD),Randall T. Moon (University of Washington, Seattle, WA), Eric Vilain (Universityof California at Los Angeles, Los Angeles, CA), and Craig V. Smith (Universityof California at Los Angeles, Los Angeles, CA).
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Menin Is Essential for Wnt Signaling
Mol Cancer Res 2008;6(12). December 2008
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2008;6:1894-1907. Mol Cancer Res Gao Chen, Jingbo A, Min Wang, et al. Endocrine CellsMenin Promotes the Wnt Signaling Pathway in Pancreatic
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