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Molecular and Cellular Biology, January 1999, p. 704-713, Vol. 19, No. 1
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
The NeuroD1/BETA2 Sequences Essential for Insulin Gene
Transcription Colocalize with Those Necessary for Neurogenesis and
p300/CREB Binding Protein Binding
Arun
Sharma,1,
Melissa
Moore,2
Edoardo
Marcora,2
Jacqueline E.
Lee,2
Yi
Qiu,1
Susan
Samaras,1 and
Roland
Stein1,*
Department of Molecular Physiology and
Biophysics, Vanderbilt Medical Center, Nashville, Tennessee
37232,1 and
Molecular, Cellular and
Developmental Biology, University of Colorado, Boulder, Colorado
803092
Received 11 June 1998/Returned for modification 27 July
1998/Accepted 17 September 1998
 |
ABSTRACT |
NeuroD1/BETA2 is a key regulator of pancreatic islet morphogenesis
and insulin hormone gene transcription in islet 
cells. This factor
also appears to be involved in neurogenic differentiation, because
NeuroD1/BETA2 is able to induce premature differentiation of neuronal
precursors and convert ectoderm into fully differentiated neurons upon
ectopic expression in Xenopus embryos. We have identified amino acid sequences in mammalian and Xenopus NeuroD1/BETA2
that are necessary for insulin gene expression and ectopic
neurogenesis. Our results indicate that evolutionarily conserved
sequences spanning the basic helix-loop-helix (amino acids [aa] 100 to 155) and C-terminal (aa 156 to 355) regions are important for both
of these processes. The transactivation domains (AD1, aa 189 to 299;
AD2, aa 300 to 355) were within the carboxy-terminal region, as
analyzed by using GAL4:NeuroD1/BETA2 chimeras. Selective activation of
mammalian insulin gene enhancer-driven expression and ectopic
neurogenesis in Xenopus embryos was regulated by two
independent and separable domains of NeuroD1/BETA2, located between aa
156 to 251 and aa 252 to 355. GAL4:NeuroD1/BETA2 constructs spanning
these sequences demonstrated that only aa 252 to 355 contained
activation domain function, although both aa 156 to 251 and 300 to 355 were found to interact with the p300/CREB binding protein (CBP)
coactivator. These results implicate p300/CBP in NeuroD1/BETA2 function
and further suggest that comparable mechanisms are utilized to direct target gene transcription during differentiation and in adult islet cells.
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INTRODUCTION |
The mouse pancreas develops as an
outpocketing from the embryonic gut. Cells lining this evagination
differentiate and segregate into exocrine and endocrine tissues. Both
of these pancreatic tissues arise from a common, but limited, set of
multipotential endodermal precursors (2, 12, 29, 61). The
hormones produced by the endocrine pancreas appear sequentially during
development. Glucagon- and insulin-producing cells are first observed
at 9.5 days postcoitum in mice, followed by somatostatin- and then
pancreatic polypeptide-producing cells. The pancreas develops from
precursor cells that coexpress these hormonal gene products, with
expression both selectively increased and extinguished during islet
maturation, resulting in the production of the single hormone, 
(glucagon)-, (insulin)-, 
(somatostatin)-, and PP (pancreatic
polypeptide) cell types (20, 21, 42, 59). The endocrine
pancreas progenitors also coexpress a subset of markers of
neuroectodermal cell differentiation, such as tyrosine hydroxylase
(59), an enzyme in the catecholamine biosynthesis pathway.
This observation suggested that there may be shared lineage-specific
regulators within pancreatic and neuronal cells. Recently, this
relationship was assessed by analyzing the effect of elimination of
various genes encoding transcription factors enriched within both cell
types on pancreatic development. Such experiments have clearly
demonstrated that inactivation of the genes encoding PAX-4
(57), PAX-6 (58), Isl-1 (1), or NeuroD1/BETA2 (36) profoundly influences islet development. Although these studies showed that these proteins play important regulatory roles during development, the molecular mechanisms involved
are poorly understood.
NeuroD1/BETA2 is in the basic helix-loop-helix (bHLH) family of
transcriptional activators (26, 37) and functions in a complex with the more generally distributed E2A (i.e. E47, E12, E2-5)-encoded proteins (3, 10, 18, 54) and HEB-encoded proteins (41). Dimerization between bHLH proteins depends on the HLH region, while protein-DNA interactions are mediated by the
basic region. The presence of a tissue-enriched and a ubiquitously distributed bHLH factor in the activator complex is characteristic of
other tissue-specific members of this family, the best characterized of
which are involved in myogenic (17, 32) and neuronal
(8, 23, 56) differentiation. These activators bind to the
consensus sequence CANNTG (termed an E-box), with heterodimerization
increasing DNA binding and activation capacity (25, 32, 37).
NeuroD1/BETA2 is expressed in pancreatic islet endocrine cells
(34, 36), the intestine (34), the pituitary
(43), and a subset of neurons in the central and peripheral
nervous system (26). This factor was independently isolated
and characterized by its ability to activate neurite formation upon
ectopic expression in Xenopus embryos (termed NeuroD and
referred to here as NeuroD1 [26]), and insulin
reporter gene transcription in transfected cells (termed BETA2
[37]). NeuroD1/BETA2 also stimulates secretin (34) and proopiomelanocortin (POMC [43])
transcription in the intestine and pituitary gland, respectively.
Activation by NeuroD1/BETA2 is potentiated by the p300/CREB binding
protein (CBP) coactivator (35, 45). Although the exact
mechanism involved in p300/CBP-mediated transcription is unclear, it
may result from bridging through direct interactions the activator to
the basal transcriptional machinery and/or from promotion of a
transcriptionally active state to targeted genes through its intrinsic
histone acetyltransferase activity (15, 55). Since p300/CBP
also modulates the activity of a number of key activators involved in
regulating cellular proliferation and differentiation (15,
55), including the myogenic bHLH factors (16, 50, 64),
its association with NeuroD1/BETA2 may be important for
transcriptional signaling during development and in the adult.
Gene targeting experiments established an important role for
NeuroD1/BETA2 in pancreatic development. NeuroD1/BETA2
/
mice have a marked reduction in insulin-producing cells and fail to
develop mature islets (25a, 36). In addition, secretin- and
cholecystokinin-producing enteroendocrine cells were not present in
homozygous mutant mice (36). These animals develop severe diabetes and die within a few days of birth. In contrast, homozygous E2A (5, 65, 66) or HEB (65) null mice do not
display any change in endocrine pancreas morphology or function
(22, 52). The nervous system also appears to be normal at
the gross level in NeuroD1/BETA2/ mice,
presumably due to the presence of a compensatory factor.
Collectively, these results indicated that NeuroD1/BETA2 is required
during the development of specialized pancreatic and enteroendocrine
cell types arising from gut endoderm, as well as being involved in
differentiated gene product expression (i.e., insulin, secretin, and
POMC). Furthermore, because both NeuroD1/BETA2 (26) and
NeuroD2 (31) can convert epidermal cells to neurons, NeuroD-like factors also appear to be important in the development of
the nervous system. In this study, the amino acid sequences of
NeuroD1/BETA2 that are necessary for insulin gene transcription and
neurogenesis were identified. The stimulatory properties of the
mammalian and Xenopus NeuroD1/BETA2 proteins were compared. These proteins share approximately 71, 96, and 85% identity in their
N-terminal (amino acids [aa] 1 to 99), bHLH (aa 100 to 155), and
C-terminal (aa 156 to 355) regions, respectively (26, 31, 37). The sequences spanning the C-terminal region of
NeuroD1/BETA2 were required for insulin gene activation and
neuronal differentiation. Stimulation appears to be mediated by the
p300/CBP coactivator through contacts within aa 156 to 251 and aa 300 to 355. We propose that the interaction of p300/CBP with NeuroD1/BETA2
plays an important role in E-box activation by NeuroD1/BETA2 in adult
islet cells and during differentiation.
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MATERIALS AND METHODS |
DNA constructs.
The hamster BETA2 (37) and
Xenopus NeuroD (26) protein coding sequences used
in constructing the full-length and deletion mutant GAL4 chimeras were
derived by PCR. Amplification was performed according to the method of
Saiki et al. (49) with Thermus aquaticus DNA
polymerase (Perkin-Elmer Cetus). The resulting BETA2 and
Xenopus NeuroD sequences were ligated into the simian virus
40 (SV40) promoter-enhancer-driven GAL4 expression plasmid, pSG424
(28), to create in-frame GAL4-fusion proteins. Each
construct is named according to the N- and C-terminal amino acid
sequence of BETA2 and Xenopus NeuroD present in the
construct. The BETA2 and Xenopus NeuroD sequences were
subcloned into pCS2+NLSMT (60), which contains the simian
cytomegalovirus (CMV) promoter and SV40 T-antigen nuclear localization
signal fused to six copies of the myc epitope recognized by the 9e10
monoclonal antibody. The inserts were cloned in frame and downstream of
the myc sequences. The structure of all plasmid constructs was
confirmed by sequencing. The E47 activation domain (AD) mutants, AD1,
AD2, and AD1/AD2, were described previously (39). The
activation domain activity of E47 has been significantly compromised by
a change in aa 19 (Leu to Arg) and aa 22 (Phe to Arg) in the AD1 mutant
and aa 337 (Val to Glu) and aa 338 (Leu to Arg) in the AD2 mutant. The
wild-type and mutant E47 cDNAs were expressed from the SV40
enhancer-promoter in pJ3
(30). The p300 dl10 mutant
(deletion of aa 1680 to 1811) (27), p300:herpes virus acidic
activation region (VP16) fusion (p300 Q:VP16) (aa 1945 to 2377)
(45), insulin FF chloramphenicol acetyltransferase (CAT)
(19), and (GAL4)5 E1bCAT reporter
(28) constructs have been described previously.
Cell culture and transfections.
Monolayer cultures of
BETATC3, baby hamster kidney (BHK), HeLa, and HIT T-15 2.2.2 cells were
maintained as described previously (39). The transfections
were performed by using either the calcium-phosphate coprecipitation
procedure (HIT T-15, BHK, and HeLa) (62) or the
electroporation procedure (BETATC3) (47). A luciferase
(LUC) reporter gene recovery marker, pSV2 LUC (13), was
cotransfected with the CAT reporter plasmid. Four hours after the
addition of the calcium-phosphate DNA precipitate, BHK and HIT T-15
cells were treated with 20% glycerol for 2 min. The transfections in TC3, BHK, HeLa, and HIT T-15 cells with the GAL4:ND plasmids (or the
GAL4 DNA binding vector alone [termed GAL4 1-147]) (8 µg) also
included (GAL4)5 E1bCAT (2 µg), and a luciferase (LUC) reporter gene recovery marker, pSV2 LUC (1 µg); the transfection analysis (total DNA concentration 10 µg) in HeLa cells of the CMV
NeuroD1 constructs was conducted with (or without) the E47 expression
plasmid (2 µg), FF CAT (1 µg), and pSV2 LUC (1 µg). Cells were
harvested 40 to 48 h after transfection. The CAT activity from the
reporter plasmid was normalized to the LUC activity of the
cotransfected internal control plasmid. LUC and CAT enzymatic assays
were performed as described by de Wet et al. (13) and Nordeen et al. (38), respectively. Each experiment was
repeated several times with at least two different plasmid preparations.
Western blot analysis.
HeLa nuclear extracts were prepared
from transfected cells as described previously (51). Fifty
micrograms of protein extract was resolved on a sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gel (12.5%
polyacrylamide) and electrotransferred to Immobilon polyvinylidene
difluoride membrane (Millipore, Bedford, Mass.). The membrane was
probed with the monoclonal anti-myc tag 9e10 antibody (ATCC CRL1729).
The positions of bound antibodies were detected by autoluminography
with the ECL (enhanced chemiluminescence) detection kit (Amersham).
Ectopic neurogenic assay by RNA injection into Xenopus
laevis embryos.
Albino embryos were obtained by in vitro
fertilization, dejellied with 2% cysteine 1 h later, and injected
at the two-cell stage with in vitro-synthesized, capped, and
polyadenylated RNAs. All RNAs were synthesized from CS-2 vectors
(60) by using SP6 polymerase. Microinjection of RNA was
performed by injection of approximately 4 to 5 nl of RNA (100 pg/nl)
into one cell of two-cell stage Xenopus embryos at two
positions in the animal hemisphere. The injected embryos were allowed
to develop in 0.1× modified Barth's saline until they reached
between stages 20 and 24. Embryos were fixed in Dent's fixative (20%
dimethylsulfoxide, 80% methanol) and stained with rabbit anti-N-CAM
antibody (1:500 dilution) (6) as described previously
(26). Primary antibody was detected with alkaline
phosphatase-conjugated goat anti-rabbit secondary antibody (diluted
1:2,000; Boehringer Mannheim).
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RESULTS |
The NeuroD1/BETA2 activation domains are located C terminal to the
bHLH region.
To begin to map the domain or domains of
NeuroD1/BETA2 that mediate activation, we employed a GAL4 DNA-binding
domain (DBD)-dependent reporter system, in which regions of hamster
NeuroD1/BETA2 were fused to the DBD of yeast GAL4. The GAL4 protein
fusion plasmids, together with a CAT reporter plasmid containing five
GAL4 DNA binding sites upstream of the E1b TATA, were cotransfected
into cell lines that express both insulin and NeuroD1/BETA2 (HIT T-15 and TC3) and those that do not (BHK and HeLa). CAT enzyme activity from the GAL4 chimeras was normalized to the activity of the
cotransfected internal control plasmid, pSV2 LUC.
In general, the expression patterns of the GAL4:NeuroD1/BETA2 (GAL4:ND)
chimeras were similar between different cell lines (Fig.
1). We observed that while constructs
containing only the N-terminal region or both the N-terminal and bHLH
regions were inactive [see GAL4:ND(1-99) and GAL4:ND(1-155)], those
that contained the C-terminal region were effective activators [see
GAL4:ND(156-355), GAL4:ND(189-355), and GAL4:ND(239-355)]. Gel
shift analysis also revealed that similar relative amounts of each GAL4
fusion protein were synthesized between cell lines (data not shown).
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FIG. 1.
The transcriptional activation domains of
Xenopus and hamster NeuroD1/BETA2 are located within
C-terminal region sequences. (A) Schematic representation showing the
percentage of identity between the Xenopus and hamster
NeuroD1/BETA2 proteins. The percentages of identity between the
hamster, mouse, and human NeuroD1/BETA2 proteins are 97 and 100%,
respectively (31, 37). The wild-type and mutant hamster (B)
and Xenopus (C) GAL4:ND fusion proteins were cotransfected
into NeuroD1/BETA2-expressing (HIT T-15 and TC-3) and nonexpressing
(HeLa and BHK) cells with the (GAL4)5 E1b CAT reporter
construct and a recovery marker for transfection efficiency, pSV2 LUC.
The amino acids of NeuroD1/BETA2 present in the GAL4 fusion are in
parentheses. The normalized activity for each GAL4:ND construct is
presented ± the standard error relative to the plasmid containing
only the GAL4 DBD [GAL4(1-147)]. ND, not determined.
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The results suggested that C-terminal region sequences from 189 to 355 spanned the transactivation domains of NeuroD1/BETA2.
Further analysis
indicated that two distinct activation domains
were located within this
region, between aa 189 and 299 (termed
activation domain 1 [AD1]) and aa 300 and 355 (termed AD2). Because
GAL4:ND(189-355) and GAL4:ND(239-355) had comparable activities
(Fig.
1B), we considered that the amino-terminal boundary of AD1
might be
closer to aa 239. However, GAL4:ND(239-299) was found
to be much less
active than GAL4:ND(189-299) (Fig.
1B), indicating
that aa 189 to 238 also contribute to AD1 activation. The GAL4
constructs spanning the
homologous region of
Xenopus NeuroD1 also
showed a similar
selective expression pattern (Fig.
1C and Table
1). These results suggest that the
mechanisms important in transactivation
domain function are conserved
between the
Xenopus and hamster
NeuroD1/BETA2 proteins.
The C-terminal domain sequences of NeuroD1/BETA2 mediate insulin
gene transcription.
We next sought to identify the sequences in
NeuroD1/BETA2 that were necessary for insulin E-box
element-mediated transcription in HeLa cells. NeuroD1/BETA2
specifically stimulates transcription by binding to the E-box element
at bp 
239 to 228 within the insulin enhancer-driven FF CAT
construct, which contains from bp 247 to bp 197 of the rat insulin
I gene (19, 39). Because HeLa cells lack NeuroD1/BETA2, as
well as other -cell-enriched transcription factors important for
insulin gene expression (10, 11, 19, 24, 40, 54, 62), this
system provides the opportunity to evaluate the transactivation
potential of mutant proteins in isolation. The bHLH region was retained
in each of the NeuroD1/BETA2 mutant constructs, since it has been
clearly demonstrated to be essenconstructs, since it has been clearly demonstrated to be essential for dimerization and E-box DNA binding within this family of proteins (9, 25, 33). A myc epitope tag and nuclear localization signal were inserted at the N terminus of
each NeuroD1/BETA2 protein to facilitate monitoring of protein expression levels and direct appropriate localization. These
modifications do not affect the function of the protein (26,
31).
HeLa cells were transfected with CMV-driven expression vectors encoding
wild-type NeuroD1/BETA2 and C-terminally truncated
constructs that are
missing sequences from both AD1 and AD2 [ND(1-155)
and ND(1-251),
respectively] or only AD2 [ND(1-299)]. Insulin
gene activation from
FF CAT was analyzed for each NeuroD1/BETA2
construct in the presence or
absence of the E2A-encoded protein,
E47. Activation was not observed in
cells transfected only with
the NeuroD1/BETA2 construct spanning the
N-terminal region, ND(1-155),
whereas full-length NeuroD1/BETA2
effectively stimulated FF CAT
expression (Fig.
2). In the absence of AD2, ND(1-299)
retained
37% of NeuroD1/BETA2 activity, while the AD1/AD2 mutant,
ND(1-251),
retained 10%. In addition, removal of the region of aa 1 to 99
from ND(1-251) did not significantly affect activity [see
ND(100-251)
in Fig.
2]. Western blotting also revealed that similar
amounts
of each NeuroD1/BETA2 protein were synthesized in transfected
cells (Fig.
3). The same activation
pattern was also obtained
with comparable regions of
Xenopus
NeuroD1/BETA2 (data not shown).
These results are in general
agreement with the mapping of the
transcriptional activation domains to
aa 189 to 299 and aa 300
to 355. Although we did not expect to find any
stimulatory activity
from ND(1-251), since a GAL4 fusion construct
spanning the C-terminal
activation domain region sequences of
this NeuroD1/BETA2 construct
was inactive in HIT T-15 and
HeLa cells [see GAL4:ND(156-251)
in Fig.
4]. Together, these observations imply
that the activation
domain functions of NeuroD1/BETA2 are important,
but not essential,
for insulin E-box-stimulated transcription.
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FIG. 2.
Insulin E-box-driven expression is mediated by sequences
within the C-terminal region of NeuroD1/BETA2. Diagrammatic
representation of hamster NeuroD1/BETA2 showing the bHLH (aa 100 to
155), AD1 (aa 189 to 299), and AD2 (aa 300 to 355) domains. HeLa cells
were cotransfected with the insulin enhancer-driven FF CAT reporter,
wild-type or mutant NeuroD1/BETA2 (termed ND), E47, and the recovery
marker, pSV2 LUC. FF CAT contains five copies of the bp 247 to 197
region of the rat insulin I gene and spans an essential E-box at bp
239 to 228 (19). The ND sequences in the CMV
enhancer-driven plasmid are in parentheses. The normalized results ± standard error are expressed relative to FF CAT alone.
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FIG. 3.
Western analysis of NeuroD1/BETA2 in transfected HeLa
cells. Nuclear extracts were prepared from HeLa cells transfected with
a myc-tagged wild-type or mutant ND expression plasmid. Fifty
micrograms of protein was resolved on a 12.5% acrylamide-SDS gel and
transferred onto an Immobilon polyvinylidene difluoride membrane. The
membrane was probed with the monoclonal anti-myc tag 9e10 antibody, and
the bands were detected by autoluminography. The arrows denote the
transfected ND proteins.
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FIG. 4.
The C-terminal region sequences of hamster NeuroD1/BETA2
found between aa 252 and 355, but not aa 156 and 251, contain a
functional transcription activation domain. The GAL4:ND(156-251),
GAL4:ND(252-355), and GAL4(1-147) constructs were cotransfected into
HIT T-15 and HeLa cells with (GAL4)5 E1b CAT and pSV2 LUC.
The amino acids of hamster NeuroD1/BETA2 present in the GAL4
fusion are in parentheses. The normalized activity for each GAL4:ND
construct is presented ± standard error relative to
GAL4(1-147).
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E47 stimulated the activity from each of the
NeuroD1/BETA2 expression plasmids, yet did not effect FF
CAT expression alone
(Fig.
2) (
39). Since dimerization
between NeuroD1/BETA2 and
the E2A (
3,
10,
18,
54)- or
HEB (
41)-encoded protein
is required for E-box binding
(
37), these results indicated
that the levels of the
generally distributed partner were limiting
in cells transfected with
NeuroD1/BETA2 alone. To determine if
the activation domains of the E2A
and HEB proteins were also important
in FF CAT stimulation, mutants
within these conserved regions
of the E47 protein were cotransfected
with ND(1-155) and ND(1-251).
The two distinct activation domains of
E47 are located between
aa 1 to 83 (termed AD1) (
4,
30) and
aa 345 to 411 (AD2) (
4,
46). FF CAT activity was reduced by
approximately 50% in the
AD1 or AD2 mutants of E47, and the AD1/AD2
double mutant activity
was reduced to near the level of the
NeuroD1/BETA2 construct transfected
alone (Fig.
5). These results indicate that E-box
stimulation
is also mediated by the activation domains in the E2A- and
HEB-encoded
proteins.
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FIG. 5.
The transactivation domains of E47 contribute to
activation with NeuroD1/BETA2. Schematic representations of the
wild-type and mutant E47 constructs indicating the positions of the AD1
(aa 1 to 83 [4, 30]), AD2 (aa 345 to 411 [4,
46]), and bHLH (aa 539 to 597) regions. The dysfunctional
activation domain is missing in the E47 mutant diagram. HeLa cells were
cotransfected with FF CAT, ND(1-155) or ND(1-251), wild-type or
mutant E47, and pSV2 LUC. The normalized results ± standard error
are expressed relative to that of FF CAT alone.
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The p300/CBP coactivator interacts with sequences in
NeuroD1/BETA2 essential for activation.
Recent studies have
demonstrated that p300/CBP can bind to and potentiate the activity of
NeuroD1/BETA2 (35, 45) and the HEB- and E2A-encoded proteins
(16, 45). p300/CBP can physically and functionally interact
with the bHLH (35) and C-terminal region (aa 156 to 355)
(45) of NeuroD1/BETA2. Since the results described above
indicated that aa 156 to 355 were more important in selective
activation, we sought to define more precisely the sequences within
this region that were required for binding to p300/CBP. In this
analysis, the abilities of GAL4:ND fusion proteins spanning aa 156 to
251, 189 to 299, and 300 to 355 to functionally interact with p300/CBP
or the p300 mutant (p300 dl10) were compared to that of
GAL4:ND(156-355) in HIT T-15 cells. Although p300 dl10 lacks the
histidine- and cysteine-rich region (termed C/H3) between aa 1680 and
1811 which is important in adenovirus E1A binding (Fig.
6A), it can functionally substitute for
p300 in assays with NeuroD1/BETA2 (45). p300 dl10 (Fig. 6B)
and p300 (data not shown) stimulated the activity of GAL4:ND(156-251)
and GAL4:ND(300-355) to the same level as the GAL4:ND(156-355)
positive control. However, the activity of GAL4:ND(189-299) was not
affected to the same extent.
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FIG. 6.
p300/CBP interacts with two distinct regions within
NeuroD1/BETA2. (A) Schematic representation of p300/CBP with the
cysteine/histidine (C/H1, C/H2, and C/H3)-, bromo-, and glutamine-rich
(Q-rich) domains. The numbers correspond to the amino acid residues in
human p300; CBP has a similar organization (2,440 residues) (15,
55). The regions in p300/CBP required for binding to adenoviral
E1A (14) and NeuroD1/BETA2 (45) are shown. HIT
T-15 cells were transfected with a hamster GAL4:ND construct,
(GAL4)5 E1b CAT, pSV2 LUC, and (B) p300 dl10 or (C) p300
Q:VP16. The aa 1680 to 1811 are deleted from the p300 dl10 mutant; p300
Q:VP16 is an in-frame fusion between the p300 Q (aa 1945 to 2377)
domain and the herpesvirus acidic activation region (VP16). Stimulation
of the CAT reporter due to the interaction between p300 and
NeuroD1/BETA2 is shown as fold activation (± standard error).
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We have recently shown that NeuroD1/BETA2 binds to the glutamine-rich
region of p300/CBP located between aa 1945 and 2377
(termed the Q
domain) (
45). To determine if this region of p300/CBP
also
binds to the 156 to 251 and 300 to 355 (AD2) domains of NeuroD1/BETA2,
we analyzed whether a p300 Q:VP16 activation domain fusion protein
could interact with and stimulate GAL4:ND(156-251) and
GAL4:ND(300-355)
activity. The level of p300 Q:VP16 stimulation was
comparable
to that observed with GAL4:ND(156-355) (Fig.
6C). In
contrast,
p300 Q:VP16 had only a minimal effect on GAL4:ND(189-299)
activity.
Together, these results strongly suggest that interactions
between
the Q region of p300/CBP and aa 156 to 251 and 300 to 355 (AD2)
of NeuroD1/BETA2 are important for
activation.
NeuroD1/BETA2-induced neurogenesis is mediated by the C-terminal
region sequences required for insulin E-box-directed
transcription.
Ectopic expression of NeuroD1/BETA2 (26)
or NeuroD2 (31) in developing Xenopus embryos
results in cell fate conversion of ectodermal cells to neurons in the
epidermis. To determine if the neurogenic activity of
NeuroD1/BETA2 involved the same regions of the protein found
to be important in stimulating insulin E-box transcription, we injected
Xenopus embryos at the two-cell stage with
Xenopus NeuroD1/BETA2 RNA encoding the wild-type protein and
mutants either capable or incapable of inducing insulin gene expression. Each construct contained the NeuroD1/BETA2 bHLH region and
a nuclear localization signal. Injections were conducted on one side of
the embryo, with the other side serving as a control. The neurogenic
conversion activity of the NeuroD1/BETA2 constructs was evaluated by
their ability to induce expression of a neural cell-specific marker in
Xenopus, neural cell adhesion molecule (N-CAM)
(26), by whole-mount immunohistochemistry. An anti-myc tag
antibody, 9e10, was used to confirm that most of the ectodermal cells
on the injected side of the embryo expressed the myc-tagged BETA2
fusion protein (data not shown).
The regions of NeuroD1/BETA2 that are important for regulating insulin
E-box transcription were also found to be necessary
for ectopic
neuronal development. Thus, neurogenic activity was
dependent upon the
C-terminal region, because constructs encoding
the sequences from 1 to
251 and 1 to 299 induced N-CAM staining,
while the 1 to 155 construct
did not (Fig.
7). The N-CAM staining
pattern for XND 1-155 was indistinguishable from that in wild-type
uninjected embryos (data not shown). As in the case of XND (Fig.
7)
(
26), the ectopic neurons induced by the XND mutants were
confined to a subpopulation of ectodermal cells, as shown by the
spotty
N-CAM-positive staining pattern.
View larger version (58K):
[in this window]
[in a new window]
|
FIG. 7.
Ectopic neurogenesis is induced by the regions of
NeuroD1/BETA2 essential in insulin E-box activation. (A) Stage 2 Xenopus embryos were injected with wild-type or mutant
Xenopus NeuroD1/BETA2 RNA. At stage 24, the embryos were
stained with anti-N-CAM antibody and localized with alkaline
phosphatase-conjugated secondary antibody. The + corresponds to
the side on which the Xenopus NeuroD1 RNA was injected (the
spotty pattern indicates N-CAM-positive neuronal processes) and corresponds to the uninjected side.
|
|
Because XND 100-251 induced neurogenesis (Fig.
7) and insulin gene
transcription (Fig.
2), we concluded that the N-terminal
region was not
important in these responses, nor was the bHLH
alone sufficient. These
results also indicated that the sequences
between 156 and 251 of
NeuroD1/BETA2 alone could mediate these
activities. Toward this end, we
analyzed whether removal of these
sequences influenced either insulin
E-box-driven transcription
or neurogenic activation.
XND
156-251 was capable of stimulating
both insulin gene
transcription (Fig.
2) and N-CAM staining (Fig.
7). This
NeuroD1/BETA2 mutant expression construct possesses activation
domain function, as concluded from an analysis of GAL4:ND(252-355)
activity in HIT T-15 and HeLa cells (Fig.
4). In contrast, XND
100-251
and XND 1-251 do not appear to have a functional activation
domain
[see GAL4:ND(156-251) in Fig.
4].
In contrast to the insulin E-box-driven assay, we were unable to
quantitate differences in neurogenic potential between the
NeuroD1/BETA2 mutants upon ectopic expression in
Xenopus
embryos
(Fig.
8). This may be reflective
of the significance of the C-terminal
regulatory regions in activating
E-box-mediated transcription
of an insulin versus neuronal target gene,
or may be simply a
difference in the sensitivity of the assays.
Importantly, these
assays indicate that activation of both the
neurogenic and the
islet transcription programs is mediated by the same
two distinct
regions of NeuroD1/BETA2. Furthermore, the interaction of
the
p300/CBP coactivator with these regulatory regions, which are
located between aa 156 to 251 and 252 to 355, could play an essential
role in NeuroD1/BETA2 transcriptional activity.
View larger version (10K):
[in this window]
[in a new window]
|
FIG. 8.
Summary of neurogenic conversion, transactivation, and
p300/CBP binding activities of NeuroD1/BETA2. Diagrammatic
representation of NeuroD1/BETA2 showing the bHLH (aa 100 to 155), AD1
(aa 189 to 299), and AD2 (aa 300 to 355) domains. p300/CBP binding
region sequences were obtained from the stimulation of GAL4:ND
construct activity by p300 dl10 (Fig. 5B; GAL4:ND(156-251) and
GAL4:ND(300-355) showed 135 and 118% of GAL4:ND(156-355) activity,
respectively. The neurogenic activity of the wild-type and mutant XND
constructs in injected embryos was determined by immunohistochemical
staining for N-CAM expression. There was no significant quantitative
difference between the active constructs in this analysis (Fig. 7).
+++, wild-type ND activity; , no detectable conversion.
Transactivation by ND of the insulin E-box reporter, FF CAT, was
described in the legend to Fig. 2. In the transactivation, +++
represents 100 to 66% of that obtained with wild-type ND, ++
represents 65 to 33%; + represents 32 to 5%, and represents
no detectable activity.
|
|
| |
DISCUSSION |
In this study, we examined the basis for transcriptional
activation by NeuroD1/BETA2 in islet cells and the developing
nervous system. Our objective was to identify and functionally
characterize the domain or domains of NeuroD1/BETA2 that were important
in these processes. Although we found that the bHLH region alone was
unable to stimulate insulin E-box or neurogenic activation, C-terminal
region sequences from 156 to 355 of the Xenopus or mammalian
protein, when linked to the bHLH region, were active. Mutational
analysis demonstrated that selective activation by the C-terminal
region was mediated by two functionally independent domains, which
spanned sequences 156 to 251 and 252 to 355. These results suggest that
similar mechanisms are utilized by NeuroD1/BETA2 to
direct E-box-mediated transcription of important regulatory genes
involved in neuronal differentiation and adult islet -cell function. Since p300/CBP, an essential coactivator of NeuroD1/BETA2 (35, 45), interacted with each domain (i.e., aa 156 to 251 and aa 300 to 355) associated with selective activation, its
recruitment appears to be required for activity.
Our initial observation was that the transactivation domain function of
mammalian and Xenopus NeuroD1/BETA2 was located within aa
189 and 355, as analyzed with GAL4:ND chimeras. More detailed analysis
demonstrated that this region contained two activation components, with
AD1 (aa 189 to 299) more active than AD2 (aa 300 to 355) in islet BETA
cells. AD1 function was severely compromised in GAL4:ND(156-251) and
GAL4:ND(239-299), suggesting that NeuroD1/BETA2 sequences
within each mutant played an important role in defining AD1 activation.
To examine the role of the AD1 and AD2 regions in transcriptional
stimulation of a physiologically relevant target gene, activation
domain mutants within the mammalian and Xenopus NeuroD1/BETA2 protein were analyzed for their ability to activate insulin E-box-driven enhancer expression. The bHLH region was present
in each mutant construct, while N-terminal sequences preceding the bHLH
domain as well as selected portions of the C-terminal region were
removed. The data indicate that C-terminal region sequences of
NeuroD1/BETA2, which lack a functional activation domain, mediate E-box
activation. Thus, while NeuroD1/BETA2 constructs missing AD2
[ND(1-299)] and AD1 [ND(1-251) or ND(100-251)] function were
less effective than the wild type, they were significantly more active
than the N-terminal region construct [ND(1-155)] (Fig. 2).
Stimulation from each mutant was potentiated upon cotransfection with
E47, a heterodimeric partner in the insulin E-box activator complex
(3, 10, 18, 54), implying that mutagenesis affected only the
activation properties of NeuroD1/BETA2 and not its dimerization and DNA
binding properties.
Strikingly, neurogenic activation was mediated by the same regions of
NeuroD1/BETA2 required in insulin E-box activation (Fig. 8). These
results suggest the direct involvement of 156-to-355 region sequences
in stimulating transcription from genes important in neurogenic
differentiation and adult islet gene expression. The NeuroD1/BETA2 bHLH
domain is unable to mediate selective activation in the
absence of C-terminal region sequences, yet is still required for
up-regulation of transcription of target genes by its ability to direct
both heterodimerization with the E47, E12, or HEB protein and
E-box-specific binding.
The sequences from 156 to 251 and 252 to 355 of NeuroD1/BETA2
defined separable and independently acting stimulatory regions, with
only aa 252 to 355 containing activation domain properties. Interestingly, p300/CBP interacted within both the 156 to 251 and 252 to 355 regions, indicating that its recruitment was necessary for
activation. Mutoh et al. (35) have recently shown that
p300/CBP can also interact with the bHLH region of NeuroD1/BETA2. While our results demonstrate that the association of p300/CBP with the bHLH
region is not sufficient for insulin gene or neurogenic activation, it
is possible that this interaction is important in another context.
Notably, the association of p300/CBP with the myogenic bHLH activator,
MyoD, appears to be required for E-box activation and differentiation
(44), and this key regulatory factor also has binding sites
for p300/CBP within both its activation domain (50, 64) and
bHLH (16) regions.
The high degree of sequence identity among
NeuroD1/BETA2-related proteins (i.e., Nex1
[7], NeuroD2 [31], and NeuroM
[48]) within their bHLH and C-terminal region
sequences suggests that p300/CBP is also likely to be essential for
their activation as well. Neurogenic activation by NeuroD1/BETA2
(26) or NeuroD2 (31) converts only a
subpopulation of ectodermal cells to neurons (represented by the spotty
N-CAM expression pattern in Fig. 7), suggesting that other
cell-restricted factors act in conjunction with this factor to mediate
neurogenesis. The ubiquitously distributed p300/CBP protein may
facilitate regulated E-box transcription in ectodermal cells, as well
as islet endocrine cells, by promoting interactions between
NeuroD1/BETA2 and other tissue-enriched regulators. Recent studies have
clearly demonstrated that p300/CBP utilizes such a mechanism to
modulate the activity of a number of other key activators, including
those involved in regulating cellular proliferation and differentiation
(15, 55).
Our results suggest that the mechanisms important in
NeuroD1/BETA2 activation of E-box-driven genes involved in
neuronal development are closely related to those required for insulin
gene expression in islet cells and are likely related to islet
endodermal cell differentiation. Furthermore, that stimulation is
linked to the transcriptional signaling properties of p300/CBP. Results
consistent with this hypothesis were recently obtained in both
Caenorhabditis elegans (53) and mice
(63), when it was shown that p300/CBP was essential for
cellular differentiation. In mice lacking NeuroD1/BETA2, there is a
severe effect on islet endodermal cell development (25a,
36), with specific losses in islet -, -, and -cell numbers of nearly 75, 40, and 20%, respectively. Experiments are in
progress to test if NeuroD1/BETA2-mediated differentiation of islet
cells involves the recruitment of p300/CBP.
| |
ACKNOWLEDGMENTS |
We thank Mina Peshavaria, Gladys Teitelman, and Kevin Gerrish for
constructive criticism of the manuscript, Lauren Snider and Kristin
Swihart for technical assistance; and Ming-Jer Tsai for generously
providing the hamster BETA2 cDNA.
This work was supported by grants from the National Institutes of
Health (RO1 DK49852 to R.S., NIH RO1 N535118 to J.E.L., and DK7061
training grant to S.S.), American Diabetes Association (to A.S.), and
Juvenile Diabetes Foundation (398212 to S.S.). Partial support was also
derived from the Vanderbilt University Diabetes Research and Training
Center Molecular Biology Core Laboratory (Public Health Service grant
P60 DK20593 from the National Institutes of Health).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular Physiology and Biophysics, Vanderbilt Medical Center,
Nashville, TN 37232. Phone: (615) 322-7026. Fax: (615) 322-7236. E-mail: roland.stein{at}mcmail.vanderbilt.edu.
Present address: Joslin Diabetes Center, Boston, MA 02215.
| |
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Molecular and Cellular Biology, January 1999, p. 704-713, Vol. 19, No. 1
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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