Identification of cis- and trans-Active Factors Regulating Human Islet Amyloid Polypeptide Gene Expression in Pancreatic beta -Cells*

(Received for publication, December 17, 1996, and in revised form, February 4, 1997)

Maynard D. Carty Dagger , Jay S. Lillquist Dagger , Mina Peshavaria §, Roland Stein § and Walter C. Soeller Dagger

From the Dagger  Department of Molecular Sciences, Central Research Division, Pfizer, Inc., Groton, Connecticut 06340 and the § Department of Molecular Physiology and Biophysics, Vanderbilt University Medical Center, Nashville, Tennessee 37232

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
Note Added in Proof
REFERENCES


ABSTRACT

Islet amyloid polypeptide is expressed almost exclusively in pancreatic beta - and delta -cells. Here we report that beta  cell-specific expression of the human islet amyloid polypeptide gene is principally regulated by promoter proximal sequences. The sequences that control tissue-specific expression were mapped between nucleotides -2798 and +450 of the human islet amyloid polypeptide (IAPP) gene using transgenic mice. To localize the cis-acting elements involved in this response, we examined the effects of mutations within these sequences using transfected islet amyloid polypeptide promoter expression constructs in pancreatic beta  cell lines. The sequences between -222 and +450 bp were found to be necessary for beta  cell-specific expression. Linker-scanning mutations of the 5'-promoter proximal region defined several key distinct control elements, including a negative-acting element at -111/-102 base pairs (bp), positive-acting elements like the basic helix-loop-helix-like binding site at -138/-131 bp, and the three A/T-rich, homeobox-like sites at -172/-163, -154/-142, and -91/-84 bp. Mutations within any one of these elements eliminated transcriptional expression by the promoter. Gel mobility shift assays revealed that the PDX-1 homeobox factor, which is required for insulin gene transcription in beta  cells, interacted specifically at the -154/-142- and -91/-84-bp sites. Since PDX-1 is highly enriched in beta  and delta  cells, these results suggest that this factor plays a principal role in defining islet beta  cell- and delta  cell-specific expression of the IAPP gene.


INTRODUCTION

Amyloid deposits are a common feature in individuals with non-insulin-dependent diabetes mellitus (NIDDM)1 (1). Islet amyloid polypeptide (IAPP) or amylin, which is a member of the calcitonin gene family (2), is the most abundant component of pancreatic amyloid. This 37-amino acid peptide is normally co-secreted with insulin from beta  cells (3) and is also expressed in a subset of islet delta  cells (4).

The physiological role IAPP plays normally or in NIDDM is unclear. As a consequence of its abilities to inhibit insulin secretion in isolated islets (5, 6) and to counteract insulin action in peripheral tissues (7), IAPP has been proposed to play an important role in regulating plasma glucose levels in mammals. The formation of diabetes-associated amyloid deposits appears to be related to the primary sequence of IAPP, as only certain species, which include primates and cats, encode a hydrophobic amyloidogenic core of amino acids (amino acids 20-29) that allow fibril formation (8). However, since amyloid deposits are not normally found in nondiabetic individuals, other factors must also contribute to disease formation. It has been proposed that elevated expression of IAPP may be one such factor (9).

Experiments conducted by German et al. (10) indicate that transcription of the IAPP gene is controlled by a factor that is also involved in beta  cell-specific expression of the insulin gene. Thus, it was demonstrated that the -176 to -117-bp region of the human IAPP gene could direct cell-specific transcription from a heterologous promoter in transient transfection assays with characteristics similar to the -247 to -197-bp region of rat insulin I gene. This region of the insulin gene I is regulated by A/T-rich elements and a basic helix-loop-helix (B-HLH) factor binding site (10, 11). The regulatory factors that bind to and activate the A/T-rich elements appear to be shared between the IAPP and insulin genes (10).

The PDX-1 homeoprotein, which is selectively expressed in islet beta  and delta  cells as well as specific enteroendocrine cell-types in the duodenum (12), activates expression from A/T-rich elements of the insulin gene (13-16). Interestingly, homozygous PDX-1 mutant mice fail to form a pancreas (17, 18), and the enteroendocrine cells in the duodenum are also affected (18). Recently, two laboratories have identified factors that appear to regulate expression from the promoter proximal A/T-rich elements in the IAPP gene. However, the conclusions drawn from these studies are quite different. Bretherton-Watt et al. (19) concluded that PDX-1 interacts with these A/T-rich elements in beta  cells, whereas Wang and Drucker (20) demonstrated that a distinct factor, the LIM homeodomain protein Isl-1, can activate IAPP expression.

In the present study, we have examined the effects of mutations throughout the human IAPP gene on beta  cell-type-specific expression. This resulted in the identification of a minimal control region spanning sequences from -222 to +450 bp, which was regulated by a number of distinct cis-acting elements. The positive control elements included the A/T-rich elements at -172/-163, -154/-142, and -91/-84 bp and a B-HLH-like binding site at -138/-131. In addition, this analysis identified a negative-acting element at -111/-102 bp. Using the gel shift assay, we found that PDX-1 composed the major beta -cell binding activity with the human IAPP elements at -154/-142 and -91/-84 bp. In contrast, Isl-1 did not appear to bind to these elements. These results indicate that there are several distinct factors acting upon the sequences within the 5'-flanking region of the IAPP gene to control islet beta  cell-specific expression. Furthermore, one of these factors, PDX-1, is common to the insulin gene.


EXPERIMENTAL PROCEDURES

Generation of Transgenic Mice and Immunohistochemical Staining

The IAPP-GH fusion gene was constructed from human IAPP and growth hormone (GH) sequences using standard cloning techniques. IAPP sequences were isolated from the luciferase reporter plasmid pSLA12 (21) and spanned -2798 to +450 bp (exon 1 (102 bp) + intron 1 (333 bp) + exon 2 (15 bp)) of the human 5'-flanking and -untranslated leader region; human growth hormone sequences were obtained from the plck-hGH (22) plasmid, a gift of Dr. Roger Perlmutter. IAPP-GH DNA was injected into the male pronuclei of fertilized FVB/N mouse oocytes. Founder animals were identified using Southern blotting and polymerase chain reaction (PCR) methods. IAPP-GH RNA was detected by Northern analysis in pancreas samples in one (strain HGC) of six germline positive founders. IAPP-GH expression was examined immunohistochemically in nontransgenic and the HGC transgenic strain using growth hormone (1:250 dilution, Peninsula Laboratories, Belmont, CA) and insulin (1:400 dilution, Dako Laboratories, Carpinteria, CA) antiserum in 3-4-µm paraformaldehyde-fixed, paraffin-embedded sections by the peroxidase-anti-peroxidase method as described previously (23).

Plasmid Constructions

All of the IAPP promoter mutants were cloned into the chloramphenicol acetyltransferase (CAT) expression vector, pTC, which is a Bluescript II SK- plasmid (Stratagene) containing the CAT reporter gene fused to beta -globin poly(A) sequences. Each of the clones described below were verified by DNA sequencing. The 5' deletion constructs were made with the human IAPP sequences in pSL (-2798 to +450; Ref. 21) using an exonuclease III/mung bean digestion kit (Pharmacia Biotech Inc.). The constructs were named according to their 5'-flanking end point. The exon I internal deletion mutants were generated in pAm-391 by standard molecular techniques. The intron I deletion mutant, pAm-241 (Delta +104 to +434), was constructed in pAm-241 by deleting the amylin intron 1. The oligonucleotide PCR primers spanned human IAPP sequences from -214/-231 (5'-AGATCTGATGGCAAATTC-3') and bridged exon 1 and exon 2 (5'-CATTAAAAGAAAATTTGAGAAGCCATGG-3'). The IAPP-human elongation factor-1 (EF-1) intron mutants were generated by cloning EF-1 intron 2 (+1726 to +2091) and EF-1 intron 4 (+2674 to +2756) fragments generated by the PCR reaction between the IAPP +103 (exon 1) and +436 (exon 2) sequences in pAm-391 to yield pAm-391EF-1Int2 and pAm-391EF-1Int4. The IAPP promoter linker-scanning mutants were constructed in pAm-222 by a modification of the procedure of Gustin and Burke (24). The IAPP promoter mutant oligos used in the PCR reactions are listed in Fig. 5.


Fig. 5. The A and E sites within the IAPP proximal promoter region are essential for expression in beta  cells. A, schematic diagram showing the positions of the A and E element sites. The E site at -138/-131 is referred to as E-like in the text since its sequence (NNC) deviates from a consensus B-HLH binding motif (NN; Ref. 43). The mutant name, position of mutation, and the wild-type and mutant sequence for each construct is shown. The relative activity (mean ± S.D.) of the mutant to pAm-222 in beta TC3 (B) and RIN-m5F cells (C) is shown. Comparisons were made by a nonpaired Student's t test. Statistically significant differences (p < 0.05) are indicated by an asterisk.
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Cell Culture and Transient Transfections

beta TC3 (kindly provided by Shimon Efrat, Albert Einstein College of Medicine, Bronx, NY), RINm5F (from ATCC), and HeLa S3 cells were maintained in RPMI 1640 supplemented with 10% fetal bovine serum, 2 mM glutamine, 100 units/ml penicillin, and 100 µg/ml streptomycin. All expression constructs were introduced into cells by electroporation with the Cell-porator (Life Technologies, Inc., Gaithersburg, MD) using conditions described previously (25). Routinely, 10 µg of IAPP-CAT chimera was co-transfected along with 2 µg of RSV-long terminal repeat promoter luciferase (LUC) expression plasmid, RSV-LUC; the LUC activity from RSV-LUC was used to control for transfection efficiency. Expression from the IAPP-CAT constructs was compared with a herpes simplex virus thymidine kinase promoter-driven CAT reporter construct, pBLCAT2 (26), transfected in parallel. LUC and CAT activities were measured from 10 µg of crude extract 40-48 h after transfection. The protein concentration of the crude lysate was determined by the method of Bradford (27). CAT and LUC activities were determined using the methods described by Kingston and Sheen (28). Each experiment was repeated a minimum of 3 times.

Western Blot Analysis

Nuclear extracts from beta TC3 cells and human adult islets were prepared as described (29). beta TC3 (0.5-10 µg) and islet (10 and 20 µg) extract protein were resolved on a 12% SDS-PAGE and electrotransferred to an Immobilon polyvinylidene difluoride membrane (Millipore, Bedford, MA). The membranes were either probed with N-terminal PDX-1 or Isl-1 K5 (31) polyclonal antisera (1:500 dilution in a buffer composed of 5% nonfat dry milk in Tris-buffered saline (140 mM NaCl, 10 mM Tris-HCL, pH 7.5) + 0.5% Tween 20). The N-terminal XlHbox8 antisera was developed against the first 75 amino acids of the Xenopus XlHbox8 protein and cross-reacts with the mouse PDX-1 protein (14); and the Isl-1 K-5 antisera was generated against C-terminal residues 178-349 of rat Isl-1 (31). The blot was washed and probed with peroxidase-conjugated protein A as described previously (14). The positions of the bound antibodies were detected by autoluminography with the ECL detection kit (Amersham Life Science Inc., Arlington Heights, IL).

Electrophoretic Mobility Shift Assays

Nuclear extract (5 µg) from HeLa and beta TC3 cell lines and human islet extracts were used in gel shift assays with double-stranded 32P-labeled human IAPP oligonucleotides probes (A1, -96GATGGAAATTAATGACAGAGG-76'; A2, -163ACTGATGAGTTAATGTAATAATGACC-138; A3, -183TATTTGCTACGTTAATATTTACT-161) using the conditions described previously (14). The sequence of the wild-type and mutant PDX-1 binding oligonucleotides in the rat insulin II gene (-213/-192 bp) have been described (14). The antibody addition experiments contained 3 µl of either N-terminal XlHbox 8, Isl-1 (A8 and K5), or Mox-2 antibodies. The Mox-2 antibody was raised to amino acids 2-139 of the mouse Mox-2 protein (30); and Isl-1 A8 antisera was generated against residues 86-175 of chick Isl-1 (31). Preincubation reactions with antisera and beta TC3 extract were conducted for 10 min at room temperature prior to initiation of the DNA binding reactions. The competition analyses were conducted with 100-fold excess of competitor DNA, the radiolabeled oligonucleotide probe, and extract. The samples were analyzed on a 6% nondenaturing polyacrylamide gel run at 4 °C in TGE buffer (50 mM Tris, 380 mM glycine, and 2 mM EDTA, pH 8.5). After electrophoresis, the gel was dried and subjected to autoradiography.


RESULTS

IAPP Promoter Activity in Transgenic Mice

To localize the sequences of the human IAPP gene that were sufficient for islet-specific expression, a 3.3-kilobase region of the genomic clone lambda h201 (32) was ligated to the human GH gene and expression examined in transgenic mice. The IAPP sequences contained within the IAPP-GH reporter included 2798 bp of 5'-flanking sequence, exon 1 (102 bp), intron 1 (333 bp), and a portion of exon 2 (15 bp). There were no IAPP protein coding sequences present in the GH reporter construct. IAPP-GH was subjected to pronuclear microinjection to generate six founder lines, one of which (line HGC) was shown by Northern analysis to express the transgene. To determine whether the transgene was expressed within islets, we prepared serial sections from the pancreas of transgenic and nontransgenic littermates and examined them for GH and insulin expression immunohistochemically (Fig. 1). We detected GH staining within the islets of transgenic mice but not their nontransgenic littermates. In contrast, insulin expression was observed in the islets of both sets of animals. The co-incidence of GH and insulin staining indicates that the majority of human GH-containing cells were beta  cells. These results are consistent with the expression pattern for the endogenous IAPP protein (4). In contrast, GH staining was not detected in any other tissues tested, including kidney, liver, spleen, stomach, skin, muscle, and brain.2 These results indicated that the region from -2798 to +450 bp was sufficient to direct islet-specific expression of the IAPP gene.


Fig. 1. Human IAPP gene -2798 to +450 sequences direct GH reporter expression to pancreatic islets in transgenic mice. Immunocytochemical localization of GH (A and B) and insulin (C and D) from transgenic and nontransgenic cryosections of adult pancreas. The amber staining corresponds to GH and insulin immunostaining; sections were counterstained with hematoxylin. A and C, HGC transgenic; B and D, nontransgenic littermate. Phase contrast magnification = × 200.
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Identification of 5'- and 3'-Flanking Sequences that Regulate IAPP Expression in beta  Cells

As a first step toward identifying the IAPP sequences within the -2798/+450 bp control region that were necessary for islet beta  cell expression, we subcloned a series of IAPP control region mutants into a bacterial CAT expression plasmid. The CAT activity from these chimeras was assayed in two well established, rodent, pancreatic islet beta  cell lines, beta TC3 (mouse) and RIN-m5F (rat), and a non-IAPP producing cell line, HeLa S3 (human). The insulin and IAPP genes are expressed in both of these beta  cell lines (10, 15, 21, 42). IAPP-CAT activity was compared with pTC, the parent CAT expression vector, and a ubiquitously expressed herpes simplex thymidine kinase promoter-driven CAT reporter construct, pBLCAT2. CAT activity from each transfected construct was normalized to the activity obtained from a cotransfected Rous sarcoma virus-luciferase expression plasmid.

To determine the exon 1 and intron 1 sequences that were important in expression, internal deletion mutants within these regions were constructed in the context of human IAPP sequences spanning -391/+450 (Fig. 2) or -241/+450 (Fig. 3). There was only a small change in IAPP-CAT reporter gene activity as a consequence of this 5' deletion (compare pAm-391 with pAm-222 in Fig. 4). All of the exon 1 deletion mutants were active in the transfected beta  cell lines and inactive in HeLa cells (Figs. 2 and 3; data not shown). The activity of the largest exon 1 deletion mutant, which spanned sequences from +5 to +47 bp, was reduced approximately 2.8-fold when compared with pAm-391 (Fig. 2, B and C). In contrast, precise deletion of intron 1 from pAm-241 resulted in a 20-fold drop in activity (Fig. 3A). To determine whether the loss in pAm-241Delta 104-434 activity resulted from the removal of essential cis-active transcriptional control sequences, we replaced the IAPP intron with nonrelated intron sequences from the generally expressed elongation factor 1 (EF-1) gene (33). The activity of the constructs containing either EF-1 intron 2 or EF-1 intron 4 sequences were very similar to the IAPP wild-type construct (compare pAm-391 with either pAm-391EF-1Int2 or pAm-391EF-1Int4 in Fig. 3B). Together, these results indicate that IAPP transgene transcription within beta  cells was not profoundly affected by the human IAPP noncoding sequences present in the construct. However, our results suggest that a post-transcriptional processing event may have been very important in the expression of IAPP-GH. We therefore have retained the IAPP noncoding sequences to +450bp within each of the 5'-flanking control region mutant constructs in the studies described below.


Fig. 2. Effect of exon 1 mutagenesis on pAm-391 activity. The exon 1 mutants were constructed within pAm-391 as described under "Experimental Procedures." A, exon 1 sequences within wild-type (pAm-391) and mutant constructs. The transcriptional activities of the wild-type and mutant IAPP-CAT constructs in beta TC-3 (B), RIN-m5F (C), and HeLa S3 cells (D). The results represent the normalized mean percent CAT acetylation (% CAT) from at least three independent transfections ± S.D.
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Fig. 3. Analysis of the expression of intron 1 mutants in beta TC-3 cells. A, comparison of pAm-241, pTC, and pBLCAT2 activity to the intronless IAPP-CAT mutant, pAm-241Delta 104-434. A schematic representation of the wild-type pAm-241 and intronless pAm-241Delta 104-434 constructs is shown. The transcription start site is represented by the arrow. B, comparison of pAm-391, pTC, pBLCAT2 activity to the EF-1 intron 2, pAm-391EF-1Int2, and EF-1 intron 4, pAm-391EF-1Int4, substitution mutants. A schematic representation of the wild-type pAm-391 and pAm-391EF-1Int2 and pAm-391EF-1Int4 constructs is shown. The results represent the normalized mean percent CAT acetylation (% CAT) from at least three independent transfections ± S.D.
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Fig. 4. Proximal elements within the IAPP promoter direct expression of islet beta  cells. A, schematic representation of the 5'-flanking deletion constructs; the transcription start site is represented by the arrow. The plasmids were named according to the 5' deletion end point relative to the IAPP transcription start site. The transcriptional activities of the IAPP-CAT, pTC, and pBLCAT2 constructs in beta TC3 (B), RIN-m5F (C), and HeLa S3 cells (D). The results represent the normalized mean percent CAT acetylation (% CAT) from three independent transfections ± S.D.
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To identify the 5'-flanking region sequences within the human IAPP promoter that were important in beta -cell expression, we generated a series of 5'-flanking IAPP-CAT deletion constructs. The expression pattern obtained with these mutants was similar between the beta cell lines, beta TC3 and RIN-m5F (Fig. 4, B and C). Thus, the chimera with only 222 bp of upstream sequence, pAm-222, had approximately the same activity as the -2798 construct, pAm-2798. In contrast, deletion of the IAPP sequences between -222 to -138 resulted in a 6-10-fold drop in activity in both beta  cell lines. This region contains the A/T-rich motifs that appear to be functionally similar to those of the insulin gene (10). The generally lower activity of the IAPP-CAT construct in RIN-m5F cells, when compared with beta TC-3, is also reflected in their IAPP and insulin levels (21, 42). All of the 5'-deletion constructs were inactive in HeLa cells (Fig. 4D). These studies indicate that the sequences between -222 to +450 bp are responsible for directing IAPP gene expression to beta  cells.

Identification of cis-Acting Elements Involved in Regulating beta  Cell-specific Expression

To identify the IAPP control elements within the 5' proximal region that were important in beta  cell-type-specific activity, we constructed a series of 10-bp linker-scanner mutants between positions -211 and -32 bp in pAm-222 (Fig. 5). This strategy allowed us to analyze the importance of small regions of the IAPP gene in transcriptional control without altering the spacing between putative promoter elements. The activity of each construct was assayed in beta TC3 and RINm5f cells.

There were several IAPP promoter sequences sensitive to mutation in transfected beta  cells (Fig. 5). In some instances, we observed that mutant IAPP-CAT activity was reduced primarily in only one of the beta  cell lines. In this category were the mutants at -201/-192, and -81/-71 bp. We presume that their activators were only limiting for IAPP-CAT expression in the sensitive beta  cell line. We believe that the more interesting mutants were those that influenced IAPP-CAT activity in both RIN-m5F and beta TC-3 cells as these probably represent the action of regulators that are essential for transcription. The phenotype of these mutants indicates that IAPP gene expression is regulated by both positive- and negative-acting cellular activities. Thus mutations within activator sites, like the A/T-rich elements at -172/-163, -154/-142, and -91/-84 bp or the B-HLH-like site at -138/-131, reduced activity by 65-75% (compare the activity of the C, D, E, F, G, and L mutants with pAm-222 in Fig. 5A). In accordance with the nomenclature used in naming the A/T-rich and B-HLH sites in the insulin gene (34), the A/T-rich elements at -172/-163, -154/-142, and -91/-84 bp will be referred to as A3, A2, and A1, respectively, and the B-HLH-like site as E1. Each of the A and E element mutants profoundly affected pAm-222 activity, implying that the activators functioning at these sites act cooperatively to mediate IAPP expression. In contrast to the A/T-rich and B-HLH-like site mutants, the properties of -111/-102 mutant indicates that it is a repressor binding site. This result does not appear to be caused by artifactual generation of an activator binding site since the 2-8-fold increase in activity observed with the -111/-102 site mutant was also obtained with two other linker-scanner mutants over this region.3

PDX-1 Is the Predominant beta  Cell Activity Binding to the A1 and A2 Elements

The gel mobility shift assay was used to determine the distribution of the cellular factors interacting with the A1, A2, and A3 elements. Nuclear extracts were prepared from beta TC3 and HeLa S3 cells. Binding reactions were conducted in the presence of extract and 32P-labeled human IAPP A-element probes spanning sequences at -183/-161 (A3), -163/-138 (A2), and -96/-76 (A1) bp. Binding to these IAPP elements was compared with the insulin A2 element binding site at -213 to -192 bp, which interacts with the PDX-1 transcription factor (14). Several protein-DNA complexes were detected with these IAPP probes in these extracts (Fig. 6). Specificity of binding was determined in competition assays with wild-type IAPP and with wild-type and mutant alleles of the insulin -213/-192 element as competitors. The competition pattern indicates that there was at least one common, specific protein-IAPP element complex detected using beta TC3 cell extract with the A1 and A2 probes (Fig. 6, A and B). This complex composes the major beta  cell binding activity and co-migrates with the PDX-1-insulin complex (Fig. 6D); it was not detected in HeLa extracts (Fig. 6). The presence of PDX-1 in this complex was also confirmed by antibody-supershift analysis. Thus, the addition of an antibody that recognizes PDX-1 specifically super-shifted this complex with the IAPP A1 and A2 probes, whereas there was no effect upon incubation with a polyclonal antisera to the unrelated murine mesoderm-specific Mox-2 homeoprotein (Fig. 6). In contrast, the IAPP A3 element does not bind to this factor (Fig. 6C).


Fig. 6. Binding of beta TC-3 and HeLa nuclear proteins to IAPP and insulin A element sequences. Equal concentrations of HeLa (lane 1) and beta TC3 (lanes 2-7) protein extracts (5 µg) were analyzed for IAPP A1 (A), IAPP A2 (B), IAPP A3 (C), and insulin A2 element binding (D). Competition reactions were conducted with the A probe plus beta TC-3 extract in the presence of a 100-fold molar excess of unlabeled competitor. Lane 3, corresponding IAPP A competitor; lane 4, wild-type insulin A2; and lane 5, mutant insulin A2. The alpha XlHbox8 and alpha Mox-2 antiseras were preincubated with the beta TC-3 extract before initiation of the DNA-binding reactions. Lane 6, plus alpha PDX-1 antibody; lane 7, alpha Mox-2 antibody. The position of the PDX-1 complex is labeled.
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Our gel-shift results indicated that the homeoprotein PDX-1 was the principal A element binding protein of the IAPP gene. Recent studies by Bretherton-Watt et al. (19) have also come to a similar conclusion. However, Wang and Drucker (20) proposed that Isl-1, a LIM homeodomain protein, binds to and activates IAPP expression through an IAPP A/T-rich element. Their results indicate that Isl-1 actions are primarily through the A2 element. To compare the relative contribution of Isl-1 and PDX-1 with A2 element binding activity, we analyzed the effect of PDX-1 and Isl-1 polyclonal antisera on protein-DNA complex formation in extracts prepared from beta TC-3 cells and human islets. Isl-1 antisera raised to either amino acids 86-175 or 178-349 were used in this analysis. Western blot analysis indicated that there was approximately 80-fold more PDX-1 than Isl-1 in beta TC-3 cells and 1.5-fold more in islets (Fig. 7). The PDX-1 binding complex formed with the A2 element probe was quantitively removed from these extracts upon addition of the PDX-1 antisera (Fig. 8). In contrast, the Isl-1 and preimmune antisera did not have any specific influence on A2 element complex levels. Increasing the amount of Isl-1 antisera had no effect on this result nor did changing the gel-shift reaction conditions to those of Wang and Drucker.4 These results strongly suggest that PDX-1 is the major IAPP A2 element binding factor in beta  cells, with little or no contribution from Isl-1. We infer from these results that PDX-1 is an activator of IAPP A/T-element driven activity in islet beta  cells.


Fig. 7. Western blot analysis for PDX-1 and Isl-1 proteins in beta TC-3 and human islet extracts. The blot was probed with the polyclonal antibodies (1:500 dilution) raised to Isl-1 (K5) (A) and PDX-1 (B). The positions of PDX-1 and Isl-1 are indicated. The amount of beta TC3 (lanes 1-4) and islet (lanes 5 and 6) extract protein in each lane varies. Lane 1, 5 µg; land 2, 10 µg; lane 3, 15 µg; lane 4, 20 µg, lane 5, 5 µg; and lane 6, 10 µg. The exposure time for the beta TC3 (lanes 1-4) in panel A is 2 min and in panel B is 10 s; the islet exposure time in panels A and B was 10 s. Quantitation of the relative levels of PDX-1 to Isl-1 was determined by densitometric scanning of the autoradiogram. There was approximately 80-fold more PDX-1 than Isl-1 in beta TC3 extracts and about 1.5-fold more in islets.
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Fig. 8. An antibody to PDX-1 but not Isl-1 influences IAPP A2 element complex formation. Binding and gel electrophoreses were conducted with the IAPP A2 element probe with beta TC-3 and human islet extracts. Lane 1, control; lane 2, plus N-terminal XlHbox 8 antibody; lane 3, plus the Isl-1 (K5) antibody; lane 4, plus the Isl-1 A8 antibody; and lane 5, plus preimmune serum.
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DISCUSSION

IAPP is a major component of islet amyloid plaques found in NIDDM patients (1). Although the physiological and pathophysiological role of IAPP is unclear, this factor appears to inhibit insulin action by affecting both its release from the pancreas (5, 6) and its activity in target tissues such as skeletal muscle (7). It has been proposed that overexpression of IAPP could contribute to the development of disease (9). Recent studies with transgenic mice that overexpress human IAPP support this proposal (35). Thus, inhibiting IAPP transcription by targeting the action of factors uniquely required for expression could be a viable therapeutic initiative. In the present study, we have identified the cis-acting DNA elements of the human IAPP gene that are required for islet beta  cell expression. Our analyses revealed that human IAPP sequences, which reside between nucleotides -222 to +450, contain the control elements that impart beta  cell-specific expression. Furthermore, we observed that transcription appears to be mediated through the interaction of both positive- and negative-acting cellular factors. These results also indicate that the PDX-1 transcription factor contributes to the correct, cell-type-specific expression of both the IAPP and insulin genes.

The transgenic reporter gene IAPP-GH, which contained human IAPP gene sequences from -2798 to +450 bp driving growth hormone expression, was expressed in the same islet-specific manner as the endogenous gene and therefore served to define the region of the IAPP gene required for transcription. To determine more precisely the regions of the IAPP gene that were important in beta  cell expression, we constructed a series of 5'- and 3'-flanking deletion mutants spanning the sequences from -2798 to +450 and examined their activity in IAPP expressing and nonexpressing cell lines. Two regions appear to be important in islet beta -cells, a promoter proximal region between -222 and -91 bp and an intron region between +104 and +434 bp. The promoter region contains the cis-acting elements required for islet-specific transcriptional activity. In contrast, the intron region appears to be important in post-transcriptional control. This conclusion is based on our observation that replacement of IAPP first intron sequences with non-related sequences from the ubiquitously expressed EF-1 gene restored IAPP-CAT expression to a level comparable with the wild-type gene. Although the exact regulatory mechanism has not been elucidated, these results suggest that splicing is required for maximal IAPP expression. Studies conducted with other mammalian genes (36, 37) and in plants (38) indicate that this may be an important regulatory process. Detailed experiments conducted by Huang and Gorman (39) suggest that splicing is coupled to efficient polyadenylation and transport of the mRNA to the cytoplasm.

To systematically identify the elements within the human IAPP proximal promoter region that were important in beta  cell expression, linker-scanner mutants were constructed spanning the sequences between -211 and -32. Our results suggest that activation of IAPP transcription is primarily mediated by an interplay between several distinct regulators acting at the A elements at -172/-163, -154/-142, and -91/-84 bp and the E-like site at -138/-131 bp. The activator of the A1 and A2 elements appears to be PDX-1, a factor which plays a key role in pancreatic determination and insulin transcription in beta  cells (14-18). This conclusion is based upon several observations. First, antibodies to PDX-1 recognize the principal binding complex associated with each of these elements in gel shift experiments performed with beta  cell line and islet extracts. The recent binding and antibody supershift studies conducted with the human IAPP gene by Bretherton-Watt et al. (19) also support this conclusion. Second, the endogenous expression pattern of PDX-1 and IAPP appear to be identical (4, 12, 14, 16). Finally, Serup et al. (40) have recently demonstrated that PDX-1 stably transfected into the islet alpha  cell line AN 697 coordinately induces IAPP and insulin gene expression. Interestingly, PDX-1 did not affect the expression of other genes selectively transcribed in islet beta  cells, like the glucose transporter 2, beta  glucokinase, or glucagon-like peptide 1 receptor genes in their study. In contrast, co-transfection experiments conducted by Wang and Drucker (20) indicates that Isl-1 can activate A2 element-mediated expression. These studies were conducted in the islet alpha  cell line, InR1 G9. Although we cannot detect any binding of Isl-1 to this element in either beta TC-3 or islet extracts, it is still possible that there are circumstances where this generally distributed islet factor (41) is important for A2 element activity. However, we believe that the islet cell types used in the various investigations may explain the discrepancies between studies. Wang and Drucker (20) used an islet alpha  cell line. In contrast, our results and those of Bretherton-Watt et al. (19) were obtained with IAPP producing beta  cell lines (10, 15, 21, 42). As a consequence, we believe that PDX-1 is the IAPP activator of A1- and A2-mediated expression in islet beta  and delta  cells.

Given the ability of PDX-1 to induce both IAPP and insulin expression, there must be other regulators that control their distinct expression patterns. Transcription between insulin and IAPP may be distinguished by factors that bind to and activate expression at the A3 or E1 elements. Insulin transcription is also regulated by proteins in the B-HLH family (43). However, previous studies have demonstrated that the B-HLH-like site of the IAPP gene will not functionally substitute for the insulin B-HLH site (10), arguing that a distinct factor is important in control. Alternatively, the negative regulator that acts at the -111/-102-bp element or another of the cis-active elements identified by our linker-scanner analysis may be key to selective expression. Further understanding of the importance of each of these factors in IAPP transcription may lead to better therapeutic strategies for preserving beta  cell function in NIDDM.


FOOTNOTES

*   This work was supported by National Institutes of Health Grant DK R01-50203 (to R. S.), and partial support was also derived from the Vanderbilt University Diabetes Research and Training Center Molecular Biology Core Laboratory (U. S. Public Health Service Grant P60 DK20593 from the National Institutes of Health).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
   To whom correspondence should be addressed. Tel.: 860-441-5412; Fax: 860-441-3783; E-mail: soellerwc{at}Pfizer.com.
1   The abbreviations used are: NIDDM, non-insulin dependent diabetes mellitus; IAPP, islet amyloid polypeptide; LUC, luciferase; CAT, chloramphenicol acetyl transferase; RSV, Rous sarcoma virus, bp, base pair(s); B-HLH, basic helix-loop-helix; GH, growth hormone; PCR, polymerase chain reaction; EF-1, elongation factor 1.
2   W. C. Soeller, P. Roche, and P. C. Butler, unpublished results.
3   M. D. Carty, J. S. Lillquist, and W. C. Soeller, unpublished results.
4   M. Peshavaria, and R. Stein, unpublished results.

ACKNOWLEDGEMENTS

We thank Drs. Yi Qiu and Arun Sharma for constructive criticism of the manuscript, Drs. Jeff Hanke and Roger Perlmutter for plasmid plck-hGH, Dr. Sam Pfaff for providing the Isl-1 A8 and K5 antisera, and Dr. Christopher Wright for the polyclonal N-terminal XlHbox8 antisera. We also thank the Diabetes Research and Training Center, Islet Isolation Core Facility (supported by U. S. Public Health Service Grant DK20579 from the National Institutes of Health) at Washington University School of Medicine for providing human adult islets; Jeff Stock, Jane Bennett, and Dr. John McNeish for generation of the HAPhGh founder animals; and Drs. Patrick Roche and Peter Butler of the Mayo Clinic, Rochester, MN for immunostaining of the mouse tissue sections.


Note Added in Proof

During review of this manuscript, another report was published that describes the importance of PDX-1 in IAPP transcription in the beta  cell (Watada, H., Kajimoto, Y., Kaneto, H., Matsuoka, T., Fujitani, Y., Miyazaki, J., and Yamasaki, Y. (1996) Biochem. Biophys. Res. Commun. 229, 746-751).


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