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Query: UMLS:C0011849 (
diabetes
)
277,896
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Insulin promoter factor 1
(
IPF-1
) is a homeodomain-containing protein that is thought to be a key regulator of pancreatic islet development and insulin gene transcription in beta-cells. This report describes the isolation and characterization of the human
IPF-1
gene. The coding region, which showed 83% nucleotide identity with the mouse
IPF-1
gene, was encoded by two exons that extended over a 5-kb region of human genome. The deduced human
IPF-1
protein contained 283 amino acids, 1 amino acid less than the mouse
IPF-1
protein. The homeodomain region of
IPF-1
was encoded by the second exon, and it was highly conserved among species. The human
IPF-1
gene was mapped to chromosome 13q12(12.1) by fluorescent in situ hybridization (FISH) analysis. A simple sequence repeat polymorphism (ipf1CA2) was identified in the genomic clone. Polymerase chain reaction (PCR) amplification of this repeat region revealed two alleles (heterozygosity = 0.32). This simple sequence repeat polymorphism, and thus the
IPF-1
gene, was incorporated into the human linkage map by genotyping reference Human Polymorphism Study Center (CEPH) pedigrees. Multipoint analysis with the CEPH genotype database placed the gene with equal likelihood between two marker intervals: D13S292-cdx3GA1 and cdx3GA1-D13S289 on chromosome 13, consistent with the results of FISH analysis. Two-point linkage analysis inferred that the most likely location for ipf1CA2 was at theta = 0 from cdx3GA1 locus. The exon-intron boundaries of the
IPF-1
gene were sequenced, and primers were synthesized to search the homeodomain region for potential variants in patients with NIDDM. By single-strand conformational polymorphism analysis, no variants were found within this region in 61 Japanese patients, which could contribute to the pathogenesis of NIDDM. The isolation of the human
IPF-1
gene, along with characterization of its genomic structure and chromosomal mapping, will now permit the assessment of the role of this gene in the pathogenesis of NIDDM in various populations.
Diabetes
1996 Jun
PMID:Isolation, characterization, and chromosomal mapping of the human insulin promoter factor 1 (IPF-1) gene. 863 54
The glycolytic enzyme glucokinase plays a primary role in the glucose-responsive secretion of insulin, and defects of this enzyme can cause NIDDM. As a step toward understanding the molecular basis of glucokinase (GK) gene regulation, we assessed the structure and regulation of the human GK gene beta-cell-type promoter. The results of reporter gene analyses using HIT-T15 cells revealed that the gene promoter was comprised of multiple cis-acting elements, including two primarily important cis-motifs: a palindrome structure, hPal-1, and the insulin gene cis-motif A element-like hUPE3. While both elements were bound specifically by nuclear proteins, it was the homeodomain-containing transcription factor
insulin promoter factor 1
(
IPF1
)/STF-1/PDX-1 that bound to the hUPE3 site:
IPF1
, when expressed in CHO-K1 cells, became bound to the hUPE3 site and activated transcription. An anti-
IPF1
antiserum used in gel-mobility shift analysis supershifted the DNA protein complex formed with the hUPE3 probe and nuclear extracts from HIT-T15 cells, thus supporting the involvement of
IPF1
in GK gene activation in HIT-T15 cells. In contrast to the insulin gene, however, neither the synergistic effect of the Pan1 expression on the
IPF1
-induced promoter activation nor the glucose responsiveness of the activity was observed for the GK gene promoter. These results revealed some conservative but unique features for the transcriptional regulation of the beta-cell-specific genes in humans. Being implicated in insulin and GK gene regulations as a common transcription factor,
IPF1
/STF-1/PDX-1 is likely to play an essential role in maintaining normal beta-cell functions.
Diabetes
1996 Nov
PMID:The human glucokinase gene beta-cell-type promoter: an essential role of insulin promoter factor 1/PDX-1 in its activation in HIT-T15 cells. 886 50
Currently there is debate regarding the capacity of pancreatic islets to regenerate in adult animals. Because pancreatic endocrine cells are thought to arise from duct cells, we examined the pancreatic ductal epithelium of the diabetic NOD mouse for evidence of islet neogenesis. We have evidence of duct proliferation as well as ductal cell differentiation, as suggested by bromodeoxyuridine-labeling and the presence of glucagon-containing cells within these ducts. In addition, the ductal epithelia in diabetic NOD mice expressed the neuroendocrine markers neuropeptide Y and tyrosine hydroxylase. These ducts also expressed the homeobox gene product,
insulin promoter factor 1
. Ductal cell proliferation and expression of these markers was not observed in transgenic NOD mice (NOD-E), which do not develop clinical or histopathological symptoms of IDDM. This suggests that the observed ductal cell proliferation and differentiation was a direct result of beta-cell destruction and insulin insufficiency in these adult diabetic mice, which further suggests that these events are recapitulating islet ontogeny observed during embryogenesis. It is possible that comparable processes occur in the human diabetic pancreas.
Diabetes
1997 Apr
PMID:alpha-Cell neogenesis in an animal model of IDDM. 907 99
To clarify the regeneration process of pancreatic beta-cells, we established a new mouse model of
diabetes
induced by selective perfusion of alloxan after clamping the superior mesenteric artery. In this model,
diabetes
could be induced by the destruction of beta-cells in alloxan-perfused segments, while beta-cells in nonperfused segments were spared. Intraperitoneal glucose tolerance tests showed glucose intolerance, which gradually ameliorated and was completely normalized in 1 year with a concomitant increase of insulin content in the pancreas. Histological examination showed neo-islet formation in the alloxan-perfused segment and the proliferation of spared beta-cells in the nonperfused segment. In the alloxan-perfused segment, despite a marked reduction of islets in size and number at an early stage, both the number of islets, including islet-like cell clusters (ICCs), and the relative islet area significantly increased at a later stage. Increased single beta-cells and ICCs were located in close contact with duct cell lining, suggesting that they differentiated from duct cells and that such extra-islet precursor cells may be important for beta-cell regeneration in beta-cell-depleted segment. In addition to beta-cells, some nonhormone cells in ICCs were positive for nuclear
insulin promoter factor 1
, which indicated that most, if not all, nonhormone cells positive for this factor were beta-cell precursors. In the nonperfused segment, the islet area increased significantly, and the highest 5-bromo-2-deoxyuridine-labeling index in beta-cells was observed at day 5, while the number of islets did not increase significantly. This indicated that the regeneration of islet endocrine cells occurs mostly through the proliferation of preexisting intra-islet beta-cells in the nonperfused segment. In conclusion, the regeneration process of beta-cells varied by circumstance. Our mouse model is useful for studying the mechanism of regeneration, since differentiation and proliferation could be analyzed separately in one pancreas.
Diabetes
1997 Aug
PMID:Demonstration of two different processes of beta-cell regeneration in a new diabetic mouse model induced by selective perfusion of alloxan. 923 52
Insulin promoter factor 1
(
IPF1
) is a key factor both for the regulation of insulin gene expression and for the development of the pancreas. In this study 88 patients with non-insulin-dependent
diabetes mellitus
(NIDDM) who were diagnosed as diabetic at less than 40 years of age, 55 patients with insulin-dependent-
diabetes
(IDDM), and 67 normal control subjects were analysed for variants in the upstream region of the
IPF1
gene by direct sequencing. A novel single nucleotide insertion polymorphism was found in a guanine triplet at 108 bp upstream of the translation start site. The G insertion allele (G4 allele) was found to be common in the Japanese population, at a frequency of 0.50. The prevalence of G3 homozygotes was higher in IDDM patients (35%) and lower in NIDDM patients (17%) than in normal control subjects (28%, p=0.049). In the NIDDM group, the ratio of insulin treatment tended to be higher in subjects homozygous for the G3 allele, although the genotype was not significantly associated with basal C-peptide levels. The polymorphism is unlikely to be a major contributor to the insulin deficiency of
diabetes
. However, the polymorphic locus, or an unknown mutation which is in linkage disequilibrium with the polymorphism, could be involved in the pathophysiology of
diabetes
. The high heterozygosity may be useful for genetic linkage studies of other mutations within and near the
IPF1
gene.
...
PMID:Identification of a single nucleotide insertion polymorphism in the upstream region of the insulin promoter factor-1 gene: an association study with diabetes mellitus. 962 81
Maturity-onset diabetes of the young (MODY) is a genetically and clinically heterogeneous subtype of Type 2
diabetes
characterized by early onset, autosomal dominant inheritance and primary defects in insulin secretion. To date, five proteins have been identified whose genetic absence or impairment causes MODY, the enzyme glucokinase (GCK/MODY2) and four transcription factors: hepatocyte nuclear factor 4alpha (HNF-4alpha/MODY1), HNF-1alpha/MODY3,
insulin promoter factor 1
(IPF-1/MODY4) and HNF-1beta/MODY5. Additional MODY genes remain to be identified.
...
PMID:Molecular Genetics of Maturity-onset Diabetes of the Young. 1032 8
The differential diagnosis of hyperglycemia in childhood and adolescence has to take into consideration early-onset non-insulin-dependent
diabetes
, defined as maturity onset
diabetes
of the young (MODY). To date, mutations in genes of five proteins have been shown to cause MODY: glucokinase (MODY2), hepatic nuclear factor-1 alpha (HNF-1 alpha) (MODY3), hepatic nuclear factor-4 alpha (HNF-4 alpha) (MODY1),
insulin promoter factor 1
(
IPF-1
) (MODY4) and hepatic nuclear factor-1 beta (HNF-1 beta) (MODY5), but other MODY genes still await elucidation. Clinical and metabolic heterogeneity of these subtypes of type 2 diabetes need to be defined, as deficiency of each factor has its own phenotype. Pediatric diabetologists should be aware of the increasing importance of MODY as a possible cause of hyperglycemia in children and adolescents. This will allow for the early diagnosis of these metabolic conditions and for the appropriate follow-up and treatment.
...
PMID:Maturity-onset diabetes of the young (MODY): a new challenge for pediatric diabetologists. 1041 64
Expression of the homeodomain transcription factor
IDX1
/IPF1 has been shown to be restricted to cells in the developing foregut that form the pancreatic primordium. In the adult,
IDX1
/IPF1 is expressed in the duodenum and pancreatic islets. The
IDX1
/IPF1 gene is required for pancreatic development, and in the human, heterozygous mutations have been linked to
diabetes mellitus
. In the present communication, we report that
IDX1
/IPF1 is expressed in discrete cells of the rat central nervous system during embryonic development. Using RT-PCR,
IDX1
/IPF1 mRNA was detected in neural precursor RC2.E10 cells, as well as in both forebrain and hindbrain of developing rats at embryonic day 15 (E15). The presence of
IDX1
/IPF1 protein was confirmed by Western immunoblotting. Immunohistochemical analyses of sagittal sections of E15 rats demonstrated the presence of scattered
IDX1
/IPF1-immunopositive cells in the forebrain. Finally, electrophoretic mobility shift assays using nuclear extracts from neural cells revealed the presence of
IDX1
/IPF1 bound to a putative homeodomain protein DNA-binding site present in the promoter of the glial fibrillary acidic protein gene. Our results suggest that
IDX1
/IPF1 may have previously unsuspected extrapancreatic functions during development of neural cells in the central nervous system.
...
PMID:The pancreatic homeodomain transcription factor IDX1/IPF1 is expressed in neural cells during brain development. 1043 48
Neonatal diabetes mellitus (NDM) is defined as hyperglycaemia occurring in the first few weeks of life. It can be either transient (TNDM) or permanent (PNDM), and until recently, little was known about the condition. A cohort of 30 infants with a history of TNDM has been studied, and findings have suggested that NDM does not have the same aetiology as classical type 1 childhood
diabetes
. Uniparental isodisomy of chromosome 6 and an unbalanced duplication of paternal chromosome 6 have both been described as a genetic basis for TNDM in over 75% of the cases. In addition, cerebellar hypoplasia and Walcott-Rallison syndrome have been associated with PNDM, suggesting an autosomal recessive inheritance pattern; furthermore, a mutation in the gene
insulin promoter factor 1
has been identified as a cause of pancreatic agenesis in PNDM. In the long term, TNDM may reduce beta cell functional capacity and present a predisposition to type 2 diabetes mellitus.
...
PMID:Neonatal diabetes: new insights into aetiology and implications. 1089 36
Human pancreatic cells with a typical ductal phenotype and potential to proliferate can be obtained in vitro, but the differentiation capacity of these putative human pancreatic stem cells remains to be documented. We investigated the protein and mRNA expression of
insulin promoter factor 1
(
IPF-1
) (or pancreas/duodenal homeobox 1), a transcription factor critical for pancreatic development and endocrine cell neogenesis, in human pancreatic ductal cells derived from cultured exocrine tissue. In vitro, exocrine cells rapidly adhered (within 12 h) and were de-/transdifferentiated to ductal cells after 3 days with a dramatic loss of amylase protein (n = 4, 92 +/- 3.3%, P < 0.05 vs. day 1) and a simultaneous increase of ductal cytokeratin 19 protein (n = 4, 3.4-fold on day 3 and 7-fold on day 9, P < 0.05 vs. day 1).
IPF-1
protein and mRNA levels were low to undetectable in exocrine preparations before culture. After 2 days of culture, a 3.2-fold increase in
IPF-1
protein was observed, corresponding to the characteristic 46-kDa protein in Western blots. Reverse transcriptase-polymerase chain reaction confirmed a 10.5-fold increase in
IPF-1
mRNA levels after 3 days of culture (n = 5, P < 0.001 vs. day 1). Double immunocytochemistry showed direct evidence that
IPF-1
appeared during culture in these exocrine-derived ductal cells (cytokeratin 7-positive) and was not merely in contaminating endocrine cells (chromogranin A-positive). In conclusion, we describe herein the first converging evidence on both the molecular and protein level that human cells with a typical ductal phenotype derived ex vivo from pancreatic exocrine tissue (obtained from healthy donors) can reexpress
IPF-1
in culture, suggesting their pancreatic precursor/stem cell potential.
Diabetes
2000 Oct
PMID:Adult human cytokeratin 19-positive cells reexpress insulin promoter factor 1 in vitro: further evidence for pluripotent pancreatic stem cells in humans. 1101 51
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