Effects of ageing and senescence on pancreatic β-cell function

Ageing is generally associated with deterioration of organ function and regenerative potential. In the case of pancreatic β-cells, an age-related decline in proliferative potential is well documented, and was proposed to contribute to the increased prevalence of type 2 diabetes in the elderly. The effects of ageing on β-cell function, namely glucose-stimulated insulin secretion (GSIS), have not been studied as extensively. Recent work revealed that, surprisingly, β-cells of mature mice and humans secrete more insulin than young β-cells in response to high glucose concentrations, potentially serving to counteract age-related peripheral insulin resistance. This functional change appears to be orchestrated by p16(Ink4A) -driven cellular senescence and downstream remodelling of chromatin structure and DNA methylation, enhancing the expression of genes controlling β-cell function. We propose that activation of the cellular senescence program drives life-long functional maturation of β-cells, due to β-cell hypertrophy, enhanced glucose uptake and more efficient mitochondrial metabolism, in parallel to locking these cells in a non-replicative state. We speculate that the beneficial aspects of this process can be harnessed to enhance GSIS. Other age-related mechanisms, which are currently poorly understood, act to increase basal insulin secretion levels also in low glucose conditions. This leads to an overall reduction in the amplitude of insulin secretion between low and high glucose at old age, which may contribute to a deterioration in metabolic control.

Pancreatic islet and progenitor cell surface markers with cell sorting potential

AIMS/HYPOTHESIS

The aim of the study was to identify surface bio-markers and corresponding antibody tools that can be used for the imaging and immunoisolation of the pancreatic beta cell and its progenitors. This may prove essential to obtain therapeutic grade human beta cells via stem cell differentiation.

METHODS

Using bioinformatics-driven data mining, we generated a gene list encoding putative plasma membrane proteins specifically expressed at distinct stages of the developing pancreas and islet beta cells. In situ hybridisation and immunohistochemistry were used to further prioritise and identify candidates.

RESULTS

In the developing pancreas seizure related 6 homologue like (SEZ6L2), low density lipoprotein receptor-related protein 11 (LRP11), dispatched homologue 2 (Drosophila) (DISP2) and solute carrier family 30 (zinc transporter), member 8 (SLC30A8) were found to be expressed in early islet cells, whereas discoidin domain receptor tyrosine kinase 1 (DDR1) and delta/notch-like EGF repeat containing (DNER) were expressed in early pancreatic progenitors. The expression pattern of DDR1 overlaps with the early pancreatic and duodenal homeobox 1 (PDX1)⁺/NK6 homeobox 1 (NKX6-1)⁺ multipotent progenitor cells from embryonic day 11, whereas DNER expression in part overlaps with neurogenin 3 (NEUROG3)⁺ cells. In the adult pancreas SEZ6L2, LRP11, DISP2 and SLC30A8, but also FXYD domain containing ion transport regulator 2 (FXYD2), tetraspanin 7 (TSPAN7) and transmembrane protein 27 (TMEM27), retain an islet-specific expression, whereas DDR1 is undetectable. In contrast, DNER is expressed at low levels in peripheral mouse and human islet cells. Re-expression of DDR1 and upregulation of DNER is observed in duct-ligated pancreas. Antibodies to DNER and DISP2 have been successfully used in cell sorting.

CONCLUSIONS/INTERPRETATION

Extracellular epitopes of SEZ6L2, LRP11, DISP2, DDR1 and DNER have been identified as useful tags by applying specific antibodies to visualise pancreatic cell types at specific stages of development. Furthermore, antibodies recognising DISP2 and DNER are suitable for FACS-mediated cell purification.

Transcriptomes of the major human pancreatic cell types

AIMS/HYPOTHESIS

We sought to determine the mRNA transcriptome of all major human pancreatic endocrine and exocrine cell subtypes, including human alpha, beta, duct and acinar cells. In addition, we identified the cell type-specific distribution of transcription factors, signalling ligands and their receptors.

METHODS

Islet samples from healthy human donors were enzymatically dispersed to single cells and labelled with cell type-specific surface-reactive antibodies. Live endocrine and exocrine cell subpopulations were isolated by FACS and gene expression analyses were performed using microarray analysis and quantitative RT-PCR. Computational tools were used to evaluate receptor-ligand representation in these populations.

RESULTS

Analysis of the transcriptomes of alpha, beta, large duct, small duct and acinar cells revealed previously unrecognised gene expression patterns in these cell types, including transcriptional regulators HOPX and HDAC9 in the human beta cell population. The abundance of some regulatory proteins was different from that reported in mouse tissue. For example, v-maf musculoaponeurotic fibrosarcoma oncogene homologue B (avian) (MAFB) was detected at equal levels in adult human alpha and beta cells, but is absent from adult mouse beta cells. Analysis of ligand-receptor interactions suggested that EPH receptor-ephrin communication between exocrine and endocrine cells contributes to pancreatic function.

CONCLUSIONS/INTERPRETATION

This is the first comprehensive analysis of the transcriptomes of human exocrine and endocrine pancreatic cell types-including beta cells-and provides a useful resource for diabetes research. In addition, paracrine signalling pathways within the pancreas are shown. These results will help guide efforts to specify human beta cell fate by embryonic stem cell or induced pluripotent stem cell differentiation or genetic reprogramming.

Transcriptional regulation of α-cell differentiation

The development of the endocrine pancreas and the differentiation of its five cell types, α, β, δ, ε and pancreatic polypeptide (PP) cells, are a highly complex and tightly regulated process. Proper differentiation and function of α- and β-cells are critical for blood glucose homeostasis. These processes are governed by multiple transcription factors and other signalling systems, and its dysregulation results in diabetes. The differentiation of α-cells and the maintenance of α-cell function can be influenced at several stages during development and in the maturing islet. Many transcription factors, such as neurogenin 3 (Ngn3), pancreatic duodenal homeobox 1 (Pdx1) and regulatory factor x6 (Rfx6), play a crucial role in the determination of the endocrine cell fate, while other transcription factors, such as aristaless-related homeobox (Arx) and forkhead box A2 (Foxa2), are implicated in the initial or terminal differentiation of α-cells. In vivo and in vitro studies have shown that preproglucagon transcription, and therefore the maintenance of α-cell function, is regulated by several factors, including forkhead box A1 (Foxa1), paired box 6 (Pax6), brain4 (Brn4) and islet-1 (Isl-1). Detailed information about the regulation of normal and abnormal α-cell differentiation gives insight into the pathogenesis of diabetes, identifies further targets for diabetes treatment and provides clues for the reprogramming of α- to β-cells for replacement therapy.

Disease-associated loci are significantly over-represented among genes bound by transcription factor 7-like 2 (TCF7L2) in vivo

AIMS/HYPOTHESIS

Transcription factor 7-like 2 (TCF7L2) has been strongly implicated in type 2 diabetes and cancer. Our goal was to identify the DNA sequences bound by this transcription factor in vivo.

METHODS

We applied chromatin immunoprecipitation and sequencing to globally identify and map human DNA sequences bound by TCF7L2 in the colorectal carcinoma cell line, HCT116, where it is abundantly expressed.

RESULTS

We identified 1,095 discrete binding sites across the genome, of which a subset were within 5 kb of 548 annotated NCBI Reference Sequence (RefSeq) genes. Despite using a cancer cell line, the most significant functions represented using pathway analysis software were related to diabetes, genetic disorders and coronary artery disease. As one of the enriched categories was related to genetic disorders, we queried our results against all published genome-wide association studies (GWAS) and found a highly significant over-representation of reported loci from among the genes bound by TCF7L2 within 5 kb (p = 7.50 × 10⁻¹⁵). This observation was primarily driven by excess loci revealed from GWAS of metabolic and cardiovascular traits; however, there was no or only minor enrichment of GWAS-derived loci for cancer, and inflammatory or neurological diseases. Of the specific traits, the most enriched loci were for type 2 diabetes and height. When defining the distance from genes at 50 kb or 500 kb, this enrichment pattern persisted, with some additional evidence for enrichment of cancer-related loci.

CONCLUSIONS/INTERPRETATION

A highly significant proportion of genes bound by TCF7L2 are known disease-associated loci. These findings suggest that TCF7L2 is a central node in the regulation of human diabetes and other disease-associated genes.

The Foxa family of transcription factors in development and metabolism

The Foxa subfamily of winged helix/forkhead box (Fox) transcription factors has been the subject of genetic and biochemical study for over 15 years. During this time its three members, Foxa1, Foxa2 and Foxa3, have been found to play important roles in multiple stages of mammalian life, beginning with early development, continuing during organogenesis, and finally in metabolism and homeostasis in the adult. Foxa2 is required for the formation of the node and notochord, and in its absence severe defects in gastrulation, neural tube patterning, and gut morphogenesis result in embryonic lethality. Foxa1 and Foxa2 cooperate to establish competence in foregut endoderm and are required for normal development of endoderm-derived organs such as the liver, pancreas, lungs, and prostate. In post-natal life, members of the Foxa family control glucose metabolism through the regulation of multiple target genes in the liver, pancreas, and adipose tissue. Insight into the unique molecular basis of Foxa function has been obtained from recent genetic and genomic data, which identify the Foxa proteins as 'pioneer factors' whose binding to promoters and enhancers enable chromatin access for other tissue-specific transcription factors.

Krüppel-like factor 4 exhibits antiapoptotic activity following gamma-radiation-induced DNA damage

In response to gamma-radiation-induced DNA damage, organisms either activate cell cycle checkpoint and repair machinery or undergo apoptosis to eliminate damaged cells. Although previous studies indicated that the tumor suppressor p53 is critically involved in mediating both responses, how a cell decides which pathway to take is not well established. The zinc-finger-containing transcription factor, Krüppel-like factor 4 (KLF4), is a crucial mediator for the checkpoint functions of p53 after gamma-irradiation and does so by inhibiting the transition from the G(1) to S and G(2) to M phases of the cell cycle. Here, we determined the role of KLF4 in modulating the apoptotic response following gamma-irradiation. In three independent cell systems including colorectal cancer cells and mouse embryo fibroblasts in which expression of KLF4 could be manipulated, we observed that gamma-irradiated cells underwent apoptosis if KLF4 was absent. In the presence of KLF4, the degree of apoptosis was significantly reduced and cells resorted to checkpoint arrest. The mechanism by which KLF4 accomplished this antiapoptotic effect is by activating expression of the cell cycle arrest gene, p21(WAF1/CIP1), and by inhibiting the ability of p53 to transactivate expression of the proapoptotic gene, BAX. Results of our study illustrate an unexpected antiapoptotic function of KLF4, heretofore considered a tumor suppressor in colorectal cancer, and suggest that KLF4 may be an important determinant of cell fate following gamma-radiation-induced DNA damage.

Stage-specific regulation of respiratory epithelial cell differentiation by Foxa1

Foxa1 is a member of the winged helix family of transcription factors that is expressed in epithelial cells of the conducting airways and in alveolar type II cells of the lung. To determine the role of Foxa1 during lung morphogenesis, histology and gene expression were assessed in lungs from Foxa1-/- gene-targeted mice from embryonic day (E) 16.5 to postnatal day (PN) 13. Deletion of Foxa1 perturbed maturation of the respiratory epithelium at precise times during lung morphogenesis. While dilatation of peripheral lung saccules was delayed in Foxa1-/- mice at E16.5, sacculation was unperturbed later in development (E17.5-E18.5). At PN5, alveolarization was markedly delayed in Foxa1-/- mice; however, by PN13 lung histology was comparable to wild-type controls. Clara cell secretory protein (CCSP), prosurfactant protein (SP)-C, and SP-B protein content and immunostaining were decreased in Foxa1-/- mice between E16.5 and E18.5 but normalized after birth. Timing and sites of expression of thyroid transcription factor-1, Foxj1, and beta-tubulin were unaltered in lungs of Foxa1-/- mice. In vitro, Foxa1 regulated the activity of CCSP and SP-A, SP-B, SP-C, and SP-D promoters as assessed by luciferase reporter assays in HeLa, H441, and MLE15 cells. Although Foxa1 regulates respiratory epithelial differentiation and structural maturation of the lung at precise developmental periods, the delay in maturation is subsequently compensated at times to enable respiratory function and restore normal lung structure after birth.

Foxa3 (hepatocyte nuclear factor 3gamma ) is required for the regulation of hepatic GLUT2 expression and the maintenance of glucose homeostasis during a prolonged fast

The winged helix transcription factors, hepatocyte nuclear factors 3alpha, -beta, and -gamma (HNF-3, encoded by the Foxa1, -a2, and -a3 genes, respectively), are expressed early in embryonic endoderm and play important roles in the regulation of gene expression in liver and pancreas. Foxa1 has been shown to be required for glucagon secretion in the pancreas, whereas Foxa2 is critical for the regulation of insulin secretion in pancreatic beta-cells. Here we address the role of Foxa3 in the maintenance of glucose homeostasis. Mice homozygous for a null mutation in Foxa3 appear normal under fed conditions. However, when fasted, Foxa3(-/-) mice have a significantly lower blood glucose compared with control mice. The fasting hypoglycemia in Foxa3(-/-) mice could not be attributed to defects in pancreatic hormone secretion, ketone production, or hepatic glycogen breakdown. Surprisingly, mRNA levels for several gluconeogenic enzymes were up-regulated appropriately in fasted Foxa3(-/-) mice, despite the fact that the corresponding genes had been shown to be activated by FOXA proteins in vitro. However, the mRNA for the plasma membrane glucose transporter GLUT2 was decreased by 64% in the fasted and 93% in the fed state, suggesting that efflux of newly synthesized glucose is limiting in Foxa3(-/-) hepatocytes. Thus, Foxa3 is the dominating transcriptional regulator of GLUT2 expression in hepatocytes in vivo. In addition, we investigated the hepatic transcription factor network in Foxa3(-/-) mice and found that the normal activation of HNF-4alpha, HNF-1alpha, and PGC-1 induced by fasting is attenuated in mice lacking Foxa3.

Foxl1 controls the Wnt/beta-catenin pathway by modulating the expression of proteoglycans in the gut

Foxl1 is a winged helix transcription factor expressed in the mesenchyme of the gastrointestinal tract. Foxl1 null mice display severe structural defects in the epithelia of the stomach, duodenum, and jejunum. Here we addressed the molecular mechanisms by which Foxl1 controls gastrointestinal differentiation. First we showed that the abnormalities found in the epithelia of the null mice are the result of an increase in the number of proliferating cells and not a change in the rate of cell migration. Next we investigated the regulatory circuits affected by Foxl1. We focused on the Wnt/beta-catenin signaling pathway as a possible target of Foxl1 as it has been shown to play a central role in gastrointestinal proliferation. We demonstrated that Foxl1 activates the Wnt/beta-catenin pathway by increasing extracellular proteoglycans, which act as co-receptors for Wnt. Thus we establish that Foxl1 is involved in the regulation of the Wnt/beta-catenin pathway, providing a novel link in mesenchymal/epithelial cross-talk in the gut. Moreover, we provide the first example implicating proteoglycans in the regulation of cellular proliferation in the gastrointestinal tract.

Ron-mediated cytoplasmic signaling is dispensable for viability but is required to limit inflammatory responses

Ron receptor activation induces numerous cellular responses in vitro, including proliferation, dissociation, and migration. Ron is thought to be involved in blood cell development in vivo, as well as in many aspects of the immune response including macrophage activation, antigen presentation, and nitric oxide regulation. In previous studies to determine the function of Ron in vivo, mice were generated with a targeted deletion of the extracellular and transmembrane regions of this gene. Mice homologous for this deletion appear to die early during embryonic development. To ascertain the in vivo function of Ron in more detail, we have generated mice with a germline ablation of the tyrosine kinase domain. Strikingly, our studies indicate that this domain of Ron, and therefore Ron cytoplasmic signaling, is not essential for embryonic development. While mice deficient in this domain are overtly normal, mice lacking Ron signaling have an altered ability to regulate nitric oxide levels and, in addition, have enhanced tissue damage following acute and cell-mediated inflammatory responses.

Tissue-specific deletion of Foxa2 in pancreatic beta cells results in hyperinsulinemic hypoglycemia

We have used conditional gene ablation to uncover a dramatic and unpredicted role for the winged-helix transcription factor Foxa2 (formerly HNF-3 beta) in pancreatic beta-cell differentiation and metabolism. Mice that lack Foxa2 specifically in beta cells (Foxa2(loxP/loxP); Ins.Cre mice) are severely hypoglycemic and show dysregulated insulin secretion in response to both glucose and amino acids. This inappropriate hypersecretion of insulin in the face of profound hypoglycemia mimics pathophysiological and molecular aspects of familial hyperinsulinism. We have identified the two subunits of the beta-cell ATP-sensitive K(+) channel (K(ATP)), the most frequently mutated genes linked to familial hyperinsulinism, as novel Foxa2 targets in islets. The Foxa2(loxP/loxP); Ins.Cre mice will serve as a unique model to investigate the regulation of insulin secretion by the beta cell and suggest the human FOXA2 as a candidate gene for familial hyperinsulinism.

Insulin resistance and a diabetes mellitus-like syndrome in mice lacking the protein kinase Akt2 (PKB beta)

Glucose homeostasis depends on insulin responsiveness in target tissues, most importantly, muscle and liver. The critical initial steps in insulin action include phosphorylation of scaffolding proteins and activation of phosphatidylinositol 3-kinase. These early events lead to activation of the serine-threonine protein kinase Akt, also known as protein kinase B. We show that mice deficient in Akt2 are impaired in the ability of insulin to lower blood glucose because of defects in the action of the hormone on liver and skeletal muscle. These data establish Akt2 as an essential gene in the maintenance of normal glucose homeostasis.

Fas-induced apoptosis in mouse hepatocytes is dependent on C/EBPbeta

Apoptotic cell death in the liver in response to activation of the Fas pathway has been implicated in human disease states as well as liver remodeling and tissue repair. C/EBPbeta, a member of the CCAAT enhancer binding protein family of bZIP transcription factors has been linked to both growth response and apoptotic targets in the liver, and, therefore, is a likely candidate for the regulation of apoptotic liver injury. We investigated differences in apoptotic cell death in the livers of C/EBPbeta-null mice using the Jo-2 agonistic anti-Fas antibody. Apoptotic injury was dramatically reduced in C/EBPbeta -/- livers as shown by a nearly 20-fold reduction in apoptotic hepatocytes 6 hours post-Jo-2 treatment in C/EBPbeta -/- hepatocytes compared with controls (P < .04) and reduced activation of caspase 3. Bid cleavage occurred in Jo-2 treated C/EBPbeta -/- livers indicating a block of Fas-induced injury distal to the death-inducing signaling complex. The level of the antiapoptotic protein bcl-x(L) was increased greater than tenfold in the mutant animals (P < .04), which can, at least in part, account for the protection from Fas-mediated apoptosis. In contrast, bcl-x(L) mRNA levels were unchanged. These observations link C/EBPbeta to Fas-induced hepatocyte apoptosis through a mechanism that likely involves translational or posttranslational regulation of bcl-x(L).

The hepatocyte nuclear factor 3 (HNF3 or FOXA) family in metabolism

The genes encoding hepatocyte nuclear factor 3 (HNF3) proteins play a pivotal role in the regulation of metabolism and in the differentiation of metabolic tissues such as the pancreas and liver. HNF3 transcription factors bind to cis-regulatory elements in hundreds of genes encoding gluconeogenic and glycolytic enzymes, serum proteins and hormones. Genetic analysis in mice has shown that HNF3 beta is necessary for the development of the foregut endoderm, from which the liver and pancreas arise. HNF3 alpha is required for the full activation of glucagon in the pancreas, whereas HNF3 gamma induces the activation of gluconeogenic enzymes to prevent hypoglycemia during fasting.

Hepatocyte nuclear factor 3beta (Foxa2) is dispensable for maintaining the differentiated state of the adult hepatocyte

Liver-specific gene expression is controlled by a heterogeneous group of hepatocyte-enriched transcription factors. One of these, the winged helix transcription factor hepatocyte nuclear factor 3beta (HNF3beta or Foxa2) is essential for multiple stages of embryonic development. Recently, HNF3beta has been shown to be an important regulator of other hepatocyte-enriched transcription factors as well as the expression of liver-specific structural genes. We have addressed the role of HNF3beta in maintenance of the hepatocyte phenotype by inactivation of HNF3beta in the liver. Remarkably, adult mice lacking HNF3beta expression specifically in hepatocytes are viable, with histologically normal livers and normal liver function. Moreover, analysis of >8,000 mRNAs by array hybridization revealed that lack of HNF3beta affects the expression of only very few genes. Based on earlier work it appears that HNF3beta plays a critical role in early liver development; however, our studies demonstrate that HNF3beta is not required for maintenance of the adult hepatocyte or for normal liver function. This is the first example of such functional dichotomy for a tissue specification transcription factor.

Identification of a mouse germ cell-less homologue with conserved activity in Drosophila

Drosophila Germ cell-less (Gcl) has previously been shown to be important in early events during the formation of pole cells, which are the germ cell precursors in the fly. We have isolated a 524 amino acid mouse gene with 32% identity and 49% similarity to Drosophila gcl, termed mgcl-1. Like Drosophila Gcl, mGcl-1 localizes to the nuclear envelope. Ectopic expression of mgcl-1 in Drosophila rescues the gcl-null phenotype, indicating that mGcl-1 is a functional homologue of Gcl. mgcl-1 maps to chromosome 6 at 47.3 cM, and is expressed at low levels at all embryonic stages examined from 8.5 to 18.5 d.p.c. as well as in many adult tissues. Different from Drosophila gcl, mgcl-1 is not highly expressed at the time the primordial germ cells appear in the mouse, but high mgcl-1 expression is found in selected mouse adult male germ cells. The differences in these expression patterns in light of conserved activity between the two genes is discussed.

Characterization of the structure and regulation of the murine gene encoding gut-enriched Krüppel-like factor (Krüppel-like factor 4)

Gut-enriched Krüppel-like factor (GKLF, KLF4) is an epithelial-specific transcription factor whose expression is associated with growth arrest. In order to understand the mechanisms regulating expression of the gene encoding GKLF, we isolated a genomic clone containing murine GKLF. The gene spans 5.3 kb and contains four exons. A major start site of transcription was mapped to an adenine residue 601 nt 5' of the translation initiation codon. An additional 1 kb of the 5'-flanking region was sequenced and found to contain multiple cis -elements homologous to the binding sites of several established transcription factors including Sp1, AP-1, Cdx, GATA, and USF. In particular, three closely spaced GC-boxes 5' of the TATA box resemble the established binding site for GKLF. DNase I protection and electrophoretic mobility shift assays verified that recombinant GKLF bound to each of the three GC-boxes. In co-transfection experiments, GKLF transactivated a reporter gene linked to the GKLF 1 kb 5'-flanking region, as did Sp1, Sp3 and Cdx-2. Mutations of one or both of the first and second GC-boxes in the promoter resulted in diminished transactivation by GKLF. These results demonstrate that the 5'-flanking sequence of the mouse GKLF gene functions as a promoter and is subject to autoregulation by its own gene product.

Inactivation of the winged helix transcription factor HNF3alpha affects glucose homeostasis and islet glucagon gene expression in vivo

Mice homozygous for a null mutation in the winged helix transcription factor HNF3alpha showed severe postnatal growth retardation followed by death between P2 and P12. Homozygous mutant mice were hypoglycemic despite unchanged expression of HNF3 target genes involved in hepatic gluconeogenesis. Whereas insulin and corticosteroid levels were altered as expected, plasma glucagon was reduced markedly in the mutant animals despite the hypoglycemia that should be expected to increase glucagon levels. This correlated with a 70% reduction in pancreatic proglucagon gene expression. We also showed that HNF3alpha could bind to and transactivate the proglucagon gene promoter. These observations invoke a central role for HNF3alpha in the regulatory control of islet genes essential for glucose homeostasis in vivo.

Glucocorticoid receptor, C/EBP, HNF3, and protein kinase A coordinately activate the glucocorticoid response unit of the carbamoylphosphate synthetase I gene

A single far-upstream enhancer is sufficient to confer hepatocyte-specific, glucocorticoid- and cyclic AMP-inducible periportal expression to the carbamoylphosphate synthetase I (CPS) gene. To identify the mechanism of hormone-dependent activation, the composition and function of the enhancer have been analyzed. DNase I protection and gel mobility shift assays revealed the presence of a cyclic AMP response element, a glucocorticoid response element (GRE), and several sites for the liver-enriched transcription factor families HNF3 and C/EBP. The in vivo relevance of the transcription factors interacting with the enhancer in the regulation of CPS expression in the liver was assessed by the analysis of knockout mice. A strong reduction of CPS mRNA levels was observed in glucocorticoid receptor- and C/EBPalpha-deficient mice, whereas the CPS mRNA was normally expressed in C/EBPbeta knockout mice and in HNF3alpha and -gamma double-knockout mice. (The role of HNFbeta could not be assessed, because the corresponding knockout mice die at embryonic day 10). In hepatoma cells, most of the activity of the enhancer is contained within a 103-bp fragment, which depends for its activity on the simultaneous occupation of the GRE, HNF3, and C/EBP sites, thus meeting the requirement of a glucocorticoid response unit. In fibroblast-like CHO cells, on the other hand, the GRE in the CPS enhancer does not cooperate with the C/EBP and HNF3 elements in transactivation of the CPS promoter. In both hepatoma and CHO cells, stimulation of expression by cyclic AMP depends mainly on the integrity of the glucocorticoid pathway, demonstrating cross talk between this pathway and the cyclic AMP (protein kinase A) pathway.

The mouse Fkh1/Mf1 gene: cDNA sequence, chromosomal localization and expression in adult tissues

The 'winged helix' or 'forkhead' transcription factor gene family is defined by a common 100-amino-acid DNA-binding motif. Here, we describe the chromosomal position, start site of transcription, sequence and adult expression pattern of the mouse Fkh1/Mf1 (Forkhead homologue 1/mesoderm/mesenchyme forkhead 1) gene. This gene contains one exon and encodes a protein of 553 amino acids that is highly related to the mouse MFH1 protein. The Fkh1/Mf1 mRNA is expressed widely in adult tissues. Linkage analysis showed that the Fkh1/Mf1 gene is localized to chromosome 13 at 17.02cM from the centromer, in close proximity to Bmp6 and Hfh1, another distinct member of the winged helix gene family.

The winged helix transcription factor Hfh2 is expressed in neural crest and spinal cord during mouse development

The embryonic neural crest is a unique group of cells that gives rise to the peripheral nervous system as well as many other cell types. Most of the work describing the behavior and specification of these cells has been done in the avian system, a system amenable to experimental manipulations such as tissue grafting, cell transplantation and lineage tracing. This work has been greatly facilitated by the use of molecular markers of neural crest cells such as HNK-1 and slug, markers that are not yet available for the study of mouse neural crest. Here we demonstrate that Hfh2 (HNF3 forkhead homologue 2), a member of the 'winged helix' or 'forkhead' transcription factor gene family, is expressed in premigratory and migrating neural crest cells in the early mouse embryo and in motorneuron progenitors in the developing spinal cord. Using linkage analysis we have localized the Hfh2 gene to chromosome 4 at 44.91 cM from the centromere.

Targeted disruption of the gene encoding hepatocyte nuclear factor 3gamma results in reduced transcription of hepatocyte-specific genes

The winged helix transcription factor hepatocyte nuclear factor 3gamma (HNF3gamma) is expressed in embryonic endoderm and its derivatives liver, pancreas, stomach, and intestine, as well as in testis and ovary. We have generated mice carrying an Hnf3g-lacZ fusion which deletes most of the HNF3gamma coding sequence as well as 5.5 kb of 3' flanking region. Mice homozygous for the mutation are fertile, develop normally, and show no morphological defects. The mild phenotype change of the Hnf3g-/- mice can be explained in part by an upregulation of HNF3alpha and HNF3beta in the liver of the mutant animals. Analysis of steady-state mRNA levels as well as transcription rates showed that levels of expression of several HNF3 target genes (phosphoenolpyruvate carboxykinase, transferrin, tyrosine aminotransferase) were reduced by 50 to 70%, indicating that HNF3gamma is an important activator of these genes in vivo.

DNA binding of the glucocorticoid receptor is not essential for survival

Transcriptional regulation by the glucocorticoid receptor (GR) is essential for survival. Since the GR can influence transcription both through DNA-binding-dependent and -independent mechanisms, we attempted to assess their relative importance in vivo. In order to separate these modes of action, we introduced the point mutation A458T into the GR by gene targeting using the Cre/loxP system. This mutation impairs dimerization and therefore GRE-dependent transactivation while functions that require cross-talk with other transcription factors, such as transrepression of AP-1-driven genes, remain intact. In contrast to GR-/- mice, these mutants termed GRdim are viable, revealing the in vivo relevance of DNA-binding-independent activities of the GR.

Analysis of glucocorticoid signalling by gene targeting

Glucocorticoids are involved in the regulation of numerous physiological processes. The majority of these effects are thought to be mediated by the glucocorticoid receptor (GR) via activation and repression of gene expression. In most cases activation requires binding of a receptor-dimer to DNA while repression is mediated by protein-protein-interaction of GR-monomers with other transcription factors. To analyse the molecular mechanisms that underlie glucocorticoid effects, mouse mutations in the GR gene were generated and analysed. In order to address the role of glucocorticoid receptor signalling during development and in physiology, the gene was disrupted by gene targeting. Most of the mice homozygous for the mutation die shortly after birth due to severe lung atelectasis. Additional defects were found in the adrenals, liver, brain, bone marrow and thymus as well as in the feedback-regulation of the HPA-axis. To approach the question which functions of the GR are regulated by DNA-binding and which by protein-protein-interaction, a point mutation was introduced into the dimerization domain of the GR which is located in the DNA-binding domain. By homologous recombination in ES-cells using the Cre/loxP-system, mice carrying this mutation were generated [GR(dim) mice]. The mice are fully viable although they show impaired inducibility of gluconeogenetic enzymes in liver, defects in longterm renewal of erythroid progenitors and increased expression of POMC and ACTH in the pituitary. However neither in the lung nor the adrenals were any histological abnormalities found. In conclusion GR(dim)-mice represent a valuable tool to further analyse mechanisms of physiological effects of the GR.

Expression of the mouse Fkh1/Mf1 and Mfh1 genes in late gestation embryos is restricted to mesoderm derivatives

We have compared the expression patterns of the mouse Forkhead homologue 1/ mesoderm/mesenchyme forkhead 1 (Fkh1/Mf1) gene with that of the highly related winged helix gene Mfh1 in late gestation mouse embryos. Transcripts for both genes are restricted to derivatives of the mesoderm. Co-expression was found in cartilage primordia of the head, ribs, vertebra and bones. However, in several structures analyzed, Fkh1/Mf1 signals are lower in the inner layers of the developing cartilage than those of Mfh1.

The mesenchymal winged helix transcription factor Fkh6 is required for the control of gastrointestinal proliferation and differentiation

The winged helix transcription factor Fkh6 is expressed in the mesoderm of the gastrointestinal tract directly adjacent to the endoderm-derived epithelium. Homozygous null mice for Fkh6 showed postnatal growth retardation secondary to severe structural abnormalities of the stomach, duodenum, and jejunum. Dysregulation of epithelial cell proliferation in these organs resulted in an approximately fourfold increase in the number of dividing intestinal epithelial cells and marked expansion of the proliferative zone. As a consequence, the tissue architecture of the stomach and small intestine was distorted, with abnormal crypt structure, formation of mucin filled cysts, and lengthening of villi. Changes in the cellular phenotype and composition of the gastric and intestinal epithelia also suggests that epithelial cell-lineage allocation or differentiation may be affected by loss of Fkh6. From the analysis of a number of potential signaling molecules, we found Bmp2 and Bmp4 expression reduced in the gastrointestinal tract of Fkh6 mutant mice, suggesting that Fkh6 directs a signaling cascade that mediates communication between the mesenchyme and endoderm of the gut to regulate cell proliferation.

Transcriptional regulation in endoderm development: characterization of an enhancer controlling Hnf3g expression by transgenesis and targeted mutagenesis

The hepatic nuclear factor 3gamma (Hnf3g) is a member of the winged helix gene family of transcription factors and is thought to be involved in anterior-posterior regionalization of the primitive gut. In this study, cis-regulatory elements essential for the expression of Hnf3g in vivo have been characterized. To this end, a 170 kb yeast artificial chromosome (YAC) carrying the entire Hnf3g locus was isolated and modified with a lacZ reporter gene. The two mouse lines carrying the unfragmented Hnf3g-lacZ YAC showed tissue-specific, copy number-dependent and position-independent expression, proving that 170 kb of the Hnf3g locus contain all elements important in the regulation of Hnf3g. Cis-regulatory elements necessary for expression of Hnf3g were identified in a three-step procedure. First, DNase I hypersensitive site mapping was used to delineate important chromatin regions around the gene required for tissue-specific activation of Hnf3g. Second, plasmid-derived transgenes and gene targeting of the endogenous Hnf3g gene locus were used to demonstrate that the 3'-flanking region of the gene is necessary and sufficient to direct reporter gene expression in liver, pancreas, stomach and small intestine. Third, a binding site for HNF-1alpha and beta, factors expressed in organs derived from the endoderm such as liver, gut and pancreas, was identified in this 3'-enhancer and shown to be crucial for enhancer function in vitro. Based on its expression pattern we inferred that HNF-1beta is a likely candidate for directly activating Hnf3g gene expression during development.

The mesenchymal winged helix transcription factor Fkh6 is required for the control of gastrointestinal proliferation and differentiation

The winged helix transcription factor Fkh6 is expressed in the mesoderm of the gastrointestinal tract directly adjacent to the endoderm-derived epithelium. Homozygous null mice for Fkh6 showed postnatal growth retardation secondary to severe structural abnormalities of the stomach, duodenum, and jejunum. Dysregulation of epithelial cell proliferation in these organs resulted in an approximately fourfold increase in the number of dividing intestinal epithelial cells and marked expansion of the proliferative zone. As a consequence, the tissue architecture of the stomach and small intestine was distorted, with abnormal crypt structure, formation of mucin filled cysts, and lengthening of villi. Changes in the cellular phenotype and composition of the gastric and intestinal epithelia also suggests that epithelial cell-lineage allocation or differentiation may be affected by loss of Fkh6. From the analysis of a number of potential signaling molecules, we found Bmp2 and Bmp4 expression reduced in the gastrointestinal tract of Fkh6 mutant mice, suggesting that Fkh6 directs a signaling cascade that mediates communication between the mesenchyme and endoderm of the gut to regulate cell proliferation.

Clustered arrangement of winged helix genes fkh-6 and MFH-1: possible implications for mesoderm development

The ‘winged helix’ or ‘forkhead’ transcription factor gene family is defined by a common 100 amino acid DNA binding domain which is a variant of the helix-turn-helix motif. Here we describe the structure and expression of the mouse fkh-6 and MFH-1 genes. Both genes are expressed in embryonic mesoderm from the headfold stage onward. Transcripts for both genes are localised mainly to mesenchymal tissues, fkh-6 mRNA is enriched in the mesenchyme of the gut, lung, tongue and head, whereas MFH-1 is expressed in somitic mesoderm, in the endocardium and blood vessels as well as the condensing mesenchyme of the bones and kidney and in head mesenchyme. Both genes are located within a 10 kb region (in mouse chromosome 8 at 5.26 +/− 2.56 cM telomeric to Actsk1. The close physical linkage of these two winged helix genes is conserved in man, where the two genes map to chromosome 16q22-24. This tandem arrangement suggests the common use of regulatory mechanisms. The fkh-6/MFH-1 locus maps close to the mouse mutation amputated, which is characterised by abnormal development of somitic and facial mesoderm. Based on the expression patterns we suggest that a mutation in MFH-1, not fkh-6 is the possible cause for the amputated phenotype.

The mouse homolog of the region specific homeotic gene spalt of Drosophila is expressed in the developing nervous system and in mesoderm-derived structures

The region specific homeotic gene spalt (sal) of Drosophila determines the specification of terminal segments. Its mutation leads to an incomplete transformation of terminal segments into trunk-like segments. The gene product is a zinc finger protein with a novel structure. We have isolated the mouse homolog of the Drosophila spalt gene (msal). The msal cDNA sequence is similar to its Drosophila counterpart in that it contains seven C2H2-type zinc finger motifs grouped into three pairs plus a single zinc finger closely linked to the middle pair. The two genes exhibit high sequence similarity in the zinc finger regions and to a lower extent in the putative transactivation domains. We have analysed the expression pattern of msal and show that it is expressed in the developing neuroectoderm of the brain, the inner ear and the spinal cord and in urogenital ridge-derived structures such as testis, ovaries and kidneys. A weaker and transient expression is seen in early embryos in the branchial arches and in tissues like the notochord, the limb buds and the heart. Given its role in Drosophila melanogaster and its strong sequence conservation, this expression pattern suggests an important role for msal in the development of the nervous system.

Expression of the winged helix genes fkh-4 and fkh-5 defines domains in the central nervous system

The 'winged helix' or 'forkhead' transcription factor gene family is defined by a common 100 amino acid DNA binding domain which is a variant of the helix-turn-helix motif. Here we describe the structure and expression of the mouse fkh-4 and fkh-5 genes. The two genes encode proteins of 427 and 324 amino acids, respectively, with highly similar winged helix domains. Both genes are expressed in adjacent domains in the developing diencephalon from the headfold stage onward. Linkage analysis localised fkh-5 to chromosome 9 at 34.5 centiMorgans (cM) and fkh-4 to chromosome 19 at 10.5 cM. The potential relationship of the two genes to the mouse mutations staggerer and small thymus (for fkh-5) and muscle deficient (for fkh-4) is discussed.

Severe impairment of spermatogenesis in mice lacking the CREM gene

Spermatogenesis is a complex developmental process that occurs in several phases. A large number of genes have been identified that are expressed during spermatogenesis, but the biological significance of many of these is not yet known. We have used gene targeting to selectively eliminate the transcription factor CREM (cyclic AMP- responsive element modulator), which is thought to be important for mammalian spermatogenesis. Male mice deficient for all CREM proteins are sterile, as their developing spermatids fail to differentiate into sperm, and postmeiotic gene expression in the testis declines dramatically. The cessation of sperm development is not accompanied by decreases in the levels of follicle-stimulating hormone or testosterone. Our findings indicate that the CREM gene is essential for spermatogenesis, and mice deficient for this transcription factor could serve as a model system for the study of idiopathic infertility in men.

Targeting of the CREB gene leads to up-regulation of a novel CREB mRNA isoform

To define the role of cAMP signaling in gene control, we have generated mice with a mutation in the cAMP response element binding protein (CREB) gene. Mice carrying this mutation are viable but show an impairment in memory consolidation. In further analysis of these mice, we have found an up-regulation of a CREB isoform that has not been described previously . The new isoform, termed CREB beta, has nearly the same transactivation potential as the other CREB isoforms and is expressed ubiquitously. The up-regulation appears to be due to an increase in alternative splicing or mRNA stability, but not to an increase in transcriptional rate. Due to the relatively low levels of expression in all tissues, the role of this isoform is likely to be minor in the wild-type mouse. However, its dramatic up-regulation in the mutant mouse, together with the specific deficiencies recently observed in these mice, suggest that it has a very specific role in compensating for CREB alpha and delta in some, but not all, areas where CREB function has been implicated. Together with the up-regulation of the cAMP response element modulator protein (CREM) mRNA and protein levels demonstrated previously in CREB mutant mice, we suggest that the up-regulation of CREB beta may also contribute to compensation within the CREB/ATF family of transcription factors, when CREB delta and CREB alpha are absent.

The mouse fkh-2 gene. Implications for notochord, foregut, and midbrain regionalization

The "winged helix" or "forkhead" transcription factors comprise a large gene family whose members are defined by a common 100-amino acid DNA binding domain. Here we describe the structure and expression of the mouse fkh-2 gene, which encodes a protein of 48 kDa with high similarity to other winged helix transcription factors within the DNA binding region, but unique potential transactivation domains. The gene is encoded by a single exon and is expressed in headfold stage embryos in the notochord, the anterior neuroectoderm, and a few cells of the definite endoderm. This expression becomes restricted to the anteriormost portions of the invaginating foregut and the developing midbrain. From day 11.5 of gestation onward, fkh-2 transcripts are restricted to the midbrain and become progressively localized to the red nuclei as the sole site of expression. The fkh-2 gene maps to chromosome 19B and is a candidate gene for the mouse mutation mdf (muscle-deficient) which is characterized by nervous tremors and degeneration of the hindlimb muscles. Although the expression patterns of the fkh-2 gene and another winged helix protein, HNF-3 beta, are overlapping in early stages of gestation and although the promoter of the fkh-2 gene contains a HNF-3 binding site, we demonstrate that the activation of the fkh-2 gene is independent of HNF-3 beta.

Universal beta-galactosidase cloning vectors for promoter analysis and gene targeting

Two new plasmid vectors suitable for generating fusions with the lacZ gene have been developed and tested. The vectors can be applied in the analysis of regulatory elements of eukaryotic genes in both transient and stable transfection experiments. In addition, they can be utilized as the backbone of gene targeting vectors, allowing the assessment of the expression pattern of the targeted gene by staining for beta-galactosidase activity.

The HNF-3 gene family of transcription factors in mice: gene structure, cDNA sequence, and mRNA distribution

The rat HNF-3 (hepatocyte nuclear factor 3) gene family encodes three transcription factors known to be important in the regulation of gene expression in liver and lung. We have cloned and characterized the mouse genes and cDNAs for HNF-3 alpha, beta, and gamma and analyzed their expression patterns in various adult tissues and mouse embryonic stages. The HNF-3 proteins are highly conserved between mouse and rat, with the exception of the amino terminus of HNF-3 gamma, which in mouse is more similar to those of HNF-3 alpha and beta than to the amino termini of the rat HNF-3 gamma protein. The mouse HNF-3 genes are small and contain only two or three (HNF-3 beta) exons with conserved intron-exon boundaries. The proximal promoter of the mouse HNF-3 beta gene is remarkably similar to that of the previously cloned rat HNF-3 beta gene, but is different from the promoters of the HNF-3 alpha and gamma genes. The mRNA distribution of the mouse HNF-3 genes was analyzed by quantitative RNase protection with gene-specific probes. While HNF-3 alpha and beta are restricted mainly to endoderm-derived tissues (lung, liver, stomach, and small intestine), HNF-3 gamma is more extensively expressed, being present additionally in ovary, testis, heart, and adipose tissue, but missing from lung. Transcripts for HNF-3 beta and alpha are detected most abundantly in midgestation embryos (Day 9.5), while HNF-3 gamma expression peaks around Day 15.5 of gestation.

Postimplantation expression patterns indicate a role for the mouse forkhead/HNF-3 alpha, beta and gamma genes in determination of the definitive endoderm, chordamesoderm and neuroectoderm

The HNF-3 alpha, beta and gamma genes constitute a family of transcription factors that are required for hepatocyte-specific gene expression of a number of genes, e.g. transthyretin, alpha-1 antitrypsin and tyrosine aminotransferase. These genes share a highly conserved DNA-binding domain first found in the Drosophila gene, forkhead, which is required for the normal patterning of the developing gut and central nervous system in Drosophila. In adult mouse tissues, transcripts from HNF-3 alpha and beta have been localised to the liver, intestine and lung, whereas HNF-3 gamma is found in the liver, intestine and testis. In light of the early developmental significance of forkhead in Drosophila, we have compared the patterns of expression of HNF-3 alpha, beta and gamma mRNAs during murine embryogenesis. We find that these genes are sequentially activated during development in the definitive endoderm. HNF-3 beta mRNA is expressed in the node at the anterior end of the primitive streak in all three germ layers and is the first gene of this family to be activated. Subsequently, HNF-3 alpha is transcribed in the primitive endoderm in the region of the invaginating foregut and HNF-3 gamma appears upon hindgut differentiation. These genes have different anterior boundaries of mRNA expression in the developing endoderm and transcripts are found in all endoderm-derived structures that differentiate posterior to this boundary. Therefore, we propose that these genes define regionalization within the definitive endoderm. Furthermore, differential mRNA expression of HNF-3 alpha and beta is detected in cells of the ventral neural epithelium, chordamesoderm and notochord. In the neural epithelium, expression of HNF-3 alpha and beta mRNA becomes localised to cells of the floor plate. We propose that, in addition to their characterised requirement for liver-specific gene expression, HNF-3 alpha and beta are required for mesoderm and neural axis formation. We also conclude that HNF-3 beta is the true orthologue of the Drosophila forkhead gene.

Cyclic AMP-induced transcriptional repression of the insulin-responsive glucose transporter (GLUT4) gene: identification of a promoter region required for down-regulation of transcription

The mechanism(s) by which cyclic AMP represses transcription of the GLUT4 gene was investigated. 3T3-L1 preadipocytes were stably transfected with a series of 5' deletion mutants of the mouse GLUT4 gene promoter fused to the bacterial CAT gene and then were induced to differentiate into adipocytes. A method based on reverse transcription/polymerase chain reaction (PCR) amplification was developed and optimized to quantitate expression of CAT mRNA transcripts. Treatment with 8-bromo-cAMP down-regulated the level of CAT mRNA in adipocytes transfected with the -7000/CAT, -785/CAT and -469/CAT constructs, but not the -78/CAT construct. Thus, the regulatory element(s) which mediates transcriptional repression by cAMP resides in the proximal promoter of the GLUT4 gene between positions -469 and -78. Since down-regulation of GLUT4 mRNA is unaffected by inhibitors of protein synthesis, cAMP (and insulin) may activate phosphorylation or dephosphorylation of an existing transcription factor that interacts with the GLUT4 proximal promoter.

Six members of the mouse forkhead gene family are developmentally regulated

The 110-aa forkhead domain defines a class of transcription factors that have been shown to be developmentally regulated in Drosophila melanogaster and Xenopus laevis. The forkhead domain is necessary and sufficient for target DNA binding as shown for the rat hepatic nuclear factor 3 (HNF3) gene family. We have cloned six forkhead gene family members from a mouse genomic library in addition to the mouse equivalents of the genes for HNF3 alpha, -beta, and -gamma. The six genes, termed fkh-1 to fkh-6, share a high degree of similarity with the Drosophila forkhead gene, having 57-67% amino acid identity within the forkhead domain. fkh-1 seems to be the mammalian homologue of the Drosophila FD1 gene, as the sequences are 86% identical. fkh-1 to fkh-6 show distinct spatial patterns of expression in adult tissues and are expressed during embryogenesis.

Regulated expression of an insulin-responsive glucose transporter (GLUT4) minigene in 3T3-L1 adipocytes and transgenic mice

Preliminary studies showed that up to 7 kb of 5' flanking sequence of the insulin-responsive glucose transporter (GLUT4) gene are insufficient to mediate differentiation-induced reporter gene expression in mouse 3T3-L1 preadipocytes. To locate the regulatory element(s) responsible for this function, a minigene containing the entire GLUT4 gene with substantial 5' and 3' flanking sequence and a short segment of foreign DNA (for transcript identification) was constructed and transfected into mice and 3T3-L1 preadipocytes at relatively low copy number. In transgenic mice the GLUT4 minigene exhibited a pattern of tissue-specific expression similar, but not identical, to that of the endogenous gene. In 3T3-L1 cells expression of minigene mRNA occurred upon differentiation into adipocytes, with kinetics virtually identical to that of endogenous GLUT4 mRNA. In both cultured adipocytes and transgenic mice, the level of expression of the minigene was low relative to that of the endogenous gene. Treatment of minigene-transfected 3T3-L1 adipocytes with 8-bromo-cAMP, which represses transcription of the endogenous GLUT4 gene, also repressed expression of the GLUT4 minigene. However, insulin, which down-regulates transcription of the endogenous GLUT4 gene, failed to normally down-regulate expression of the GLUT4 minigene. These findings indicate that the cis-acting elements required for directing tissue-specific expression (in heart, skeletal muscle, and brown adipose tissue), differentiation-induced activation of transcription, and cAMP-induced repression of transcription are located within the 14-kb GLUT4 minigene. However, the cis elements necessary for maximal tissue-specific expression and for insulin-induced down-regulation of expression are not located in the minigene.