Glucose regulates MafA transcription factor abundance and insulin gene expression by inhibiting AMP-activated protein kinase in pancreatic ß-cells.

Insulin mRNA expression in pancreatic islet ß-cells is up-regulated by extracellular glucose concentration, but the underlying mechanism remains incompletely understood. MafA is a transcriptional activator specifically enriched in ß-cells that binds to the insulin gene promoter. Its expression is transcriptionally and posttranscriptionally regulated by glucose. Moreover, AMP-activated protein kinase (AMPK), a regulator of cellular energy homeostasis, is inhibited by high glucose, and this inhibition is essential for the up-regulation of insulin gene expression and glucose-stimulated insulin secretion (GSIS). Here we mutagenized the insulin promoter and found that the MafA-binding element C1/RIPE3b is required for glucose- or AMPK-induced alterations in insulin gene promoter activity. Under high-glucose conditions, pharmacological activation of AMPK in isolated mouse islets or MIN6 cells by metformin or 5-aminoimidazole-4-carboxamide riboside decreased MafA protein levels and mRNA expression of insulin and GSIS-related genes (i.e. glut2 and sur1). Overexpression of constitutively active AMPK also reduced MafA and insulin expression. Conversely, pharmacological AMPK inhibition by dorsomorphin (compound C) or expression of a dominant-negative form of AMPK increased MafA and insulin expression under low-glucose conditions. However, AMPK activation or inhibition did not change the expression levels of the ß-cell-enriched transcription factors Pdx1 and Beta2/NeuroD1. AMPK activation accelerated MafA protein degradation, which is not dependent on the proteasome. We also noted that MafA overexpression prevents metformin-induced decreases in insulin and GSIS-related gene expression. These findings indicate that high glucose concentrations inhibit AMPK, thereby increasing MafA protein levels and activating the insulin promoter.

Dimeric combinations of MafB, cFos and cJun control the apoptosis-survival balance in limb morphogenesis.

Apoptosis is an important mechanism for sculpting morphology. However, the molecular cascades that control apoptosis in developing limb buds remain largely unclear. Here, we show that MafB was specifically expressed in apoptotic regions of chick limb buds, and MafB/cFos heterodimers repressed apoptosis, whereas MafB/cJun heterodimers promoted apoptosis for sculpting the shape of the limbs. Chromatin immunoprecipitation sequencing in chick limb buds identified potential target genes and regulatory elements controlled by Maf and Jun. Functional analyses revealed that expression of p63 and p73, key components known to arrest the cell cycle, was directly activated by MafB and cJun. Our data suggest that dimeric combinations of MafB, cFos and cJun in developing chick limb buds control the number of apoptotic cells, and that MafB/cJun heterodimers lead to apoptosis via activation of p63 and p73.

Ectopic expression of the transcription factor MafB in basal keratinocytes induces hyperproliferation and perturbs epidermal homeostasis.

Mammalian epidermis is composed of four morphologically and functionally distinct layers of keratinocytes. The innermost basal layer consists of proliferating self-renewing keratinocytes, which also undergo asymmetric cell division to differentiate into postmitotic suprabasal cells throughout life. Control of the balance between growth and differentiation of basal cells is important for epidermal homeostasis to prevent skin disorders including malignancies; however, the underlying mechanism remains to be elucidated. Recently, MafB was identified as one of the transcription factors that regulate epidermal keratinocyte differentiation. MafB is expressed in postmitotic differentiating keratinocytes, and epidermal differentiation is partially impaired in MafB-deficient mice. To further establish the roles of MafB in the epidermis in vivo, we generated mice transgenic for MafB under the control of the basal cell-specific keratin (Krt) 14 promoter. In the epidermis of transgenic mice at embryonic day 18.5, the number of proliferating Krt14-positive basal-like cells was increased, and the granular and cornified layers were thickened. Furthermore, these MafB transgenic mice developed papillomas spontaneously with age. Therefore, MafB promotes differentiation in postmitotic keratinocytes and simultaneously has potential to promote growth when ectopically expressed in undifferentiated basal keratinocytes.

CREB activates the MafA promoter through proximal E-boxes and a CCAAT motif in pancreatic ß-cells.

MafA is a key transcriptional regulator of pancreatic islet ß-cell function. Its target genes include those encoding preproinsulin and the glucose transporter Glut2 (Slc2a2); thus, MafA function is essential for glucose-stimulated insulin secretion. Expression levels of MafA are reduced in ß-cells of diabetic mouse models and human subjects, suggesting that ß-cell dysfunction associated with type 2 diabetes is attributable to the loss of MafA. On the other hand, MafA is transcriptionally upregulated by incretin hormones through activation of CREB and its co-activator CRTC2. ß-cell-specific expression of MafA relies on a distal enhancer element. However, the precise mechanism by which CREB-CRTC2 regulates the enhancer and proximal promoter regions of MafA remains unclear. In this report, we analyzed previously published ChIP-seq data and found that CREB and NeuroD1, a ß-cell-enriched transactivator, bound to both the promoter and enhancer regions of human MAFA. A series of reporter assays revealed that CREB activated the enhancer through a conserved cAMP-responsive element (CRE) but stimulated MAFA promoter activity even when the putative CRE was deleted. Two E-box elements and a CCAAT motif, which bind NeuroD1 and ubiquitous NF-Y transcription factors, respectively, were necessary for transcriptional activation of the MAFA promoter by CREB. Genome-wide analysis of CREB-bound loci in ß-cells revealed that they were enriched with CCAAT motifs. Furthermore, promoter analysis of the Isl1 gene encoding a ß-cell-enriched transcription factor revealed that a CRE-like element and two CCAAT motifs, but not the E-box, were necessary for activation by CREB. These results provide clues to elucidate the detailed mechanism by which CREB regulates MafA as well as ß-cell-specific genes.

ATF2 interacts with beta-cell-enriched transcription factors, MafA, Pdx1, and beta2, and activates insulin gene transcription.

Pancreatic ß-cell-restricted expression of insulin is established through several critical cis-regulatory elements located in the insulin gene promoter region. The principal cis elements are A-boxes, E1, and C1/RIPE3b. The ß-cell-enriched transcription factors Pdx1 and Beta2 bind to the A-boxes and E1 element, respectively. A ß-cell-specific trans-acting factor binding to C1/RIPE3b (termed RIPE3b1 activator) was detected by electrophoretic mobility shift assay and has been identified as MafA, a member of the Maf family of basic leucine zipper (bZip) proteins. Here, ATF2, a member of the ATF/CREB family of basic leucine zipper proteins, was identified as a component of the RIPE3b1 activator. ATF2 alone was unable to bind to the C1/RIPE3b element but acquired binding capacity upon complex formation with MafA. ATF2 also interacted with Pdx1 and Beta2, and co-expression of ATF2, MafA, Pdx1, and Beta2 resulted in a synergistic activation of the insulin promoter. Immunohistochemical analysis of mouse pancreas tissue sections showed that ATF2 is enriched in islet endocrine cells, including ß-cells. RNAi-mediated knockdown of MafA or ATF2 in the MIN6 ß-cell line resulted in a significant decrease in endogenous levels of insulin mRNA. These data indicate that ATF2 is an essential component of the positive regulators of the insulin gene expression.

SUMOylation negatively regulates transcriptional and oncogenic activities of MafA.

Dysregulated expression of Maf proteins (namely c-Maf, MafA and MafB) leads to multiple myeloma in humans and oncogenic transformation of chicken embryonic fibroblasts. Maf proteins are transcriptional activators of tissue-specific gene expression and regulators of cell differentiation. For example, MafA is a critical regulator of crystallin genes and the lens differentiation program in chickens. In mammals, MafA is essential for the development of mature insulin-producing beta-cells of pancreas. It has been shown that MafA protein stability is regulated by phosphorylations at multiple serine and threonine residues. Here, we report that Maf proteins are also post-translationally modified by small ubiquitin-like modifier (SUMO) proteins at a conserved lysine residue in the amino-terminal transactivator domain. A SUMOylation-deficient mutant of MafA (K32R) was more potent than wild-type MafA in transactivating luciferase reporter construct driven by alphaA-crystallin or insulin gene promoter. In ovo electroporation into developing chicken embryo showed that the K32R mutant induced ectopic delta-crystallin gene expression more efficiently than the wild-type MafA. We also demonstrated that the K32R mutant had enhanced ability to induce colony formation of a chicken fibroblast cell line DF-1. Therefore, SUMOylation is a functional post-translational modification of MafA that negatively regulates its transcriptional and transforming activities.

MafA, NeuroD1, and HNF1ß synergistically activate the Slc2a2 (Glut2) gene in ß-cells.

Glucose transporter type 2 (GLUT2), encoded by the SLC2A2 gene, is an essential component of glucose-stimulated insulin secretion in pancreatic islet ß-cells. Like that of the gene encoding insulin, expression of the SLC2A2 gene expression is closely linked to ß-cell functionality in rodents, but the mechanism by which ß-cell-specific expression of SLC2A2 is controlled remains unclear. In this report, to identify putative enhancer elements of the mouse Slc2a2 gene, we examined evolutional conservation of the nucleotide sequence of its genomic locus, together with ChIP-seq data of histone modifications and various transcription factors published in previous studies. Using luciferase reporter assays, we found that an evolutionarily conserved region (ECR) located approximately 40 kbp downstream of the transcription start site of Slc2a2 functions as an active enhancer in the MIN6 ß-cell line. We also found that three ß-cell-enriched transcription factors, MafA, NeuroD1, and HNF1ß, synergistically activate transcription through this 3' downstream distal enhancer (ECR3') and the proximal promoter region of the gene. Our data also indicate that the simultaneous binding of HNF1ß to its target sites within the promoter and ECR3' of Slc2a2 is indispensable for transcriptional activation, and that binding of MafA and NeuroD1 to their respective target sites within the ECR3' enhances transcription. Co-immunoprecipitation experiments suggested that MafA, NeuroD1, and HNF1ß interact with each other. Overall, these results suggest that promoter-enhancer communication through MafA, NeuroD1, and HNF1ß is critical for Slc2a2 gene expression. These findings provide clues to help elucidate the mechanism of regulation of Slc2a2 gene expression in ß-cells.

MafA stability in pancreatic beta cells is regulated by glucose and is dependent on its constitutive phosphorylation at multiple sites by glycogen synthase kinase 3.

Regulation of insulin gene expression by glucose in pancreatic beta cells is largely dependent on a cis-regulatory element, termed RIPE3b/C1, in the insulin gene promoter. MafA, a member of the Maf family of basic leucine zipper (bZip) proteins, is a beta-cell-specific transcriptional activator that binds to the C1 element. Based on increased C1-binding activity, MafA protein levels appear to be up-regulated in response to glucose, but the underlying molecular mechanism for this is not well understood. In this study, we show evidence supporting that the amino-terminal region of MafA is phosphorylated at multiple sites by glycogen synthase kinase 3 (GSK3) in beta cells. Mutational analysis of MafA and pharmacological inhibition of GSK3 in MIN6 beta cells strongly suggest that the rate of MafA protein degradation is regulated by glucose, that MafA is constitutively phosphorylated by GSK3, and that phosphorylation is a prerequisite for rapid degradation of MafA under low-glucose conditions. Our data suggest a new glucose-sensing signaling pathway in islet beta cells that regulates insulin gene expression through the regulation of MafA protein stability.

PIASy is a SUMOylation-independent negative regulator of the insulin transactivator MafA.

Insulin plays a central role in glucose homeostasis and is produced exclusively by pancreatic islet ß-cells. Insulin gene transcription is regulated by a set of ß-cell-enriched transcription factors that bind to cis-regulatory elements within the promoter region, and regulation of the insulin gene promoter is closely linked to ß-cell functionality. PIASy, a member of the PIAS family of SUMO E3 ligases, is thought to affect insulin gene transcription, but its mechanism of action is not fully understood. Here, we demonstrate that PIASy interacts with MafA and represses insulin gene promoter activity. MafA is a ß-cell-restricted basic leucine-zipper transcriptional activator that binds to the C1 element of the insulin gene promoter. In line with previous studies showing the transactivator domain of MafA is SUMOylated, PIASy enhanced the SUMOylation of MafA. However, a SUMOylation-deficient mutant of MafA was still repressed by PIASy, indicating that this modification is dispensable for repression. Using a series of MafA and PIASy mutants, we found that the basic domain of MafA and the amino-terminal region of PIASy containing the SAP domain are necessary for their interaction. In addition, SUMO-interacting motif 1 (SIM1) at the carboxyl-terminal region of PIASy was required to repress the synergistic transactivation of MafA, Pdx1, and Beta2, transcription factors playing central roles in ß-cell differentiation and function. The PINIT and SP-RING domains in the middle region of PIASy were dispensable. These findings suggest that PIASy binds to MafA through the SAP domain and negatively regulates the insulin gene promoter through a novel SIM1-dependent mechanism.

Engineering of SV40-based nano-capsules for delivery of heterologous proteins as fusions with the minor capsid proteins VP2/3.

The capsid of SV40 is regarded as a potential nano-capsule for delivery of biologically active materials. The SV40 capsid is composed of 72 pentamers of the VP1 major capsid protein and 72 copies of the minor coat proteins VP2/3. We have previously demonstrated that, when expressed in insect Sf9 cells by the baculovirus system, VP1 self-assembles into virus-like particles (VP1-VLPs), which are morphologically indistinguishable from the SV40 virion and can be easily purified. Here, we show that heterologous proteins fused to VP2/3 can be efficiently incorporated into the VP1-VLPs. Using EGFP as a model protein, we have optimized this encapsulation system and found that fusion to the C-terminus of VP2/3 is preferable and that the C-terminal VP1-interaction domain of VP2/3 is sufficient for incorporation into VLPs. The VLPs encapsulating EGFP retain the ability to attach to the cell surface and enter the cells. Using this system, we have encapsulated yeast cytosine deaminase (yCD), a prodrug-modifying enzyme that converts 5-fluorocytosine to 5-fluorouracil, into VLPs. When CV-1 cells are challenged by the yCD-encapsulating VLPs, they become sensitive to 5-fluorocytosine-induced cell death. Therefore, proteins of interest can be encapsulated in VP1-VLPs by fusion to VP2/3 and successfully delivered to cells.

Presentation of functional foreign peptides on the surface of SV40 virus-like particles.

Viral capsids of simian virus 40 (SV40) are highly efficient gene delivery vehicles that infect a broad range of cells and tissues. To develop a controlled, cell type-specific delivery system, we sought to display foreign peptides on the capsid surface by genetically manipulating the major capsid protein Vp1. Here we report the identification of two sites within the surface loops of Vp1 that can accommodate foreign peptides in such a way that the foreign peptides are displayed on the surface of the virus-like particles (VLPs) without interfering with VLP assembly or the packaging of viral DNA. Insertion of Flag-tags but not RGD integrin-binding motifs at these sites strongly inhibited cell attachment of VLPs, which normally associate with host cells through cell surface molecules such as major histocompatibility complex (MHC) class I and ganglioside GM1. Instead, VLPs carrying the RGD motifs bound to integrin in vitro and to the cell surface in an RGD-dependent manner. Thus, insertion of foreign sequences into the surface loops of Vp1 can reduce natural virus-cell interactions and even confer an ability to bind to a new target receptor. This study demonstrates the potential usefulness of this strategy for the development of novel delivery vehicles with different cell tropisms.

Multiple mechanisms and functions of maf transcription factors in the regulation of tissue-specific genes.

Maf family transcription factors are regulators of tissue-specific gene expression and cell-differentiation in a wide variety of tissues and are also involved in human diseases and oncogenic transformation. To establish tissue-specific expression, Maf binds to Maf-recognition elements (MAREs) in the regulatory regions of target genes, and functionally interacts with other transcription factors. For example, L-Maf and c-Maf, which are specifically expressed in developing lens cells, act synergistically with Sox proteins to induce lens-specific crystalline genes. MafA, a beta-cell-specific member of the Maf family, activates the insulin gene promoter synergistically with Pdx1 and Beta2 to establish beta-cell specific expression. Furthermore, in beta-cells, MafA activity is regulated at both the transcriptional and post-translational levels by glucose and oxidative stress. This review summarizes the functions and roles of Maf in various biological processes and recent progress in elucidating the mechanisms whereby Maf proteins regulate transcription.

Roles and regulation of transcription factor MafA in islet beta-cells.

Insulin is a critical hormone in the regulation of blood glucose levels. It is produced exclusively by pancreatic islet beta-cells. beta-cell-enriched transcription factors, such as Pdx1 and Beta2, have dual roles in the activation of the insulin gene promoter establishing beta-cell-specific insulin expression, and in the regulation of beta-cell differentiation. It was shown that MafA, a beta-cell-specific member of the Maf family of transcription factors, binds to the conserved C1/RIPE3b element of the insulin promoter. The Maf family proteins regulate tissue-specific gene expression and cell differentiation in a wide variety of tissues. MafA acts synergistically with Pdx1 and Beta2 to activate the insulin gene promoter, and mice with a targeted deletion of mafA develop age-dependent diabetes. MafA also regulates genes involved in beta-cell function such as Glucose transporter 2, Glucagons-like peptide 1 receptor, and Prohormone convertase 1/3. The abundance of MafA in beta-cells is regulated at both the transcriptional and post-translational levels by glucose and oxidative stress. This review summarizes recent progress in determining the functions and roles of MafA in the regulation of insulin gene transcription in beta-cells.

Synergistic activation of the insulin gene promoter by the beta-cell enriched transcription factors MafA, Beta2, and Pdx1.

Specific expression of the insulin gene in pancreatic islet beta-cells requires multiple cis-regulatory elements in its promoter. Pdx1, MafA, and Beta2 have been identified as beta-cell enriched transcription factors that bind to these elements. Pdx1 has been shown to bind to A1, A3, A5, and GG2, and Beta2 binds to E1 by forming a heterodimer with the ubiquitous factor E47. MafA was recently identified as a C1-element binding factor. However, interactions between these factors and the promoter have not been characterized in detail. In this report, we show that these transactivators synergistically stimulate insulin promoter activity. Among multiple binding sites for Pdx1, MafA, and Beta2, at least GG2, C1, and E1 elements located in the promoter region between -150 and -100 base pairs are necessary for the synergism. We also found that neither MafB nor c-Maf, close relatives of MafA, showed synergistic activation. These results suggest that co-expression and functional synergism of these beta-cell enriched transactivators, MafA, Pdx1, and Beta2, are critical for establishing the beta-cell-specific and efficient expression of the insulin gene.

Phosphorylation of MafA enhances interaction with Beta2/NeuroD1.

AIMS: MafA is a critical regulator of insulin expression and mature ß-cell function. MafA binds to the insulin promoter through its carboxyl-terminal basic domain-leucine zipper (bZip) region and activates transcription synergistically with the ß-cell-enriched transactivators Beta2 (NeuroD1) and Pdx1. MafA protein is highly phosphorylated in ß-cells, and phosphorylation at multiple sites within its amino-terminal region is critical for its DNA-binding and transactivating abilities, as well as for regulation of its degradation. Here, we investigated whether phosphorylation of MafA affects its interaction with Beta2. METHODS: By mutational analysis, we identified interaction domains of MafA and Beta2. Using in situ proximity ligation assay (PLA), we explored mechanism of phosphorylation-dependent binding of MafA with Beta2. We also searched for a pathophysiological condition that would induce lower levels of MafA phosphorylation. RESULTS: Mutational analysis revealed that the phosphorylation sites within the amino-terminal region of MafA were not necessary for interaction with Beta2. In situ PLA suggested that phosphorylation induces conformational or configurational changes in MafA, thereby regulating the interaction with Beta2. We also found that long-term culture of the MIN6 insulinoma cell line under high-glucose conditions resulted in a decrease in ß-cell-specific transcripts including insulin, along with a decrease in MafA phosphorylation and DNA binding. CONCLUSION: Phosphorylation of MafA plays a critical role in ß-cell function by regulating multiple functionalities, including binding to DNA, interaction with Beta2, and transactivation.

Transcription Factor MafB Coordinates Epidermal Keratinocyte Differentiation.

Mammalian epidermis is a stratified epithelium composed of distinct layers of keratinocytes. The outermost cornified layer is a primary barrier that consists of a cornified envelope, an insoluble structure assembled by cross-linked scaffold proteins, and a surrounding mixture of lipids. Skin keratinocytes undergo a multistep differentiation process, but the mechanism underlying this process is not fully understood. We demonstrate that the transcription factor MafB is expressed in differentiating keratinocytes in mice and is transcriptionally upregulated upon human keratinocyte differentiation in vitro. In MafB-deficient mice, epidermal differentiation was partially impaired and the cornified layer was thinner than in wild-type mice. On the basis of transcriptional profiling, we detected reduced expression levels of a subset of cornified envelope genes, for example, filaggrin and repetin, in the MafB(-/-) epidermis. By contrast, the expression levels of lipid metabolism-related genes, such as Alox12e and Smpd3, increased. The upregulated genes in the MafB(-/-) epidermis were enriched for putative target genes of the transcription factors Gata3, Grhl3, and Klf4. Immunohistochemical analysis of skin biopsy samples revealed that the expression levels of filaggrin and MafB were significantly reduced in patients with human atopic dermatitis and psoriasis vulgaris. Our results indicate that MafB is a component of the gene expression program that regulates epidermal keratinocyte differentiation.

MafA has strong cell transforming ability but is a weak transactivator.

The maf oncogene of the avian oncogenic retrovirus AS42 encodes a nuclear bZip protein, v-Maf, that recognizes sequences related to the AP-1 target site. The corresponding cellular protein, c-Maf belongs to a family of related bZip proteins together with MafA and MafB. In this paper, we compare the transactivation and cell transforming abilities of MafA and MafB along with two forms of the c-Maf protein. These proteins induce cellular transformation when expressed in chicken embryo fibroblasts. In reporter assays, MafA is a much less effective transactivator than the other Maf proteins, but unexpectedly shows the strongest activity in cell transformation. Chimeras of MafA and MafB correlate the strong cell transforming ability of MafA with its DNA-binding domain. The DNA-binding domain of MafA is also correlated with weak transactivation. Additional mutagenesis experiments show that transactivation and transformation by MafA are also controlled by phosphorylation of two conserved serine residues in the transactivation domain. Finally, we constructed MafA-estrogen receptor fusion molecules that show tightly hormone-dependent cell transforming ability. These regulatable constructs permit a kinetic characterization of target gene responses and facilitate discrimination between direct and indirect targets.

Artificial oncoproteins: modified versions of the yeast bZip protein GCN4 induce cellular transformation.

We have constructed artificial AP-1 proteins containing elements derived from yeast GCN4 and from the herpes simplex virus activator VP16. These proteins can only homodimerize but do not heterodimerize, and lacking significant homology to Jun outside the DNA-binding domain, they are largely unaffected by proteins that modulate Jun. Constructs in which the transactivation domain of GCN4 is replaced by that of VP16 induce oncogenic transformation in cultures of chicken embryo fibroblasts. The availability of transforming VP16-GCN4 fusion proteins permits an evaluation of downstream target genes, based on the hypothesis that transformation-relevant targets should be common between Jun and the artificial AP-1 proteins. In a pilot study, we examined the expression of several Jun target genes in cells transformed by the VP16-GCN4 fusions and found that some of the Jun targets are not upregulated by the GCN4-derived transforming construct, suggesting that their upregulation in Jun-transformed cells is not essential for cell transformation. We have further constructed a regulatable GCN4-VP16 protein that will permit a kinetic characterization of target gene responses and will facilitate discrimination between direct and indirect targets.

Gata3 cooperates with Gcm2 and MafB to activate parathyroid hormone gene expression by interacting with SP1.

Haploinsufficiency of the Gata3 gene, which encodes a zinc-finger transcription factor, is associated with the disorder hypoparathyroidism, deafness, and renal dysplasia (HDR) syndrome in humans. However, the roles of Gata3 in transcriptional regulation in the parathyroid glands are not well-understood. In this study, we show that Gata3 activates transcription of parathyroid hormone (PTH), which is secreted from parathyroid glands and is critical for regulating serum calcium and phosphate homeostasis. Gata3 interacted with Gcm2 and MafB, two known transcriptional regulators of parathyroid development, and synergistically stimulated the PTH promoter. An SP1-binding element (GC box) located within the PTH-promoter proximal region was critical for activating transcription by Gata3. In addition, the ubiquitous transcription factor SP1 also interacted with Gata3 as well as MafB and Gcm2, and HDR syndrome-associated Gata3 mutants were defective in activating the PTH promoter. These results suggest that Gata3 is a critical regulator of PTH gene expression.