JOP. J Pancreas (Online) 2011 Jan 5; 12(1):6-10.

 

 

Dysregulation of Hnf1b Gene Expression in Cultured Beta-Cells in Response to Cytotoxic Fatty Acid

 

 

Karen A Johnstone¹, Eleftheria Diakogiannaki^2,3, Shalinee Dhayal², Noel G Morgan¹, Lorna W Harries¹

 

 

¹Institute of Biomedical and Clinical Science, Peninsula College of Medicine and Dentistry, University of Exeter. Exeter, United Kingdom. ²Institute of Biomedical and Clinical Science, Peninsula College of Medicine and Dentistry, University of Plymouth. Plymouth, United Kingdom. ³Department of Clinical Biochemistry, University of Cambridge, Addenbrooke’s Hospital. Cambridge, United Kingdom

 

 

ABSTRACT

Context Increased levels of circulating fatty acids deriving from over-nutrition are thought to contribute to the progressive beta-cell failure associated with type 2 diabetes. Pancreatic beta-cells in culture are sensitive to exposure to long-chain saturated fatty acids (e.g. palmitate) which cause cytotoxicity, whereas the monounsaturated equivalents (e.g. palmitoleate) are cytoprotective. Objectives In this study we sought to determine whether of members of the hepatocyte nuclear factor (HNF) family of transcription factors, which are mutated in familial, young-onset, monogenic beta-cell diabetes, could play a role in fatty acid-mediated cytotoxicity in cultured beta-cells. Design We used real-time PCR to determine whether hepatocyte nuclear factor gene expression was altered in response to palmitate exposure in the BRIN-BD11 beta-cell line. Results We found that the Hnf isoforms expressed in BRIN-BD11 cells are dysregulated by palmitate exposure. The expression of Hnf1b is specifically reduced by exposure to palmitate, and this response is prevented by co-incubation with palmitoleate. Conclusions Down-regulation of Hnf1b gene expression accompanies palmitate-mediated cytotoxicity in cultured beta-cells.

 

INTRODUCTION

The rising incidence of type 2 diabetes correlates with spiralling levels of obesity [1] and it is thought that increased circulating free fatty acids, associated with over-nutrition and adiposity, may contribute to the progression of type 2 diabetes [2, 3]. Type 2 diabetes occurs when pancreatic beta-cells are unable to secrete sufficient insulin to compensate for peripheral insulin resistance, most likely due to a combination of beta-cell dysfunction and decreased beta-cell mass [4]. After the onset of type 2 diabetes, the combined effects of increasing hyperglycaemia and hyperlipidaemia contribute to a further deterioration in beta-cell function and mass [5].

Physiological levels of fatty acids are essential to normal beta-cell function [5] but it has been recognised for some time that chronic exposure to elevated circulating fatty acids is detrimental to beta-cell function [2, 6]. In addition, beta-cells exposed to saturated long-chain fatty acids in culture undergo cell death [7, 8] leading to the hypothesis that fatty acid toxicity could also contribute to decreased beta-cell mass in type 2 diabetes. Beta-cells incubated in vitro show differential responses depending on the chain length and degree of saturation of the fatty acid [9]. Most notably, long-chain saturated fatty acids such as palmitate (C16:0) induce a rapid cytotoxic response resulting in apoptosis, while monounsaturated fatty acids such as palmitoleate (C16:1) are not toxic to beta-cells in culture [8]. Additionally, monounsaturated fatty acids are potently anti-apoptotic in beta-cells exposed to palmitate or various other cytotoxic stimuli [10, 11].

It is well established that fatty acids are involved in the regulation of gene transcription and this has been attributed partly to their ability to modulate the activity or abundance of members of a small number of transcription factor families [12], including hepatocyte nuclear factor 4, alpha (HNF4alpha). HNF4alpha regulates the expression of a number of genes involved in lipid metabolism [13] and has recently been shown to bind endogenous fatty acid in vivo, although the ligand does not appear to enhance transcriptional activity [14].

Haploinsufficiency for HNF4A (the gene which encodes the HNF4alpha protein) causes a rare form of monogenic beta-cell diabetes with autosomal dominant inheritance, early age of onset, impaired insulin secretion but detectable C-peptide (formerly known as maturity onset diabetes of the young or MODY) [15]. Familial, young-onset, monogenic beta-cell diabetes is characterised by progressive beta-cell dysfunction and is also caused by heterozygous mutations in two other HNF homeobox 1 transcription factors, HNF1A and HNF1B. These transcription factors interact in a pancreatic islet-specific network and thus changes in the expression of one can have an impact on other members of the network [16]. One of the key interactions is a cross-regulatory relationship between HNF1alpha and HNF4alpha, apparently unique to the pancreas and perhaps best reflected in the overlapping beta-cell phenotype of HNF1A and HNF4A monogenic beta-cell diabetes [16]. Pancreatic beta-cells appear to be particularly sensitive to dosage perturbations since monogenic beta-cell diabetes is the primary clinical phenotype associated with both HNF1A and HNF4A heterozygous mutations despite their expression in other tissues [17].

In this study we sought to investigate whether the regulation of any of these transcription factors was altered in response to exposure to cytotoxic fatty acids using a well-characterised rodent beta-cell system.

METHODS

Treatment of Cells with Fatty Acids

The rat pancreatic beta-cell lines BRIN-BD11 [18] and INS-1 [19] were cultured under standard conditions in RPMI-1640 medium containing 11 mM glucose [20]. Six-well plates were seeded with 10⁵ cells/well 24 h prior to treatment. Palmitate (Sigma-Aldrich, Gillingham, United Kingdom) was dissolved in 50% ethanol at 70°C and palmitoleate (MP Biomedicals, Cambridge, United Kingdom) dissolved in 90% ethanol. Fatty acid was bound to 10% fatty acid-free bovine serum albumin (BSA) (MP Biomedicals, Cambridge, United Kingdom) by incubation for 1 h at 37°C prior to addition to cells. During treatment all cells were cultured in the absence of foetal bovine serum (FBS) in 1% BSA and 0.5% ethanol. BRIN-BD11 cells were treated with fatty acid/BSA complexes for 18 h and INS-1 cells for 48 h. For serum starvation, BRIN-BD11 cells were grown in supplemented RPMI-1640 lacking FBS, in 1% BSA and 0.5% ethanol for 48 h. Each condition had three replicates and BRIN-BD11 cells were treated with palmitate in five independent experiments. Cell death was estimated by microscopy and was consistent with previous results [11, 21]. BRIN-BD11 cells under control conditions underwent 10-20% cell death, 0.1 mM palmitate with 40-60% cell death and 0.25 mM palmitate with 70-90% cell death. Palmitoleate (0.25 mM) reduced cell death to below control levels and laurate (0.25 mM) did not influence cell viability.

RNA Extraction and Reverse Transcription

RNA was extracted using the RNeasy Mini Kit (Qiagen, Crawley, United Kingdom). cDNA was synthesised from total RNA using random hexamers and the ThermoScript^TM RT-PCR System (Invitrogen, Paisley, United Kingdom).

Quantitative PCR (qPCR)

All custom Hnf gene expression assays (Assays-by-Design, Applied Biosystems, Warrington, United Kingdom) are as previously described and validated [22]. The gene expression assay for the endogenous control gene beta-2 microglobulin (B2m) is commercially available (Rn00560865_m1, Assays-on-Demand, Applied Biosystems, Warrington, United Kingdom). Quantitative PCR reactions were performed in triplicate on the ABI Prism 7900HT platform using TaqMan Fast Universal PCR Master Mix (no AMPerase) (Applied Biosystems, Warrington, United Kingdom). The relative expression of each isoform under various conditions was determined by normalisation to B2m and comparison to the average of the three replicate controls within an experiment using the 2^-ΔΔCt method [23].

STATISTICS

Statistical significance was assumed for two-tailed P values less than 0.05 and was determined using the non-parametric Mann Whitney-U test in SPSS (v15.0, Chicago, IL, USA).

RESULTS

Expression Profile of HNF Transcription Factor Isoforms in the Rodent Beta-Cell Line BRIN-BD11

BRIN-BD11 cells were used in this study as their viability in response to saturated and monounsaturated fatty acids is similar to that seen in isolated human islets [10, 24]. Gene expression profiling using a series of TaqMan gene expression assays [22] designed to detect individual isoforms of Hnf1a (a, b, c), Hnf1b (a, b, c) and Hnf4a (7, 8, 9) was performed on BRIN-BD11 cells. Hnf1a(a) was abundant and Hnf1b(a) and Hnf1b(b) were also detected robustly (data not shown). The isoform expression profiles for Hnf1a and Hnf1b were consistent with data from rodent tissues [22]. All other isoforms were expressed at very low levels. Palmitate (0.25 mM) exposure was associated with high levels of cell death and the resulting yields of RNA were too low to generate reliable data for the remaining transcription factor isoforms.

Hnf1a Expression is Up-Regulated in Response to Saturated Fatty Acid Exposure

In BRIN-BD11 cells the expression of Hnf1a(a) increased significantly in response to palmitate, with a 39% increase in expression in the presence of 0.1 mM palmitate (P=0.001) and a 59% increase in the presence of 0.25 mM palmitate (P=0.013) (Figure 1). This increased expression was suppressed when cells were incubated with 0.25 mM palmitate in the presence of 0.25 mM palmitoleate (Figure 1). Incubation in the presence of 0.25 mM palmitoleate alone did not influence the expression of Hnf1a (Figure 1). The dose-dependent increase in expression of Hnf1a(a) in BRIN-BD11 cells exposed to palmitate had potentially important implications and we therefore investigated it further. First it was critical to establish whether this effect was a general response to cell death and, therefore, expression of Hnf1a(a) was measured in response to a different pro-apoptotic stimulus; serum starvation. Withdrawal of serum from the culture medium led to the loss of viability of BRIN-BD11 cells in the presence of 1% BSA and 0.5% ethanol and the magnitude of this response reached comparable levels within 48 h (50-60% cell death) to that seen during palmitate exposure. Under these conditions Hnf1a(a) expression was not increased compared to the 18 h control (Figure 1). This implies that the increase in Hnf1a(a) expression was a specific response to saturated fatty acid exposure. We therefore tested the response to a shorter chain saturated fatty acid, laurate (C12:0), which is not cytotoxic. In this case a small (non-significant) dose-dependent increase in Hnf1a(a) expression was observed compared to control conditions (Figure 1), and it did not differ significantly from the response to palmitate. Interestingly, we found that Hnf1a(a) expression was unchanged in a second rat pancreatic beta-cell line, INS-1, following palmitate exposure (Figure 1).

 

 

Figure 1. Hnf1a expression is upregulated in response to saturated fatty acids. The results of quantitative PCR (qPCR) analysis of Hnf1a(a) expression in cultured rat beta-cells exposed to a variety of stimuli. BRIN-BD11 cells were treated with palmitate or laurate for 18 h or were serum starved (-serum) for 48 h. INS-1 cells were exposed to palmitate for 48 h. The medians and interquartile ranges are plotted (n=6-15 times in each experiment). P values were derived using the Mann Whitney-U test. Values which differ significantly from the BRIN-BD11 palmitate control (BSA/ethanol only) are indicated. BSA:bovine serum albumin; FA: saturated fatty acid; PO: palmitoleate

 

 

Hnf1b Isoforms Show a Specific Response to Cytotoxic Saturated Fatty Acid

We analysed the expression of Hnf1b isoforms in BRIN-BD11 cells in response to fatty acid exposure. Two gene expression assays were used to detect all three Hnf1b isoforms. Hnf1b(a) detects isoforms a and c but since isoform c accounts for less than 10% of the transcripts under all conditions tested (data not shown) it has been simplified to Hnf1b(a). Again, it was found that Hnf1b expression showed a dose-dependent change in response to palmitate exposure but, in this case, the direction of change was opposite to that seen for Hnf1a (Figure 2). Hnf1b(a) showed an 18% and Hnf1b(b) a 19% decrease in expression in response to 0.1 mM palmitate and the magnitude of these decreases was increased further when a higher concentration (0.25 mM) was employed. Under these conditions, Hnf1b(a) decreased by 33% and Hnf1b(b) by 28%. As was the case for Hnf1a(a), incubating cells with 0.25 mM palmitate in the presence of 0.25 mM palmitoleate prevented the response, while 0.25 mM palmitoleate alone did not have any effect on the expression of Hnf1b (Figure 2). Again we were able to show that the response was specific to fatty acid exposure and did not appear to represent a general pro-apoptotic response. Under conditions of serum starvation (48 h) the expression of all Hnf1b isoforms was comparable to that of the 18 h control and they differed significantly from the levels achieved with 0.25 mM palmitate (P<0.018). Exposure to laurate did not significantly alter Hnf1b expression. The INS-1 cell line used in this study did not express detectable levels of any of the Hnf1b isoforms under the conditions employed. Since the changes in expression of Hnf1b(a) and Hnf1b(b) are reciprocal, this implies that they arise from a specific transcriptional response elicited by palmitate, rather than from a process controlling post-transcriptional processing.

 

 

Figure 2. Hnf1b expression is downregulated in response to cytotoxic fatty acid. Hnf1b isoform expression was analysed in BRIN-BD11 cells exposed to fatty acids for 18 h or serum starved (-serum) for 48 h. The medians and interquartile ranges are plotted (n=6-15 times in each experiment). P values were derived using the Mann Whitney-U test. Values which differ significantly from the BRIN-BD11 palmitate control (BSA/ethanol only) are indicated. BSA:bovine serum albumin; FA: saturated fatty acid; PO: palmitoleate

 

 

DISCUSSION

We have shown that expression of the predominant Hnf isoforms present in BRIN-BD11 cells is altered in response to chronic exposure to the saturated fatty acid palmitate. As these transcription factors act within a complex cross-regulatory circuit [16], this has general implications for the network.

With respect to palmitate-mediated beta-cell toxicity, the most significant response detected was a decrease in expression of Hnf1b. Palmitate exposure resulted in a decrease in expression of all Hnf1b isoforms, a response which was not elicited by a non-cytotoxic saturated fatty acid (laurate) or by an alternative cytotoxic mechanism (serum starvation). In addition, and perhaps most significantly, Hnf1b expression was not down-regulated when palmitate was co-incubated with the cytoprotective monounsaturated fatty acid, palmitoleate. A similar suppression of the molecular response to palmitate by co-incubation with palmitoleate is also seen for components of the endoplamic reticulum stress response [25], a pathway thought to be involved in palmitate-mediated cytotoxicity [26, 27]. HNF1B is highly dosage-sensitive. A decrease in gene dosage is clearly detrimental to beta-cell function as haploinsufficiency for HNF1B is sufficient to cause monogenic beta-cell diabetes [28] and, in a conditional mouse model, incomplete deletion is sufficient to impair glucose tolerance [29]. In addition, over-expression of HNF1beta is associated with reduced viability in INS-1 beta-cells [30]. The HNF1beta protein is not readily detected in mature pancreatic beta-cells [31], making it difficult to determine whether the reduction in gene expression observed here was reflected by a change in the protein level of HNF1beta. Perhaps the most meaningful way to determine the effects of reduced Hnf1b expression will be to examine the effect of acute exposure to palmitate on downstream targets of HNF1beta. Conditional deletion of Hnf1b in mouse beta-cells leads to a decrease in Hnf4a expression suggesting that Hnf1b may be required for Hnf4a expression in murine islets [29]. We were unable to determine whether the same effect was seen in BRIN-BD11 cells in response to palmitate as Hnf4a transcripts are expressed at very low levels.

Hnf1a expression was increased during palmitate exposure. Unlike Hnf1b, this response does not appear to relate to cytotoxicity as there was also a trend towards increased expression in response to laurate. Hnf1a expression did not increase in response to palmitate in a second beta-cell line, INS-1. In a beta-cell-specific conditional gene knockout of Hnf1b, the expression levels of Hnf1a increased in response to loss of Hnf1b [29] and thus up-regulation of Hnf1a in BRIN-BD11 cells in response to palmitate could be a secondary effect of reduced Hnf1b expression. This could also partly account for the difference in the Hnf1a response between BRIN-BD11 and INS-1 cells, which express very low levels of Hnf1b. Palmitate is also toxic to INS-1 cells but toxicity does not develop until up to 48 h of exposure, compared to as little as 18 h for BRIN-BD11 cells. We conclude that induction of Hnf1a(a) expression is a specific response to exposure to palmitate in BRIN-BD11 cells but it does not relate to cytotoxicity.

In summary, we have shown that there are changes in the expression of the Hnf transcription factor isoforms expressed in BRIN-BD11 cells in response to palmitate exposure. Most significantly we observed a dose-dependent decrease in Hnf1b expression in response to palmitate exposure. This response is specific to palmitate-mediated cytotoxicity and is prevented by co-incubation with monounsaturated fatty acid. We also detected a dose-dependent increase in the expression of Hnf1a in response to saturated, but not monounsaturated, fatty acid exposure. We conclude that reduced Hnf1b gene expression could represent one contributory factor in palmitate-mediated cytotoxicity in cultured beta-cells.

 

Received July 16^th, 2010 - Accepted October 28^th, 2010

Key words Hepatocyte Nuclear Factor 1-beta; Palmitic Acid; palmitoleic acid

Abbreviations HNF: hepatocyte nuclear factor

Acknowledgements We would like to thank Dr Mark Russell for assistance with cell culture and Dr Jonathan Locke for critical reading of the manuscript. This research was supported by the Wellcome Trust (WT081278MA) and the Mendip Golf Club (LWH) and by the Diabetes Research and Wellness Foundation and the European Foundation for the Study of Diabetes (N.G.M.)

Conflict of interest The authors have no potential conflict of interest

Correspondence
Lorna W Harries
Institute of Biomedical and Clinical Science
Peninsula Medical School
Barrack Rd
Exeter, EX2 5DW
United Kingdom
Phone: +44-(0)1392.406.749
Fax: +44-(0)1392.406.767
E-mail: l.w.harries@exeter.ac.uk

 

References

1. Zimmet P, Alberti KG, Shaw J. Global and societal implications of the diabetes epidemic. Nature 2001; 414:782-7. [PMID 11742409]

2. Unger RH. Lipotoxicity in the pathogenesis of obesity-dependent NIDDM. Genetic and clinical implications. Diabetes 1995; 44:863-70. [PMID 7621989]

3. Carpentier AC. Postprandial fatty acid metabolism in the development of lipotoxicity and type 2 diabetes. Diabetes Metab 2008; 34:97-107. [PMID 18353699]

4. Butler AE, Janson J, Bonner-Weir S, Ritzel R, Rizza RA, Butler PC. Beta-cell deficit and increased beta-cell apoptosis in humans with type 2 diabetes. Diabetes 2003; 52:102-10. [PMID 12502499]

5. Poitout V, Robertson RP. Glucolipotoxicity: fuel excess and beta-cell dysfunction. Endocr Rev 2008; 29:351-66. [PMID 18048763]

6. Zhou YP, Grill V. Long term exposure to fatty acids and ketones inhibits b-cell functions in human pancreatic islets of Langerhans. J Clin Endocrinol Metab 1995; 80:1584-90. [PMID 7745004]

7. Cnop M, Hannaert JC, Hoorens A, Eizirik DL, Pipeleers DG. Inverse relationship between cytotoxicity of free fatty acids in pancreatic islet cells and cellular triglyceride accumulation. Diabetes 2001; 50:1771-7. [PMID 11473037]

8. Maedler K, Spinas GA, Dyntar D, Moritz W, Kaiser N, Donath MY. Distinct effects of saturated and monounsaturated fatty acids on beta-cell turnover and function. Diabetes 2001; 50:69-76. [PMID 11147797]

9. Morgan NG, Dhayal S, Diakogiannaki E, Welters HJ. The cytoprotective actions of long-chain mono-unsaturated fatty acids in pancreatic beta-cells. Biochem Soc Trans 2008; 36:905-8. [PMID 18793159]

10. Maedler K, Oberholzer J, Bucher P, Spinas GA, Donath MY. Monounsaturated fatty acids prevent the deleterious effects of palmitate and high glucose on human pancreatic beta-cell turnover and function. Diabetes 2003; 52:726-33. [PMID 12606514]

11. Welters HJ, Tadayyon M, Scarpello JH, Smith SA, Morgan NG. Mono-unsaturated fatty acids protect against beta-cell apoptosis induced by saturated fatty acids, serum withdrawal or cytokine exposure. FEBS Lett 2004; 560:103-8. [PMID 14988006]

12. Pegorier JP, Le May C, Girard J. Control of gene expression by fatty acids. J Nutr 2004; 134:2444S-9S. [PMID 15333740]

13. Hayhurst GP, Lee YH, Lambert G, Ward JM, Gonzalez FJ. Hepatocyte nuclear factor 4alpha (nuclear receptor 2A1) is essential for maintenance of hepatic gene expression and lipid homeostasis. Mol Cell Biol 2001; 21:1393-403. [PMID 11158324]

14. Yuan X, Ta TC, Lin M, Evans JR, Dong Y, Bolotin E, et al. Identification of an endogenous ligand bound to a native orphan nuclear receptor. PLoS One 2009; 4:e5609. [PMID 19440305]

15. Owen K, Hattersley AT. Maturity-onset diabetes of the young: from clinical description to molecular genetic characterization. Best Pract Res Clin Endocrinol Metab 2001; 15:309-23. [PMID 11554773]

16. Ferrer J. A genetic switch in pancreatic beta-cells: implications for differentiation and haploinsufficiency. Diabetes 2002; 51:2355-62. [PMID 12145145]

17. Ryffel GU. Mutations in the human genes encoding the transcription factors of the hepatocyte nuclear factor (HNF)1 and HNF4 families: functional and pathological consequences. J Mol Endocrinol 2001; 27:11-29. [PMID 11463573]

18. McClenaghan NH, Barnett CR, Ah-Sing E, Abdel-Wahab YH, O'Harte FP, Yoon TW, et al. Characterization of a novel glucose-responsive insulin-secreting cell line, BRIN-BD11, produced by electrofusion. Diabetes 1996; 45:1132-40. [PMID 8690162]

19. Asfari M, Janjic D, Meda P, Li G, Halban PA, Wollheim CB. Establishment of 2-mercaptoethanol-dependent differentiated insulin-secreting cell lines. Endocrinology 1992; 130:167-78. [PMID 1370150]

20. Dhayal S, Welters HJ, Morgan NG. Structural requirements for the cytoprotective actions of mono-unsaturated fatty acids in the pancreatic beta-cell line, BRIN-BD11. Br J Pharmacol 2008; 153:1718-27. [PMID 18297101]

21. Welters HJ, Diakogiannaki E, Mordue JM, Tadayyon M, Smith SA, Morgan NG. Differential protective effects of palmitoleic acid and cAMP on caspase activation and cell viability in pancreatic beta-cells exposed to palmitate. Apoptosis 2006; 11:1231-8. [PMID 16703263]

22. Harries LW, Brown JE, Gloyn AL. Species-specific differences in the expression of the HNF1A, HNF1B and HNF4A genes. PLoS One 2009; 4:e7855. [PMID 19924231]

23. Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods 2001; 25:402-8. [PMID 11846609]

24. El-Assaad W, Buteau J, Peyot ML, Nolan C, Roduit R, Hardy S, et al. Saturated fatty acids synergize with elevated glucose to cause pancreatic beta-cell death. Endocrinology 2003; 144:4154-63. [PMID 12933690]

25. Diakogiannaki E, Welters HJ, Morgan NG. Differential regulation of the endoplasmic reticulum stress response in pancreatic beta-cells exposed to long-chain saturated and monounsaturated fatty acids. J Endocrinol 2008; 197:553-63. [PMID 18492819]

26. Kharroubi I, Ladriere L, Cardozo AK, Dogusan Z, Cnop M, Eizirik DL. Free fatty acids and cytokines induce pancreatic beta-cell apoptosis by different mechanisms: role of nuclear factor-kappaB and endoplasmic reticulum stress. Endocrinology 2004; 145:5087-96. [PMID 15297438]

27. Diakogiannaki E, Morgan NG. Differential regulation of the ER stress response by long-chain fatty acids in the pancreatic beta-cell. Biochem Soc Trans 2008; 36:959-62. [PMID 18793169]

28. Bellanne-Chantelot C, Clauin S, Chauveau D, Collin P, Daumont M, Douillard C, et al. Large genomic rearrangements in the hepatocyte nuclear factor-1beta (TCF2) gene are the most frequent cause of maturity-onset diabetes of the young type 5. Diabetes 2005; 54:3126-32. [PMID 16249435]

29. Wang L, Coffinier C, Thomas MK, Gresh L, Eddu G, Manor T, et al. Selective deletion of the Hnf1beta (MODY5) gene in beta-cells leads to altered gene expression and defective insulin release. Endocrinology 2004; 145:3941-9. [PMID 15142986]

30. Welters HJ, Senkel S, Klein-Hitpass L, Erdmann S, Thomas H, Harries LW, et al. Conditional expression of hepatocyte nuclear factor-1beta, the maturity-onset diabetes of the young-5 gene product, influences the viability and functional competence of pancreatic beta-cells. J Endocrinol 2006; 190:171-81. [PMID 16837621]

31. Maestro MA, Boj SF, Luco RF, Pierreux CE, Cabedo J, Servitja JM, et al. Hnf6 and Tcf2 (MODY5) are linked in a gene network operating in a precursor cell domain of the embryonic pancreas. Hum Mol Genet 2003; 12:3307-14. [PMID 14570708]