Congenital hyperinsulinism (CHI) is a rare genetic disorder characterized by excess insulin secretion, which results in hypoglycemia. Mutation of sulfonylurea receptor 1 (SUR1), encoded by the ABCC8 gene, is the main cause of CHI. Here, we captured the phenotype of excess insulin secretion through pancreatic differentiation of ABCC8-deficient stem cells generated by the CRISPR/Cas9 system. ABCC8-deficient insulin-producing cells secreted higher insulin than their wild-type counterparts, and the excess insulin secretion was rescued by nifedipine, octreotide and nicorandil. Further, we tested the role of SUR1 in response to different potassium levels and found that dysfunction of SUR1 decreased the insulin secretion rate in low and high potassium environments. Hence, pancreatic differentiation of ABCC8-deficient cells recapitulated the CHI disease phenotype in vitro, which represents an attractive model to further elucidate the function of SUR1 and to develop and screen for novel therapeutic drugs.
Congenital hyperinsulinism (CHI) refers to a group of rare genetic disorders that are characterized by excess insulin secretion by pancreatic β-cells. As insulin is a key hormone in the regulation of blood glucose levels, excess insulin secretion leads to severe and persistent hypoglycemia1. Persistent hypoglycemia can induce jitteriness, lethargy, unresponsiveness and seizures and can increase the risk of brain injury2. The prevalence of CHI has increased from 1:50000 births to 1:2500 in the general population3. Therefore, a more relevant and specific disease model system that can recapitulate human CHI pathogenesis is desired for studying the disease mechanism and developing effective therapies.
The molecular mechanisms of CHI involve anomalies in key genes that regulate insulin secretion from β-cells, including ABCC8, KCNJ11, GCK, SCHAD, GLUD1, SLC16A1, HNF1A, HNF4A, and UCP2 4. The most common cause of CHI is inactive mutations of the ATP-sensitive potassium (KATP) channel genes ABCC8 and KCNJ11, which encode the sulfonylurea receptor 1 (SUR1) protein and inwardly rectify potassium channel (Kir6.2) proteins, respectively. Such KATP mutations are responsible for approximately 36.3% of all CHI cases5. To date, more than 150 ABCC8 mutations and 24 KCNJ11 mutations have been reported6, 7, which can cause continuous depolarization8 and Sar1-GTPase-dependent ER exit9 resulting in excess insulin secretion.
Although multiple genetic mouse models of CHI have been developed10,11,12, stem cells-based CHI models are still lacking. The CRISPR/Cas9 system has recently emerged as a powerful and highly efficient genome engineering tool13. The combination of the CRISPR/Cas9 system and human pluripotent stem cells provides new approaches for generating in vitro human disease models14,15,16, allowing for the opportunity to study rare human genetic diseases and screen for possible therapeutic drugs.
In this report, we modeled the phenotype of excess insulin secretion of CHI with ABCC8-deficient ES cell and pancreatic beta cell differentiation. The insulin-producing cells that differentiated from the ABCC8-deficient stem cells exhibited higher insulin secretion. Excess insulin secretion was rescued by drugs used for CHI treatment. We also tested the response of ABCC8-deficient cells to different potassium media and found that the ABCC8 mutation decreased the insulin secretion rate.
ABCC8-deficient insulin-producing cells demonstrated higher insulin secretion
We previously reported the generation of CRISPR/Cas9 system-mediated mutated ABCC8 heterozygous (A2, ABCC8 +/−, ABCC8 +/+1, 1 bp insertion at 167 locus of CDS) and homozygous (A4, ABCC8 −/−, ABCC8 Δ22/Δ22, c.167-188 del) cell lines from human ES cells17, 18 in which the ABCC8 mutation did not affect pluripotency or differentiation potential in vitro, and the cells contained a normal karyotype. Furthermore, we did not detect any off-target at 8 potential off-target sites, indicating that these isogenic cells could provide an ideal cell model for CHI research.
The major clinical symptom of CHI is excess insulin secretion in the blood. To model the phenotype of excess insulin secretion in vitro, we differentiated pancreatic beta cells from wild-type and mutated heterozygous or homozygous ABCC8 cell lines. For specific differentiation towards pancreatic beta cells, we followed a previous protocol with slight modifications19 to simulate normal pancreatic development through three main phases: definitive endoderm (DE), pancreatic progenitors (PPs) and insulin-producing cells (IPCs) (Fig. 1A). The expression of markers corresponding to the three phases, FOXA2 and SOX17 for DE, PDX1 for PPs, insulin and C-peptide for IPCs, was verified by immunofluorescence (Supplementary Fig. 1A,B,C). The insulin-producing cells at the end of the final differentiation stage were measured by immunofluorescence and flow cytometry (Fig. 1B; Supplementary Fig. 1D). ABCC8-deficient cells and normal cells shared similar differentiation efficiencies in that approximately 25% of terminal phase cells were insulin-positive, indicating that ABCC8 deficiency does not affect differentiation toward insulin-producing cells. Next, we tested the amount of insulin secreted by the cells in the supernatant in Krebs-Ringer bicarbonate HEPES (KRBH) buffer. The normal insulin content per unit protein for wild-type cells was 2.09 μU, while higher levels of insulin were measured for the ABCC8 mutants corresponding to 4.09 μU for ABCC8 +/− and 3.91 μU for ABCC8 −/− cells (Fig. 1C). We also measured C-peptide content in the supernatant, which exhibited the same trend as insulin content: C-peptide content per unit protein for both of the ABCC8 +/− and ABCC8 −/− cells reached 0.14 ng, which was significantly increased compared with 0.09 ng for wild-type cells (Fig. 1D). These results demonstrated that ABCC8-deficient cells secreted insulin and C-peptide at higher levels than wild-type cells, indicating that we created a phenotype of excess insulin secretion in vitro. Next, we measured the release of human C-peptide, a by-product of endogenous insulin biosynthesis that is secreted in an equimolar ratio to insulin20, as an indicator of insulin secretion.
To test whether SUR1 protein loses its function in ABCC8-deficient cells, we tested the effects of the two most widely used modulators, diazoxide and glimepiride, on insulin secretion. Diazoxide is a benzothiazine derivative that acts on the SUR1 subunit21 to activate KATP channels. Diazoxide is an agonist of KATP channels that is widely used for decreasing insulin secretion in CHI patients22. Glimepiride is a sulfonylurea drug that blocks the SUR1 subunit of KATP channels23 and, in turn, is used to increase insulin secretion in diabetic patients24, 25. Both diazoxide and glimepiride function in the presence of SUR1 protein. Our results demonstrated decreased insulin secretion in wild-type and ABCC8 +/− cells after application of diazoxide but no effect on ABCC8 −/− cells. The fold changes observed in wild-type, ABCC8 +/− and ABCC8 −/− cells were 0.79, 0.76 and 1.04, respectively. In contrast, glimepiride increased insulin secretion in wild-type and ABCC8 +/− cells but had no effect on ABCC8 −/− cells. The fold changes observed in wild-type, ABCC8 +/− and ABCC8 −/− cells were 1.51, 1.50 and 0.94, respectively (Fig. 1E,F). These results suggest a loss of function of SUR1 protein in CRISPR/Cas9-mediated ABCC8 mutants. ABCC8 +/− cells may provide a suitable in vitro model for screening drugs that can be used to treat CHI patients who are unresponsive to diazoxide.
Excess insulin secretion by ABCC8-deficient ES-IPCs can be rescued by nicorandil, nifedipine and octreotide
The process of insulin secretion is dependent on KATP channels. High-energy ATP molecules that are generated during carbohydrate metabolism increase the intracellular ATP:ADP ratio, leading to the closure of KATP channels and then causing depolarization of the cell surface membrane. Voltage-gated calcium ion channels open in response to depolarization, and calcium ions move into the cell, inducing insulin secretion26. Somatostatin has been proven to inhibit insulin secretion27. Nifedipine, a calcium channel antagonist, and octreotide, a somatostatin analogue, have both been used to treat CHI patients22, 28,29,30. Nicorandil, a potassium channel activator31, activates KATP channels32. Treatment of wild-type cells with octreotide, nicorandil and nifedipine induced fold changes of 0.51, 0.74 and 0.88 in C-peptide secretion, indicating their effect on decreasing insulin secretion. Therefore, it is interesting to determine whether these drugs can rescue excess insulin secretion in ABCC8-deficient cells. We found that octreotide, nicorandil and nifedipine decreased insulin secretion in ABCC8-deficient cells, inducing fold changes of 0.50, 0.72, and 0.84 for heterozygous mutated cells and 0.49, 0.71, and 0.69 for homozygous mutated cells, respectively (Fig. 1G). Our results showed that nicorandil, nifedipine and octreotide, which function at different insulin secretion stages, can decrease insulin secretion in ABCC8-deficient cells. These data demonstrated that our ABCC8 mutants provide an ideal model of CHI and could be used for drug screening.
No change in extracellular ATP-, calcium- and ouabain induced insulin secretion in ABCC8-deficient cells
Intracellular ATP molecules generated during carbohydrate metabolism increased insulin secretion in a KATP channel-dependent manner. It was previously reported that extracellular ATP (200 μM) can increase insulin secretion in pancreatic cells33, 34. However, whether extracellular ATP increases insulin in a KATP channel-dependent manner remains unknown. The loss of function of SUR1 protein in ABCC8-deficient cells was correlated with inactivation of KATP channels. Therefore, we tested the fold change of C-peptide secretion after treatment with extracellular ATP. We observed a 1.6-fold increase in C-peptide secretion in all three types of cells (Fig. 1H). As extracellular calcium increases insulin secretion35, we next sought to determine whether there is any impact of ABCC8 mutation on calcium chloride (10 mM)-mediated insulin secretion. We found a positive role of calcium chloride on insulin secretion with an approximately 2.9-fold increase in the three types of cells (Fig. 1H). To further elucidate the mechanism of insulin secretion, the role of sodium-potassium adenosine triphosphatase or the Na-K pump was investigated. The Na-K pump is located in the plasma membrane of all animal cells and functions to pump sodium outward and potassium inward. Ouabain increases insulin secretion as an Na-K pump inhibitor36, 37. However, it remains unknown whether the insulin secretion increased by ouabain is dependent on KATP channels. Our findings indicated an overall of 1.4-fold increase in insulin secretion by wild-type and ABCC8-deficient cells treated with ouabain (Fig. 1H). In conclusion, our results demonstrated that extracellular ATP, calcium and ouabain increase insulin secretion in a KATP channel-independent manner.
Insulin secretion rate of ABCC8-deficient cells is more sensitive to extracellular potassium
KATP channels play an important role in the regulation of insulin secretion and the maintenance of intracellular potassium homeostasis. To investigate the relation of SUR1 with potassium, we measured insulin secretion by ABCC8-deficient and wild-type cells in different concentrations of extracellular potassium: low potassium, normal potassium and high potassium environments.
KRBH buffer was derived from Ringer’s solution38 to mimic body fluids and was thus selected as the medium in which to measure insulin secretion. We defined KRBH buffer as the normal potassium medium with a K+ concentration of 5.9 mM (4.7 mM KCl and 1.2 mM KH2PO4). KRBH buffer supplemented with 30 mM KCl19 is widely used to induce insulin secretion by differentiated insulin-producing cells and was defined as the high potassium medium with a K+ concentration of 35.9 mM (34.7 mM KCl and 1.2 mM KH2PO4). KRBH buffer without KCl was used as the low potassium medium with a K+ concentration of 1.2 mM (1.2 mM KH2PO4).
We first measured insulin secretion in different potassium media for a pre-defined time period (35 min) and calculated the fold change of low K+/normal K+ and high K+/normal K+. We observed that, compared with normal potassium medium (KRBH), low potassium medium had no distinct effect, corresponding to an approximately 1-fold change in insulin secretion for all cells. On the other hand, an increase in insulin secretion by 8.8-fold was observed for all cells in the high potassium medium (Fig. 2A).
Finally, dynamic secretion curves in different potassium environments within 95 min were plotted by measuring insulin levels at 30-min intervals. In the normal potassium medium, wild-type and ABCC8-deficient cells demonstrated similar insulin secretion rates (Fig. 2B), whereas the insulin secretion rate of ABCC8 −/− cells decreased in low (slope: 0.3994 vs 0.7894) (Fig. 2C) and high potassium media (slope: 0.4477 vs 0.7336) (Fig. 2D) compared with wild-type cells. The slopes of the curves for ABCC8 +/− cells in the low and high media were between those for the wild-type and ABCC8 −/− cells, corresponding to 0.5493 and 0.6264, respectively. These results indicated that the ABCC8 mutation causes a decreased insulin secretion rate in low and high potassium environments (Fig. 2C,D).
In this report, we recapitulated the clinical phenomenon of CHI. ABCC8-deficient stem cells-derived insulin-producing cells exhibited higher insulin secretion than their isogenic wild-type cells. More importantly, excess insulin secretion can be rescued by drugs used to treat clinical CHI. Our results demonstrated the ability to model the phenotype of excess insulin secretion of CHI stem cells in vitro. The structure of KATP channels39, 40 was recently reported, providing new targets for drug design. Our CHI stem cell model represents a highly promising choice for testing such candidate drugs in vitro.
Although many attempts have been made to generate insulin-producing cells from human pluripotent stem cells in the past decade, insulin-producing cells resemble fetal rather than adult β cells41, which lack or only exhibit partial function of glucose-stimulated insulin secretion compared with primary β cells. Insulin secretion is tightly linked with glucose metabolism. In KATP CHI, the precise regulation of blood glucose and insulin secretion is lost due to the malfunction of KATP function. Therefore, immature β cells differentiated from stem cells don’t play a key role in CHI research.
Diazoxide has been proven to be effective in the treatment of hypoglycemia in some CHI patients. However, not all patients are responsive to diazoxide. In our model system, the insulin-producing cells lost the ability to respond to diazoxide when SUR1 function was completely lost (ABCC8 −/−). This cell line could be utilized to screen for drugs to treat diazoxide-unresponsive CHI patients.
Insulin is important in maintaining potassium homeostasis which plays critical role in many physiological processes. Insulin prevents substantial changes in extracellular fluid (ECF) K+ concentration as it promotes potassium to transfer from ECF to intracellular fluid (ICF) by increasing Na+/K+-ATPase activity independent of glucose uptake42. Increases in plasma potassium concentrations stimulate pancreatic insulin secretion43, which promotes a shift of excess K+ into the intracellular compartment. Direct depolarization by the addition of potassium chloride (hyperkalemia) consistently increases insulin secretion by insulin-producing cells differentiated from pluripotent stem cells19, 44, 45. KATP channels favor depolarization and then enhance calcium-mediated insulin secretion. KATP channels consist of two components, SUR1 and Kir6.2. In this report, we demonstrated that ABCC8-deficient insulin-producing cells exhibit a decreased insulin accumulation rate in high potassium medium. Zeng has reported that Kir6.2 deficiency impaired insulin secretion in response to high concentrations of potassium chloride46, indicating that SUR1 and Kir6.2 play different roles in response to high potassium concentrations. The role of low potassium (hypokalemia) in insulin secretion remains controversial. Some studies have shown that hypokalemia could reduce insulin secretion47, 48, but others have shown that clamping plasma potassium levels potentiates the insulin secretory response to glucose49. However, the dynamic secretion curve has not yet been reported. Our results showed that malfunction of SUR1 decreased the insulin secretion rate.
Although we successfully constructed a CHI stem cell model, many questions remain to be answered. CHI is a complicated disorder with unregulated insulin secretion. However, there are still approximately 50% patients whose genetic abnormalities have not been elucidated4. Induced pluripotent stem (iPS) cells50, 51 generated from somatic cells with several transcript factors provide the opportunity to produce various disease-specific cell types52 and, therefore, are an attractive method for modeling CHI. One possibility is collecting urine cells from these patients and reprograming them into iPS cells53 to generate a “disease-in-a-dish” model and then continuing with specific differentiation. Understanding of these innovative mechanisms will provide profound knowledge regarding the function of the pancreatic β-cells and novel treatments for CHI and even for diabetic mellitus.
In conclusion, we captured the CHI phenotype of excess insulin secretion with ABCC8-deficient ES cells that were established in our lab. We further investigated the role of SUR1 in insulin secretion in different potassium media. Our study not only provides an attractive model for in vitro CHI research but may provide a platform for studying other related hereditary pancreatic diseases.
The cell lines used in this report were approved by the Ethics Committee of Guangzhou Institutes of Biomedicine and Health, Chinese Academy of Sciences.
Human embryonic H1 stem cells and ABCC8-deficient stem cells17, 18 free of mycoplasma were routinely maintained on Matrigel (Becton Dickinson) with mTeSR1 (Stemcell). The cells were passaged for 4 days with accutase (Sigma). Rock inhibitor (10 μM; Y27632, Selleck) was added to improve the survival rate to 24 h after replating.
For pancreatic differentiation, we followed Yuya Kunisada’s protocol with slight modification19. Briefly stem cells were passaged on Matrigel-coated 24-well plates at a density of 10 × 104 cells per well. Stem cells were cultured with mTeSR1 including Y27632 for 24 h and then 3 days with mTeSR1 to nearly reach confluence. For differentiation, the cells were cultured in RPMI1640 (Gibco) containing B27 insulin (Gibco), 100 ng/mL activin A (Pepro Tech) and 3 μM CHIR99021 (Stemgent) for 24 h and for 48 h in RPMI 1640 containing B27 minus insulin and 100 ng/mL activin A. Subsequently, the media was changed with DMEM/F12 containing B27 (Gibco), 1 μM dorsomorphin (Calbiochem), 10 μM SB431542 (Sigma) and 2 μM retinoic acid (Sigma) for 7 days and medium was replaced every other day. For insulin-producing cell differentiation, the medium was changed to DMEM/F12 containing B27, 10 μM forskolin (Stemgent), 10 μM dexamethasone (Enzo Life Sciences), 5 μM Alk5 inhibitor II (Calbiochem) and 10 mM nicotinamide (Stemcell) for 12 days and provided with fresh medium every other day.
The cells were fixed in 1% paraformaldehyde for 30 min. After washing 3 times with PBS, the cells were blocked and permeabilized in blocking solution (PBS containing 3% bovine albumin and 0.2% Triton X-100) for 30 min at room temperature. The cells were then incubated with primary antibodies in blocking solution at 4 °C overnight, washed 3 times, and incubated with the corresponding secondary antibodies for 1 h at room temperature. The cells were washed twice and stained with DAPI (Sigma) for 5 min and then analyzed using a Leica DMI6000B microscope (Leica Microsystems). Primary antibodies used in this study were as follows: FoxA2 (R&D, AF2400, 1:200), Sox17 (RD, AF1924, 1:200), goat anti-Pdx1 (R&D, AF2419, 1:200), guinea pig anti-insulin (Dako, A056401, 1:300), and rabbit anti-C-peptide (Abcam, ab14181, 1:300).
Single-cell suspensions of differentiated human ES cell cultures were obtained by dissociating cells with 0.25% trypsin, fixing with 2% paraformaldehyde and permeabilizing with BD Perm/Wash buffer (Becton Dickinson). The cells were incubated with guinea pig anti-insulin antibody (1:1000, Dako) for 30 min at room temperature and then stained with Alexa Fluor 488-conjugated goat antibody directed against guinea pig (1:800) for 30 min at room temperature. Flow cytometry was performed using an Accuri C6 system (Becton Dickinson).
Insulin/C-peptide release assay by ELISA
To measure insulin secretion, differentiated cells were pre-incubated on day 22 for 1 h at 37 °C in Krebs-Ringer bicarbonate HEPES buffer (KRBH buffer,116 mM NaCl, 4.7 mM KCl, 2.5 mM CaCl2 1.2 mM KH2PO4, 1.2 mM MgSO4, 24 mM HEPES, 25 mM NaHCO3, and 0.1% BSA). Cells were incubated at 37 °C in KRBH for 1 h, and the supernatant was collected. Next, insulin and C-peptide were measured using human insulin ELISA Kit (Millipore) and a C-peptide ELISA kit (Millipore), respectively, according to the manufacturer’s instructions. To determine total protein content, cells were lysed with RIPA lysis buffer, and protein content was measured with a BCA Protein Assay Kit (Millipore). The amount of insulin or C-peptide was normalized to the amount of total protein in the corresponding cell lysate.
To measure the effect of diazoxide and glimepiride on insulin secretion, differentiated cells were pre-incubated with KRBH buffer at 37 °C for 1 h on day 22 and then incubated with KRBH buffer containing DMSO for 1 h at 37 °C; the supernatant was collected. Then, the same cells were incubated with KRBH buffer containing 100 μM diazoxide (Tocris) or 10 μM glimepiride (Selleck), and the supernatant was collected. Both diazoxide and glimepiride were dissolved in DMSO. The C-peptide levels in both supernatants were measured with human C-peptide ELISA kit (Millipore). To measure the content of total protein, cells were lysed with RIPA lysis buffer, and the total protein content was determined with a BCA Protein Assay Kit (Millipore). The amount of insulin or C-peptide was normalized to the amount of total protein in the corresponding cell lysate. The ratios of C-peptide content for cells treated with diazoxide/DMSO and glimepiride/DMSO were measured as fold changes.
To test the rescue effect of octreotide, nicorandil and nifedipine on insulin secretion, after pre-incubation with KRBH buffer at 37 °C for 1 h, differentiated cells on day 22 were incubated with KRBH buffer containing vehicle for 1 h at 37 °C, and the supernatant was collected. Then, the same cells were incubated with KRBH buffer containing 50 μg/mL octreotide acetate (Selleck, dissolved in H2O), 200 μM nicorandil (Selleck, dissolved in DMSO), or 50 μM nifedipine (Selleck) for 1 h at 37 °C, and the supernatant was collected. The ratios of C-peptide content for cells treated with octreotide/H2O, nicorandil/DMSO or nifedipine/DMSO were measured as fold changes.
To test the effect of extracellular ATP, calcium ions and ouabain on insulin secretion, after pre-incubation with KRBH buffer at 37 °C for 1 h, differentiated cells on day 22 were incubated with KRBH buffer containing vehicle, and the supernatant was collected. Then, the same cells were incubated with KRBH buffer containing 200 μM ATP (Selleck) 10 mM calcium chloride (CaCl2, Aladdin) or 100 μM ouabain (Selleck) for 1 h at 37 °C, and the supernatant was collected. The ratios of C-peptide content for cells treated with ATP/H2O, calcium chloride/H2O or ouabain/DMSO were measured as fold changes.
To measure the insulin secretion response to different potassium environments, differentiated cells on day 22 were incubated for 35 min at 37 °C in KRBH buffer (normal potassium medium, K+ concentration of 5.9 mM) after pre-incubation with KRBH buffer for 1 h. The cells were then incubated in low potassium medium (KRBH buffer without KCl, K+ concentration of 1.2 mM) and high potassium medium (KRBH buffer plus 30 mM KCl, K+ concentration of 35.9 mM). The ratios of C-peptide content for incubation in low potassium/normal potassium and high potassium/normal potassium were measured as fold changes.
To measure the insulin secretion rate in low, normal and high potassium environments, on day 22, differentiated cells were pre-incubated with KRBH buffer for 1 h and then individually incubated in 3 types of medium at 37 °C. The supernatant was collected at 5 min, 35 min, 65 min and 95 min. The ratios of C-peptide content corresponding to 5 min/5 min, 35 min/5 min, 65 min/5 min, and 95 min/5 min were reported as fold changes. A linear secretion curve was plotted according to the fold change. The fitted line was valid when the R2 value was greater than 0.95. The slope of the straight line was measured as the insulin secretion rate.
Immunofluorescence microscopy and flow cytometry analyses were performed three times, and a representative group was selected. All ELISA experiments were independently performed 3 times. Data are shown as the mean ± SD. Statistical differences between the three groups were evaluated using one-way ANOVA and the Bonferroni post hoc test. Differences were considered significant when the P value was less than 0.05 (*) and highly significant when the P value was less than 0.01 (**).
Data availability statement
All data generated or analysed during this study are included in this published article (and its Supplementary Information files).
Rahman, S. A., Nessa, A. & Hussain, K. Molecular mechanisms of congenital hyperinsulinism. Journal of molecular endocrinology 54, R119–129, doi:10.1530/JME-15-0016 (2015).
Senniappan, S., Arya, V. B. & Hussain, K. The molecular mechanisms, diagnosis and management of congenital hyperinsulinism. Indian journal of endocrinology and metabolism 17, 19–30, doi:10.4103/2230-8210.107822 (2013).
Fournet, J. C. & Junien, C. The genetics of neonatal hyperinsulinism. Hormone research 59 Suppl 1, 30–34, doi:67842 (2003).
Nessa, A., Rahman, S. A. & Hussain, K. Hyperinsulinemic Hypoglycemia - The Molecular Mechanisms. Frontiers in endocrinology 7, 29, doi:10.3389/fendo.2016.00029 (2016).
Kapoor, R. R. et al. Clinical and molecular characterisation of 300 patients with congenital hyperinsulinism. European journal of endocrinology 168, 557–564, doi:10.1530/EJE-12-0673 (2013).
Flanagan, S. E. et al. Update of mutations in the genes encoding the pancreatic beta-cell K(ATP) channel subunits Kir6.2 (KCNJ11) and sulfonylurea receptor 1 (ABCC8) in diabetes mellitus and hyperinsulinism. Hum Mutat 30, 170–180, doi:10.1002/humu.20838 (2009).
Nessa, A. et al. Molecular mechanisms of congenital hyperinsulinism due to autosomal dominant mutations in ABCC8. Hum Mol Genet 24, 5142–5153, doi:10.1093/hmg/ddv233 (2015).
Ashcroft, F. M. ATP-sensitive potassium channelopathies: focus on insulin secretion. The Journal of clinical investigation 115, 2047–2058, doi:10.1172/jci25495 (2005).
Taneja, T. K. et al. Sar1-GTPase-dependent ER exit of KATP channels revealed by a mutation causing congenital hyperinsulinism. Hum Mol Genet 18, 2400–2413, doi:10.1093/hmg/ddp179 (2009).
Seghers, V., Nakazaki, M., DeMayo, F., Aguilar-Bryan, L. & Bryan, J. Sur1 knockout mice. A model for K(ATP) channel-independent regulation of insulin secretion. J Biol Chem 275, 9270–9277 (2000).
Shiota, C. et al. Sulfonylurea receptor type 1 knock-out mice have intact feeding-stimulated insulin secretion despite marked impairment in their response to glucose. J Biol Chem 277, 37176–37183, doi:10.1074/jbc.M206757200 (2002).
Szollosi, A., Nenquin, M. & Henquin, J. C. Pharmacological stimulation and inhibition of insulin secretion in mouse islets lacking ATP-sensitive K+ channels. British journal of pharmacology 159, 669–677, doi:10.1111/j.1476-5381.2009.00588.x (2010).
Mali, P. et al. RNA-guided human genome engineering via Cas9. Science 339, 823–826, doi:10.1126/science.1232033 (2013).
Musunuru, K. Genome editing of human pluripotent stem cells to generate human cellular disease models. Disease models & mechanisms 6, 896–904, doi:10.1242/dmm.012054 (2013).
Gonzalez, F. CRISPR/Cas9 genome editing in human pluripotent stem cells: Harnessing human genetics in a dish. Developmental dynamics: an official publication of the American Association of Anatomists 245, 788–806, doi:10.1002/dvdy.24414 (2016).
Yu, H. & Cowan, C. A. Minireview: Genome Editing of Human Pluripotent Stem Cells for Modeling Metabolic Disease. Mol Endocrinol 30, 575–586, doi:10.1210/me.2015-1290 (2016).
Guo, D. et al. Generation of an Abcc8 heterozygous mutation human embryonic stem cell line using CRISPR/Cas9. Stem Cell Res 17, 670–672, doi:10.1016/j.scr.2016.11.014 (2016).
Guo, D. et al. Generation of an Abcc8 homozygous mutation human embryonic stem cell line using CRISPR/Cas9. Stem Cell Res 17, 640–642, doi:10.1016/j.scr.2016.11.011 (2016).
Kunisada, Y., Tsubooka-Yamazoe, N., Shoji, M. & Hosoya, M. Small molecules induce efficient differentiation into insulin-producing cells from human induced pluripotent stem cells. Stem Cell Res 8, 274–284, doi:10.1016/j.scr.2011.10.002 (2012).
Russ, H. A. et al. Controlled induction of human pancreatic progenitors produces functional beta-like cells in vitro. EMBO J 34, 1759–1772, doi:10.15252/embj.201591058 (2015).
Larsson, O., Ammala, C., Bokvist, K., Fredholm, B. & Rorsman, P. Stimulation of the KATP channel by ADP and diazoxide requires nucleotide hydrolysis in mouse pancreatic beta-cells. The Journal of physiology 463, 349–365 (1993).
Yorifuji, T. Congenital hyperinsulinism: current status and future perspectives. Annals of pediatric endocrinology & metabolism 19, 57–68, doi:10.6065/apem.2014.19.2.57 (2014).
Song, D. K. & Ashcroft, F. M. Glimepiride block of cloned beta-cell, cardiac and smooth muscle K(ATP) channels. British journal of pharmacology 133, 193–199, doi:10.1038/sj.bjp.0704062 (2001).
Massi-Benedetti, M. Glimepiride in type 2 diabetes mellitus: a review of the worldwide therapeutic experience. Clinical therapeutics 25, 799–816 (2003).
Davis, S. N. The role of glimepiride in the effective management of Type 2 diabetes. Journal of diabetes and its complications 18, 367–376, doi:10.1016/j.jdiacomp.2004.07.001 (2004).
Fu, Z., Gilbert, E. R. & Liu, D. Regulation of insulin synthesis and secretion and pancreatic Beta-cell dysfunction in diabetes. Current diabetes reviews 9, 25–53 (2013).
Strowski, M. Z., Parmar, R. M., Blake, A. D. & Schaeffer, J. M. Somatostatin inhibits insulin and glucagon secretion via two receptors subtypes: an in vitro study of pancreatic islets from somatostatin receptor 2 knockout mice. Endocrinology 141, 111–117, doi:10.1210/endo.141.1.7263 (2000).
James, C., Kapoor, R. R., Ismail, D. & Hussain, K. The genetic basis of congenital hyperinsulinism. Journal of medical genetics 46, 289–299, doi:10.1136/jmg.2008.064337 (2009).
Demirbilek, H. et al. Long-term follow-up of children with congenital hyperinsulinism on octreotide therapy. J Clin Endocrinol Metab 99, 3660–3667, doi:10.1210/jc.2014-1866 (2014).
Welters, A. et al. Long-term medical treatment in congenital hyperinsulinism: a descriptive analysis in a large cohort of patients from different clinical centers. Orphanet journal of rare diseases 10, 150, doi:10.1186/s13023-015-0367-x (2015).
Frampton, J., Buckley, M. M. & Fitton, A. Nicorandil. A review of its pharmacology and therapeutic efficacy in angina pectoris. Drugs 44, 625–655 (1992).
Ashcroft, F. M. & Gribble, F. M. ATP-sensitive K+ channels and insulin secretion: their role in health and disease. Diabetologia 42, 903–919, doi:10.1007/s001250051247 (1999).
Arkhammar, P. et al. Extracellular ATP increases cytoplasmic free Ca2+ concentration in clonal insulin-producing RINm5F cells. A mechanism involving direct interaction with both release and refilling of the inositol 1,4,5-trisphosphate-sensitive Ca2+ pool. Biochem J 265, 203–211 (1990).
Geisler, J. C. et al. Vesicular nucleotide transporter-mediated ATP release regulates insulin secretion. Endocrinology 154, 675–684, doi:10.1210/en.2012-1818 (2013).
Tuch, B. E., Osgerby, K. J. & Turtle, J. R. The role of calcium in insulin release from the human fetal pancreas. Cell calcium 11, 1–9 (1990).
Lefebvre, P. J. & Luyckx, A. S. Effect of ouabain on insulin secretion in the anesthetized dog. Biochemical pharmacology 21, 339–345 (1972).
Triner, L. et al. Effects of ouabain on insulin secretion in the dog. Circ Res 25, 119–129 (1969).
Ringer, S. Regarding the Action of Hydrate of Soda, Hydrate of Ammonia, and Hydrate of Potash on the Ventricle of the Frog’s Heart. The Journal of physiology 3, 195–202.196 (1882).
Li, N. et al. Structure of a Pancreatic ATP-Sensitive Potassium Channel. Cell 168, 101–110.e110, doi:10.1016/j.cell.2016.12.028 (2017).
Martin, G. M. et al. Cryo-EM structure of the ATP-sensitive potassium channel illuminates mechanisms of assembly and gating. eLife 6, doi:10.7554/eLife.24149 (2017).
Hrvatin, S. et al. Differentiated human stem cells resemble fetal, not adult, beta cells. Proc Natl Acad Sci USA 111, 3038–3043, doi:10.1073/pnas.1400709111 (2014).
Moore, R. D. Effects of insulin upon ion transport. Biochimica et biophysica acta 737, 1–49 (1983).
Martinez, R., Rietberg, B., Skyler, J., Oster, J. R. & Perez, G. O. Effect of hyperkalemia on insulin secretion. Experientia 47, 270–272 (1991).
D’Amour, K. A. et al. Production of pancreatic hormone-expressing endocrine cells from human embryonic stem cells. Nature biotechnology 24, 1392–1401, doi:10.1038/nbt1259 (2006).
Zhang, D. et al. Highly efficient differentiation of human ES cells and iPS cells into mature pancreatic insulin-producing cells. Cell Res 19, 429–438, doi:10.1038/cr.2009.28 (2009).
Zeng, H. et al. An Isogenic Human ESC Platform for Functional Evaluation of Genome-wide-Association-Study-Identified Diabetes Genes and Drug Discovery. Cell stem cell 19, 326–340, doi:10.1016/j.stem.2016.07.002 (2016).
Rowe, J. W., Tobin, J. D., Rosa, R. M. & Andres, R. Effect of experimental potassium deficiency on glucose and insulin metabolism. Metabolism: clinical and experimental 29, 498–502 (1980).
Chatterjee, R., Yeh, H. C., Edelman, D. & Brancati, F. Potassium and risk of Type 2 diabetes. Expert review of endocrinology & metabolism 6, 665–672, doi:10.1586/eem.11.60 (2011).
Natali, A. et al. Relationship between insulin release, antinatriuresis and hypokalaemia after glucose ingestion in normal and hypertensive man. Clinical science (London, England: 1979) 85, 327-335 (1993).
Takahashi, K. & Yamanaka, S. Induction of pluripotent stem cells from mouse embryonic and adult fibroblast cultures by defined factors. Cell 126, 663–676, doi:10.1016/j.cell.2006.07.024 (2006).
Takahashi, K. et al. Induction of pluripotent stem cells from adult human fibroblasts by defined factors. Cell 131, 861–872, doi:10.1016/j.cell.2007.11.019 (2007).
Passier, R., Orlova, V. & Mummery, C. Complex Tissue and Disease Modeling using hiPSCs. Cell stem cell 18, 309–321, doi:10.1016/j.stem.2016.02.011 (2016).
Xue, Y. et al. Generating a non-integrating human induced pluripotent stem cell bank from urine-derived cells. PLoS One 8, e70573, doi:10.1371/journal.pone.0070573 (2013).
We thank all members of the lab of Prof. Yin-xiong Li. This work was financially supported by Thousand Talents Program (ODCCC2268, Yin-xiong Li), the Ministry of Science and Technology 973 Program (2015CB964700) and the Guangdong Province Science and Technology Plan (2014B020225004, 2015B020230007, 2016B030301007).
The authors declare that they have no competing interests.
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
About this article
Cite this article
Guo, D., Liu, H., Ruzi, A. et al. Modeling Congenital Hyperinsulinism with ABCC8-Deficient Human Embryonic Stem Cells Generated by CRISPR/Cas9. Sci Rep 7, 3156 (2017). https://doi.org/10.1038/s41598-017-03349-w
Protein & Cell (2021)