STAT3 Regulates Mitochondrial Gene Expression in Pancreatic ß-Cells and Its Deficiency Induces Glucose Intolerance in Obesity.

Most obese and insulin-resistant individuals do not develop diabetes. This is the result of the capacity of ß-cells to adapt and produce enough insulin to cover the needs of the organism. The underlying mechanism of ß-cell adaptation in obesity, however, remains unclear. Previous studies have suggested a role for STAT3 in mediating ß-cell development and human glucose homeostasis, but little is known about STAT3 in ß-cells in obesity. We observed enhanced cytoplasmic expression of STAT3 in severely obese subjects with diabetes. To address the functional role of STAT3 in adult ß-cells, we generated mice with tamoxifen-inducible partial or full deletion of STAT3 in ß-cells and fed them a high-fat diet before analysis. Interestingly, ß-cell heterozygous and homozygous STAT3-deficient mice showed glucose intolerance when fed a high-fat diet. Gene expression analysis with RNA sequencing showed that reduced expression of mitochondrial genes in STAT3 knocked down human EndoC-ß1H cells, confirmed in FACS-purified ß-cells from obese STAT3-deficient mice. Moreover, silencing of STAT3 impaired mitochondria activity in EndoC-ß1H cells and human islets, suggesting a mechanism for STAT3-modulated ß-cell function. Our study postulates STAT3 as a novel regulator of ß-cell function in obesity.

Glycaemic control in diabetic rats treated with islet transplantation using plasma combined with hydroxypropylmethyl cellulose hydrogel.

Islet transplantation is one of the most efficient cell therapies used in clinics and could treat a large proportion of patients with diabetes. However, it is limited by the high requirement of pancreas necessary to provide the sufficient surviving islet mass in the hepatic tissue and restore normoglycaemia. Reduction in organ procurement requirements could be achieved by extrahepatic transplantation using a biomaterial that enhances islet survival and function. We report a plasma-supplemented hydroxypropyl methylcellulose (HPMC) hydrogel, engineered specifically using a newly developed technique for intra-omental islet infusion, known as hOMING (h-Omental Matrix Islet filliNG). The HPMC hydrogel delivered islets with better performance than that of the classical intrahepatic infusion. After the validation of the HPMC suitability for islets in vivo and in vitro, plasma supplementation modified the rheological properties of HPMC without affecting its applicability with hOMING. The biomaterial association was proven to be more efficient both in vitro and in vivo, with better islet viability and function than that of the current clinical intrahepatic delivery technique. Indeed, when the islet mass was decreased by 25% or 35%, glycaemia control was observed in the group of plasma-supplemented hydrogels, whereas no regulation was observed in the hepatic group. Plasma gelation, observed immediately post infusion, decreased anoïkis and promoted vascularisation. To conclude, the threshold mass for islet transplantation could be decreased using HPMC-Plasma combined with the hOMING technique. The simplicity of the hOMING technique and the already validated use of its components could facilitate its transfer to clinics. STATEMENT OF SIGNIFICANCE: One of the major limitations for the broad deployment of current cell therapy for brittle type 1 diabetes is the islets' destruction during the transplantation process. Retrieved from their natural environment, the islets are grafted into a foreign tissue, which triggers massive cell loss. It is mandatory to provide the islets with an 3D environment specifically designed for promoting isletimplantation to improve cell therapy outcomes. For this aim, we combined HPMC and plasma. HPMC provides suitable rheological properties to the plasma to be injectable and be maintained in the omentum. Afterwards, the plasma polymerises around the graft in vivo, thereby allowing their optimal integration into their transplantation site. As a result, the islet mass required to obtain glycaemic control was reduced by 35%.

Intra-Omental Islet Transplantation Using h-Omental Matrix Islet filliNG (hOMING).

Regenerative medicine based on cell therapy represents a new hope for curing disease. Current obstacles include proper in vivo validation of the efficiency of the therapy. For transfer to the recipient body, cells often need to be combined with biomaterials, especially hydrogels. However, validation of the efficacy of such a graft requires the right environment, the right hydrogel, and the right recipient site. The omentum might be such a site. Based on the example of islet transplantation, we developed the hOMING (h-Omental Matrix Islet filliNG) technique, which consists of the injection of the graft inside the tissue, in between the omental layers, to improve islet implantation and survival. To achieve this, islets have to be embedded in a hydrogel with a viscosity that enables its injection using an atraumatic needle. Syringes are loaded with a combination of hydrogel and islets. Several injections are performed inside the omental tissue at different entry points, and the deposition of the islet/hydrogel mixture is made along a line. We tested the feasibility of this innovative approach using dextran beads. The beads were well spread throughout the omental tissue, in close proximity to blood vessels. To test the efficacy of the graft, we transplanted islets into diabetic rats and perform a metabolic follow-up over two months. The transplanted islets exhibited a high rate of re-vascularization around and inside islets, and reversed diabetes. The hOMING technique could be applicable for other types of hydrogel or cell therapy, for cells with high metabolic activity.

Extra-Hepatic Islet Transplantation: Validation of the h-Omental Matrix Islet filliNG (hOMING) Technique on a Rodent Model Using an Alginate Carrier.

Following the tremendous development of hydrogels for cell therapy, there is now a growing need for surgical techniques to validate in vivo scaffold benefits for islet transplantation. Therefore, we propose a newly designed surgical procedure involving the injection of hydrogel-embedded pancreatic islets in the omentum, which is considered a favorable environment for cell survival and function. Our technique, called h-Omental Matrix Islet filliNG (hOMING) was designed to test the benefits of hydrogel on islet survival and function in vivo. Islets were implanted in the omentum of diabetic rats using the hOMING technique and alginate as an islet carrier. Blood glucose and C-peptide levels were recorded to assess graft function. After 2 months, grafts were explanted and studied using insulin and vessel staining. All rats that underwent hOMING exhibited graft function characterized by a glycemia decrease and a C-peptidemia increase ( P < 0.001 compared with preoperative levels). Furthermore, hOMING appeared to preserve islet morphology and insulin content and allowed the proper revascularization of grafted islets. The results suggest that hOMING is a viable and promising approach to test in vivo the benefits of hydrogel administration for islet transplantation into the omental tissue.

Oral insulin delivery, the challenge to increase insulin bioavailability: Influence of surface charge in nanoparticle system.

Oral administration of insulin increases patient comfort and could improve glycemic control thanks to the hepatic first passage. However, challenges remain. The current approach uses poly (d, lactic-co-glycolic) acid (PLGA) nanoparticles (NPs), an effective drug carrier system with a long acting profile. However, this system presents a bioavailability of less than 20% for insulin encapsulation. In this context, physico-chemical parameters like surface charge could play a critical role in NP uptake by the intestinal barrier. Therefore, we developed a simple method to modulate NP surface charge to test its impact on uptake in vitro and finally on NP efficiency in vivo. Various NPs were prepared in the presence (+) or absence (-) of polyvinyl alcohol (PVA), sodium dodecyl sulfate (SDS), and/or coated with chitosan chloride. In vitro internalization was tested using epithelial culture of Caco-2 or using a co-culture (Caco-2/RevHT29MTX) by flow cytometry. NPs were then administered by oral route using a pharmaceutical complex vector (100 or 250 UI/kg) in a diabetic rat model. SDS-NPs (-42 ±â€¯2 mV) were more negatively charged than -PVA-NPs (-22 ±â€¯1 mV) and chitosan-coated NPs were highly positively charged (56 ±â€¯2 mV) compared to +PVA particles (-2 ±â€¯1 mV), which were uncharged. In the Caco-2 model, NP internalization was significantly improved by using negatively charged NPs (SDS NPs) compared to using classical NPs (+PVA NPs) and chitosan-coated NPs. Finally, the efficacy of insulin SDS-NPs was demonstrated in vivo (100 or 250 UI insulin/kg) with a reduction of blood glucose levels in diabetic rats. Formulation of negatively charged NPs represents a promising approach to improve NP uptake and insulin bioavailability for oral delivery.

Portal or subcutaneous insulin infusion: efficacy and impact on liver inflammation.

Intraperitoneal insulin allows physiological portal insulin administration and first-pass hepatic insulin extraction, but the impact on liver metabolism and inflammation is unknown. Our objective was to compare the impact, on metabolic control and liver function, of the same dose of insulin administered either intraperitoneally or subcutaneously during continuous infusion in diabetic rats. Wistar rats were randomly divided into 4 groups: control (C), untreated diabetic (streptozotocin, 100 mg/kg) and diabetic rats treated by continual subcutaneous Insuplant® infusion (CSII) and continual intraperitoneal Insuplant(®) infusion (CPII) of 2 UI/200 g/day (via an osmotic mini-pump for 1-4 weeks). Insulin signalling pathways were analysed through hepatic expression of growth hormone receptor and phosphorylated insulin receptor substrate 1. Metabolic control was determined by measurement of body weight, blood glucose and fructosamine. Liver function was assessed by measuring insulin-like growth factor-1 (IGF-1), with global inflammation assessed by levels of alpha-2-macroglobulin (α2M) and lipid peroxidation in plasma. Liver inflammation was evaluated by quantification of hepatic macrophage infiltration and reactive oxygen species production. CPII induced a better improvement in metabolic control and liver function than CSII, producing a significant decrease in blood glucose and fructosamine, coupled with increased IGF-1 and hepatic glycogen storage. Moreover, liver oxidative stress and liver inflammation were reduced. Such observations indicate that the same insulin level in CPII improves glucose control and hepatic glucose metabolism and function, attenuating the hepatic inflammatory response to diabetes. These data demonstrate the importance of focusing on therapeutics to allow first-pass hepatic insulin extraction or prevent diabetic complications.