Impact of Pancreatic Rat Islet Density on Cell Survival during Hypoxia

Rodriguez-Brotons, A.; Bietiger, W.; Peronet, C.; Magisson, J.; Sookhareea, C.; Langlois, A.; Mura, C.; Jeandidier, N.; Pinget, M.; Sigrist, S.; Maillard, E.

doi:https://doi.org/10.1155/2016/3615286

Journal of Diabetes Research

On this page

Abstract Introduction Materials and Methods Results Discussion Conclusion References Copyright Related Articles

Research Article | Open Access

Volume 2016 | Article ID 3615286 | https://doi.org/10.1155/2016/3615286

Impact of Pancreatic Rat Islet Density on Cell Survival during Hypoxia

A. Rodriguez-Brotons,¹W. Bietiger,¹C. Peronet,¹J. Magisson,²C. Sookhareea,¹A. Langlois,¹C. Mura,¹N. Jeandidier,^1,3M. Pinget,^1,3S. Sigrist,¹and E. Maillard¹

Academic Editor: Sergiu Catrina

Received02 Jul 2015

Revised21 Sept 2015

Accepted29 Sept 2015

Published28 Dec 2015

Abstract

In bioartificial pancreases (BP), the number of islets needed to restore normoglycaemia in the diabetic patient is critical. However, the confinement of a high quantity of islets in a limited space may impact islet survival, particularly in regard to the low oxygen partial pressure (PO₂) in such environments. The aim of the present study was to evaluate the impact of islet number in a confined space under hypoxia on cell survival. Rat islets were seeded at three different concentrations (150, 300, and 600 Islet Equivalents (IEQ)/cm²) and cultured in normal atmospheric pressure (160 mmHg) as well as hypoxic conditions (15 mmHg) for 24 hours. Cell viability, function, hypoxia-induced changes in gene expression, and cytokine secretion were then assessed. Notably, hypoxia appeared to induce a decrease in viability and increasing islet density exacerbated the observed increase in cellular apoptosis as well as the loss of function. These changes were also associated with an increase in inflammatory gene transcription. Taken together, these data indicate that when a high number of islets are confined to a small space under hypoxia, cell viability and function are significantly impacted. Thus, in order to improve islet survival in this environment during transplantation, oxygenation is of critical importance.

1. Introduction

Islet transplantation is a minimally invasive therapy recommended for patients with brittle diabetes. Over the last fifteen years, the outcome of this therapy has improved, with a 3-year graft survival rate of 44% [1] as well as a decreased insulin requirement even after partial loss of the graft [2–6]. However, the main advantage of this procedure for diabetic patients is that even if they must be put back on insulin, there is a residual protective effect from hypoglycemic unawareness episodes thanks to a basal level of C-peptide (<0.3 g/L) [1]. Although this treatment option appears to have a number of positive consequences, the negative effects and limitations of the transplant, including the pancreatic requirements, immune suppressive regimen, low rate of insulin independence, short lifespan of the graft, and the recurrence of autoimmunity, have restricted the use of this therapy, particularly when treating children [6, 7].

To address these issues, bioartificial pancreases that encapsulate the cells in a selective shield which lets nutrients and insulin cross the barrier while stopping immune cells and effectively hiding the graft from the host are currently being developed [2, 6]. To immune-isolate the islet cells in this manner, one of two strategies is typically utilized, microencapsulation or macroencapsulation. For the first, one islet to four islets are encapsulated in a microsphere of polymer [2]. This polymer facilitates the exchange of oxygen and nutrients but makes it difficult to retrieve the graft posttransplantation. In contrast, for macroencapsulation, islets are gathered in one or a few distinct devices (e.g., a sheet of polymer, cylindrical device, perfusion device, macrobeads, or selective membrane [2–6, 8]), which allow the grafted cells to be easily removed, providing an additional advantage in the favor of macroencapsulation from a regulatory point of view for clinical application [9, 10]. However, the gathering of these cells can be detrimental as a lower level of oxygen is available in the device and the islets are confined to a much more limited area, potentially increasing the local consumption of oxygen and amplifying the hypoxic conditions surrounding the cells [6].

Physiologically, islets in a normal pancreas make up less than 2% of the whole organ but use approximately 10% of the total oxygen supply. These cells are highly vascularized and not physiologically prepared to face hypoxia. During islet transplantation in the liver, an oxygen partial pressure (PO₂) of 5–10 mmHg has been shown to be enough for their survival [11], but this likely only reflects the level necessary when the islets are directly connected to the vascular system. In a bioartificial pancreas, islets cannot be vascularized as this will disrupt the immune-isolation characteristics necessary for their function. Thus, in these devices, oxygen can only be accessed via membrane diffusion, and PO₂ in a macroencapsulation device is around 15 mmHg (subcutaneously or intraperitoneally [12–15]). It is unlikely that this level is high enough for the cells to function efficiently.

The consequences of hypoxia on islets, including impaired survival and function [16, 17] and increased inflammation [18] associated with the recruitment and activation of host macrophages and leukocytes in the implantation site [19], are well established. Inflammatory molecules such as cytokines and chemokines promote insulitis and β-cell destruction together with an increased production of reactive oxygen species (ROS). The main strategy used to counteract hypoxia-induced loss of islets is to overload the devices with cells with the hope that a few will survive and help reverse the effects of diabetes. In fact, experiments performed with the TheraCyte device, which uses 1,000 islets per device, have demonstrated a 6-month survival period for the graft in an immunized rat [20]. Unfortunately, this previous study only focused on islet function 1 month after transplantation. Furthermore, no data are available concerning islet oxygenation, and the authors have only assumed that the vascularization surrounding the device was able to bring enough oxygen for islet survival. Notably, one of the primary concerns, with increasing the number of islets in the confined environment of the device, is that even more oxygen will be consumed [21, 22], further exacerbating the localized hypoxia.

The number of islets transplanted is also depending on the size of the patient. For instance, a patient that weighs 50 kg would require a graft of 500,000 Islet Equivalents (IEQ). In order to maintain a sufficient number of functioning islet cells, the typical preconized culture density is 150 Islet Equivalents (IEQ)/cm² [21], which means that to transplant this small patient, a single 3,333 cm² device or 500 small 6.67 cm² devices would need to be inserted, which is impossible. Thus, it is essential to increase the number of survival cells/cm².

In the present study, we investigated the effects of islet density in a cellular context that mimics that found in smaller sized bioartificial pancreases using under 15 mmHg of oxygen. In doing so, we sought to establish the effects of hypoxic islet confinement on islet survival, function, and inflammatory potency in order to develop new strategies to improve the outcome of islet transplantation in patients with diabetes.

2. Materials and Methods

2.1. Islet Cell Isolation and Culture

2.1.1. Animals

Male Wistar rats were supplied by Janvier Laboratory (Le Genes St Isle, France). All rats were housed in pathogen-free conditions, in standard collective cages, in a temperature-controlled room (°C) with a 12-hour light/12-hour darkness cycle. They were fed SAFE-A04 (Villemoisson-sur-Orge, France) food and water ad libitum. All experiments were performed according to the National Institutes of Health and local ethical committee (CREMEAS) guidelines (authorization number: C67-482-28).

2.1.2. Islet Isolation

Pancreatic islets were isolated from adult Wistar rat pancreas (weight: 200–250 g) using standard collagenase (Sigma-Aldrich, St. Louis, MO, USA) digestion and Ficoll (Eurobio, Les Ulis, France) purification. Islets were cultured in Medium 199 containing 5.5 mM glucose (Gibco, Life Technologies, Paisley, Scotland) supplemented with 10% heat-inactivated fetal bovine serum (FBS, Sigma-Aldrich), and 1% antibiotic/antimicotic solution (ABAM; 100 units/mL of penicillin, 100 μg/mL of streptomycin, and 0.25 μg/mL of Fungizone; Gibco). After culturing for 24 hours in 25 cm² flasks (Cellstar, Greiner Bio-One GmbH, Frickenhausen, Germany), three different islet densities (150, 300, and 600IEQ/cm²) were seeded in 48-well plates (Greiner). The 150IEQ/cm² density was considered as the control condition in these experiments. Islets were cultured at the specified density for 24 hours in a humidified incubator (StemCell Technologies, Canada) at 37°C under normal atmosphere (PO₂: 160 mmHg) as well as hypoxia conditions (PO₂: 15 mmHg).

2.2. Oxygen Measurements

Oxygen measurements were carried out with a four-channel fiber-optic oxygen meter (Oxy-4) and noninvasive oxygen sensors (Presens, Germany). Briefly, oxygen acts as a dynamic fluorescence quencher of a luminophore in a polymer matrix. Spots, made of this polymer matrix, were glued onto the bottom of each culture well (Presens, Germany), allowing noninvasive measurements of oxygen to be taken through the plastic from the outside. An optic fibre connected to the OXY 4 oxygen meter was guided and positioned from the outside of the chamber to the spot. The data are expressed in mmHg and were taken at time 0 (t0) before placing the plates into the incubators as well as after the 24 h incubation period.

2.3. Islet Viability

Viability of 10 islets from each condition was analyzed by fluorescein diacetate/propidium iodide staining (FDA/PI, Sigma) by three independent investigators. The ratio of green to red cells provided the percentage of islet viability. Images were obtained on a Nikon Eclipse 50i microscope with Nis-Element-BR software (Nikon, Amstelveen, Netherlands).

2.4. ATP Levels

A total of 50 islets from each condition were handpicked and ATP was extracted with mammalian cell lysis solution. Levels of ATP were assessed using an ATPlite kit (PerkinElmer Inc., Waltham, MA, USA) following the manufacturer’s instructions. Results are expressed as μM/50 islets.

2.5. Islet Functionality

A subset of islets () from each experimental condition were washed extensively and incubated in Krebs Ringer bicarbonate (KRB) solution with 10% FBS and 4.4 mmol/L of glucose (Sigma). Islets were then stimulated with KRB solution containing 10% FBS and 22.6 mmol/L of glucose. Each incubation step was performed for 90 min at 37°C in a humidified 5% CO₂ atmosphere. Supernatants were then collected and stored at −80°C. Insulin measurements were performed using a rat insulin enzyme linked immunosorbent assay (ELISA) kit (Mercodia, Uppsala, Sweden). Results are expressed as a stimulated index (SI) defined as the ratio of stimulated versus basal insulin secretion.

2.6. Real-Time PCR

Total cellular RNA was extracted from approximately 400 islets from each condition using a Qiagen RNeasy Mini Kit (Qiagen, CA, USA), following the manufacturer’s instructions. Extracted RNA was reverse-transcribed with a RT² First Strand Kit (Qiagen), according to the manufacturer’s instructions. The resulting cDNAs were diluted 1/100 in RNase-free water. Real-time PCR reactions were performed on a MyiQ Real-Time PCR System (Qiagen) using a QuantiTect SYBR Green PCR kit (Qiagen). Mouse 60S acidic ribosomal protein P1 (Rplp1), mouse peptidylprolyl isomerase A (Ppia), and mouse RNA ribosomal 1 (Rnr1) were chosen as the housekeeping genes (Table 1), and data were analyzed using the ΔΔCt method. The primers for hypoxia-inducible factor 1 alpha (Hif-1α), prostaglandin-endoperoxide synthase 2 (Ptgs2/Cox-2), and heme oxygenase 1 (Hmox1/Ho-1) used in this study were all purchased from Qiagen and are listed in Table 1. Amplification was run using a maximum of 35 cycles.

2.7. Protein Extraction

The total protein content was extracted from 300 islets from each condition using M-PER Mammalian Protein Extraction Reagents and HALT Protease and phosphatase inhibitor cocktail (Thermo Fisher Scientific, Illkirch-Graffenstaden, France). Protein concentration was determined using the Bradford micromethod (Bio-Rad, Life Science Group, Marnes-la-Coquette, France) and is expressed as mg/mL.

Caspase 3 activation in these cytosolic protein extracts of the islets was assessed with a Quantikine ELISA kit (R&D Systems, Minneapolis, MN, USA). Results are expressed in ng/mg of protein.

2.8. HIF-1α Activation (ELISA)

Hif-1α activation was quantified by TransAM HIF-1 (Active Motif, Belgium) following the manufacturer’s instructions. 20 μg of the total protein extraction was used to assess HIF-1α. HIF dimers bind specifically to hypoxia response element (HRE) immobilized in the 96-well plate. HIF dimers are detected by HIF-1α antibody (dilution: 1/500) and a secondary antibody conjugated to HRP (dilution: 1/1000). The results are expressed in OD.

2.9. Inflammation

An aliquot of the culture medium was used to measure the concentration of secreted interleukin- (IL-) 6 (R&D Systems, Minneapolis, MN, USA) under each condition using an ELISA kit. Results are expressed in pg/mL/IEQ.

2.10. Histology

A total of 300 islets from each condition were harvested, washed, and snap-frozen in optimal cutting temperature compound (Tissue O.C.T. Labonord, Templemars, France) and then sliced in 12μm sections. Apoptotic cells were stained using a Terminal deoxynucleotidyl transferase dUTP Nick End Labeling (TUNEL) assay (Millipore, Molsheim, France) and observed by florescence microscopy.

Hypoxic staining was performed using a Hypoxyprobe-1 Kit (HPI Inc. Burlington, MA, USA). Solid pimonidazole HCl was added in the islet cell cultures (150μM). After 24 h culture, islets were fixed with 2% paraformaldehyde (PFA) for 10 min and then incubated with primary and secondary antibodies. The antibodies used in this study include anti-mouse immunoglobulin (IgG₁, 1 : 50 dilution; HPI, Inc.) and Alexa Fluor 488 goat anti-mouse IgG (dilution 1 : 200, Life technologies, Carlsbad, CA, USA).

2.11. Statistical Analysis

Statistical analyses were performed using Statistics software (StatSoft, Maisons-Alfort, France). Results were analyzed with one-way analysis of variance (ANOVA) followed by post hoc Tukey honest significant difference (HSD) testing for the parametric data or Kruskal-Wallis for the nonparametric analysis. Results are expressed as mean ± SEM. A value less than 0.05 was considered statistically significant.

3. Results

3.1. Oxygen Measurement

At t0, the PO₂ was found to be relatively simiar for all three culture densities (150, 300, and 600IEQ/cm²) under both normal and hypoxic conditions (Table 2). However, after 24 hours of exposure to hypoxia (PO₂: 15 mmHg), the PO₂ of the control islet cultures (150IEQ/cm²) dropped to mmHg compared to mmHg under normal conditions. We also observed a decrease in the PO₂ in the cells cultured at the 300 and 600IEQ/cm² densities ( mmHg and mmHg, resp.) compared to the control after being in culture for 24 hours under normoxic conditions. Furthermore, the hypoxia-induced drop in the PO₂ observed in the control islets was exacerbated when the cell density was increased to 300 and 600IEQ/cm² ( mmHg and mmHg, resp.).

3.2. Islet Viability

Under hypoxic conditions, the viability of the islets cultured for 24 hours at a density of 150IEQ/cm² was significantly decreased compared to those under normal atmosphere (Figure 1(a)). A similar trend was observed at the higher densities, with the greatest difference being observed at 600IEQ/cm². Representative FDA/PI stained images of the normal and hypoxic cells at each density are shown in Figure 1(b). These data are supported by a significant increase in Caspase 3 protein expression (Figure 1(c); ) as well as an observed increase in TUNEL staining (Figure 1(d)) in the hypoxia treated cells compared to the normoxia treated cells. Taken together, these data indicate that islet density/confinement did not have a significant effect on the percentage of viable cells when cultured in normoxic conditions but does appear to intensify the effects of hypoxia.

(a)

(b)

(c)

(d)

(e)

Figure 1

Islet viability. (a) Islet viability at each cell density after 24 hours in culture under both normoxic (PO₂ 160 mmHg) and hypoxic (PO₂ 15 mmHg) conditions. (b) Representative fluorescein diacetate/propidium iodide (FDA/PI) stained images of islets cultured at 150, 300, or 600IEQ/cm² under normoxia and hypoxia. Green staining (FDA) indicates that the cells are alive, while red staining (PI) indicates that the cells are dead. Scale bars = 100 μm. (c) Islet apoptosis at each cell density after 24 hours in culture under both normoxic (PO₂ 160 mmHg) and hypoxic (PO₂ 15 mmHg) conditions. (d) Representative images of TUNEL stained cells cultured at 150, 300, or 600IEQ/cm² under normoxia and hypoxia. Blue staining highlights the cell nuclei (DAPI), and the green staining indicates apoptosis. Scale bars = 50 μm. (e) Caspase-3 activation at each cell density after 24 hours in culture under both normoxic (PO₂ 160 mmHg) and hypoxic (PO₂ 15 mmHg) conditions. compared to the control, compared to 600IEQ/cm² normoxia.

3.3. Hypoxia Marker Expression

Not surprisingly, HIF-1α mRNA expression (Figure 2(a)) and hypoxyprobe staining (Figure 2(c)) were significantly increased in the control islets cultured under hypoxic conditions compared to those cultured under normoxic conditions. Furthermore, the density/confinement of the islets also appeared to have a significant impact on the HIF-1α mRNA expression and hypoxyprobe staining when the cells were cultured under hypoxic conditions. A correlation between the increase in density and the activation of HIF-1α protein (Figure 2(b)) appeared under hypoxia and became significant for 600IEQ/cm² () compared to normoxic conditions. In fact, the levels of these hypoxia markers appeared to increase with the increasing level of hypoxia, indicating a particularly significant increase in the cells cultured at 600IEQ/cm² () compared to the cell cultured at 150IEQ/cm² under hypoxic conditions.

(a)

(b)

(c)

Figure 2

Hypoxia marker expression. (a) Levels of hypoxia-inducible factor 1 alpha (HIF-1α) mRNA expression after 24 hours in culture under normoxia (PO₂ 160 mmHg) and hypoxia (PO₂ 15 mmHg) at 150, 300, and 600IEQ/cm². (b) Translocation and activation of HIF-1α protein were performed after 24 hours in each density (150, 300, and 600IEQ/cm²) under normoxia and hypoxia conditions. (c) Representative images of hypoxyprobe stained cells at 150, 300, and 600IEQ/cm² under normoxia and hypoxia. Blue staining highlights the cell nuclei (DAPI), and the green staining indicates pimonidazole (hypoxia marker) expression. Scale bars = 50 μm. compared to the same concentration under normoxic conditions, compared to 150IEQ/cm² under hypoxic conditions, and compared to the control.

3.4. Islet Functionality

Islet function, in terms of ATP levels in the cell, was also evaluated. These data demonstrate that, compared to normoxia, hypoxia induced a significant decrease in the ATP content regardless of cell culture density (). However, this decrease in ATP content was significantly more prominent for the cells culture in the more confined densities compared to those cultured at 150IEQ/cm² () (Figure 3(a)). These results were also supported during our analysis of insulin secretion. We observed a significant loss of function when the cells were cultured under hypoxia compared to normoxia (). At 300IEQ/cm² and 600IEQ/cm², under normoxic conditions we observed a slight decrease in the stimulation index for both densities compared to the control density; however, these islets were still considered functional as their stimulation indices were around or over 2. Under hypoxia, confinement tended to emphasize the loss of function observed in the control density, with the indices being significantly reduced to less than 1 for both the 300IEQ/cm² and 600IEQ/cm² densities compared to 150IEQ/cm² (Figure 3(b)).

(a)

(b)

Figure 3

Islet functionality. (a) ATP levels were measured after 24 hours of culture at the 150, 300, and 600IEQ/cm² under normoxic (PO₂ 160 mmHg) and hypoxic (PO₂ 15 mmHg) conditions. (b) Insulin response to glucose stimulation was measured after 24 hours in culture using a stimulation index. Each density (150, 300, and 600IEQ/cm²) was evaluated under both normoxic (PO₂ 160 mmHg) and hypoxic (PO₂ 15 mmHg) conditions. compared to the control, compared to 150IEQ/cm² under normoxia, and compared to 150IEQ/cm² under hypoxia.

3.5. Inflammation

In order to evaluate the effects of cell density on the inflammatory response induced during hypoxia, we measure the relative mRNA expression of two inflammation markers, Cox-2 and Ho-1, as well as the secretion of IL-6. We observed that hypoxia induced a significant upregulation of both Cox-2 (Figure 4(a), ) and Ho-1 (Figure 4(b), ) mRNA expression compared to normoxia, and these increases in gene expression appear to occur independently of islet density. Interestingly, this response appears to be significantly greater in the control cells compared to the higher densities. Furthermore, IL-6 secretion did not appear to be influenced by the change in PO₂ to hypoxic levels at any cell density. However, IL-6 secretion is seemingly controlled independently of PO₂, as a significant increase was observed for both of the higher densities under normoxic conditions compared to the control cells as well as under hypoxic condition for the 300IEQ/cm² density compared to the control () (Figure 4(c)).

(a)

(b)

(c)

Figure 4

Inflammation. (a) Levels of Cox-2 mRNA expression in islets after 24 hours in culture at 150, 300, and 600IEQ/cm² under normoxic (PO₂ 160 mmHg) and hypoxic (PO₂ 15 mmHg) conditions. (b) Levels of Ho-1 mRNA expression after 24 hours in culture under the specified conditions. (c) IL-6 secretion was measured in islet medium after 24 hours in culture under the specified conditions. compared to the control, compared to 150IEQ/cm² under normoxic conditions, compared to 150IEQ/cm² under normoxic conditions, and and compared to 150IEQ/cm² under hypoxic conditions.

4. Discussion

In the present study, we have shown that the combination of hypoxia and increased islet density/confinement, which are the typical conditions in a bioartificial pancreas, causes an increased level of islet cell death. Indeed, when the recommended culture density was doubled (300IEQ/cm²) or multiplied by four (600IEQ/cm²) and maintained under hypoxic conditions, the overall survival of the islets was very poor, with an observed activation of apoptosis and necrosis factors as well as loss of function and proinflammatory cytokine secretion. To our knowledge, this is the first published study demonstrating the specific effects of hypoxia on confined islet cell survival and function.

In order to effectively and efficiently combat diabetes, it is essential that bioartificial pancreases maintain a sufficient number of viable, fully functioning islets cells. Based on clinical hepatic islet transplantations, 10,000IEQ/kg is needed to reach normoglycaemia [1]. Unfortunately, it has been estimated that approximately 40% of the transplanted islets will die during the instant blood mediated inflammatory reaction (IBMIR) [23] and another 10 to 20% will die during vascularization [24]. These losses can be avoided when using a bioartificial pancreas. However, in contrast with liver transplantation, islets will never be vascularized in a device due to the immune-isolation required. Therefore, no oxygen or nutrients will be delivered directly to islets by the vessels, because only the device can be vascularized [3, 25]. Oxygen will be delivered from the surrounding vessels to the device or via diffusion in the case of nonvascularized devices and will then need to diffuse into the cells, resulting in low cellular PO₂ (around 15 mmHg in the case of nonvascular devices) [15].

Notably, in an alternative study, a β-air II device, with PO₂ between 304 and 198 mmHg in the gas chamber and more than 2,000IEQ/cm², was used once a day to increase oxygenation of encapsulated islets in rats [26]. However, a previous report suggests that such a fluctuation in oxygen, going from hyperoxia to hypoxia, may cause oxygen toxicity [27]. Moreover, the device is not completely independent from external intervention, and it is possible that the oxygen injected into the chamber can actually generate ROS [28]. It is likely that the complications caused by such oxygenating devices will prevent their widespread clinical use.

Thus, in order to compensate for islet cell death in bioartificial pancreases, a higher number of cells are typically cultured in the device. Our results in the present study show that when the number of islets was doubled or increased four times the recommended density for islet culture, the oxygen availability decreased. In fact, the oxygen concentration dropped from 15 mmHg to 7 mmHg at the highest cell density, a change that will undoubtedly have repercussions in terms of islet survival. Interestingly, it has been shown that the cells consuming oxygen will actually create an oxygen gradient [21] further depriving other cells from oxygen. Moreover, under hypoxic conditions, we observed the effects of cell density to be amplified, leading to cell death and loss of function in less than 24 h. Zheng et al. [29] previously demonstrated that adaptation to hypoxia is difficult for normal, untreated islets, suggesting that it could be even more difficult for transplanted/cultured islets. To this end, we have shown that hypoxic conditions combined with confinement triggered HIF-1α transcription, which was also correlated with activation of Cox-2 (involved in inflammatory process) and Ho-1 (involved in oxidative stress) mRNA expression [19]. These data imply that the cells are at least attempting to activate their endogenous defense system against the lack of oxygen. Notably, the increased expression of both Cox-2 and Ho-1 in the higher density cells was significantly lower than the increase observed in the cells cultured at a normal density and appears to be insufficient, leading to an increased rate of apoptosis in the more confined cells. We also observed that secretion of IL-6 is increased as the level of cell confinement increased, regardless of oxygen availability. The role of IL-6 during islet cell survival is controversial in the literature. IL-6 is secreted as a response to cell stress and some studies have suggested that it is deleterious for islet cells [19], while others indicate that it is beneficial for their function [30]. Here, IL-6 secretion appears to be related to confinement only. However, it is possible that the 24-hour time point used in this study may have been too early to see the effects of hypoxia on IL-6 secretion. The increase in IL-6 secretion in the 300 and 600 IEQ/cm² could be also attributed to the paracrine and autocrine effect IL-6 has on its own secretion. Thus, the more cells there are in a limited space, the more IL-6 will be secreted as each islet will be more able to induce the surrounding cells. As this cytokine is known to play a significant role in inflammation [31], its secretion in the more confined cells could affect the recruitment and activation of host macrophages and leukocytes around the device, potentially increasing fibrosis and preventing good vascularization.

In terms of islet cell function, the decrease we observed in cellular ATP was enhanced under hypoxia, a phenomenon that is likely due to ATP leakage, which has been described in cases of organ ischemia [32–34]. Under low PO₂, the tricarboxylic acid cycle cannot be used and the switch for anaerobic respiration is triggered, but this alternative pathway produces a much lower amount of ATP. It was, therefore, not surprising that the level of ATP was significantly decreased during hypoxia. This loss of ATP was also correlated with a decrease in the cell’s ability to respond to glucose stimulation. Notably, ATP and insulin are strongly correlated, and the conversion of proinsulin to insulin and C-peptide is, at least in part, stimulated by ATP-dependent processes [35]. This relationship likely plays a significant role in the decrease function observed in the cells cultured at a higher density under hypoxic conditions.

5. Conclusion

We have shown that islets in a confined environment and under hypoxia suffer from hypoxia-induced apoptosis, oxidative stress, and inflammation, and are nonfunctional after only 24 hours of incubation. In order to improve islet survival in a bioartificial pancreas, the effects of hypoxia need to be reduced, as well as the inflammatory response, in order to improve islet survival and function after transplantation. While this study highlights the need for these changes, additional work is necessary in order to develop new strategies to improve the outcome of islet transplantation in patients with diabetes.

Nomenclature

PO₂:	Oxygen partial pressure
ATP:	Adenosine triphosphate
Rplp1:	Ribosomal protein P1
Ppia:	Peptidylprolyl isomerase A
Rnr1:	RNA ribosomal 1
Hif-1:	Hypoxia-inducible factor 1 alpha
Ptgs2/Cox-2:	Prostaglandin-endoperoxide synthase 2
Hmox1/Ho-1:	Heme oxygenase 1
ROS:	Reactive oxygen species
IEQ:	Islet Equivalents.

Conflict of Interests

The authors declare that there is no duality of interest associated with this paper.

Acknowledgment

This work received financial support from the Cooperation Program of the European Community’s FP7 (Grant number HEALTH-F2-2012-305746).

References

F. B. Barton, M. R. Rickels, R. Alejandro et al., “Improvement in outcomes of clinical islet transplantation: 1999–2010,” Diabetes Care, vol. 35, no. 7, pp. 1436–1445, 2012.
View at: Publisher Site | Google Scholar
D. Dufrane and P. Gianello, “Macro- or microencapsulation of pig islets to cure type 1 diabetes,” World Journal of Gastroenterology, vol. 18, no. 47, pp. 6885–6893, 2012.
View at: Publisher Site | Google Scholar
J.-L. Dulong and C. Legallais, “What are the relevant parameters for the geometrical optimization of an implantable bioartificial pancreas?” Journal of Biomechanical Engineering, vol. 127, no. 7, pp. 1054–1061, 2005.
View at: Publisher Site | Google Scholar
B. Kepsutlu, C. Nazli, T. B. Bal, and S. Kizilel, “Design of bioartificial pancreas with functional micro/nano-based encapsulation of islets,” Current Pharmaceutical Biotechnology, vol. 15, no. 7, pp. 590–608, 2014.
View at: Publisher Site | Google Scholar
B. Ludwig, A. Reichel, A. Steffen et al., “Transplantation of human islets without immunosuppression,” Proceedings of the National Academy of Sciences of the United States of America, vol. 110, no. 47, pp. 19054–19058, 2013.
View at: Publisher Site | Google Scholar
R. A. Pareta, A. C. Farney, and E. C. Opara, “Design of a bioartificial pancreas,” Pathobiology, vol. 80, no. 4, pp. 194–202, 2013.
View at: Publisher Site | Google Scholar
G. Orlando, P. Gianello, M. Salvatori et al., “Cell replacement strategies aimed at reconstitution of the β-cell compartment in type 1 diabetes,” Diabetes, vol. 63, no. 5, pp. 1433–1444, 2014.
View at: Publisher Site | Google Scholar
L. S. Gazda, H. V. Vinerean, M. A. Laramore, R. D. Hall, J. W. Carraway, and B. H. Smith, “Pravastatin improves glucose regulation and biocompatibility of agarose encapsulated porcine islets following transplantation into pancreatectomized dogs,” Journal of Diabetes Research, vol. 2014, Article ID 405362, 10 pages, 2014.
View at: Publisher Site | Google Scholar
K. Tatarkiewicz, J. Hollister-Lock, R. R. Quickel, C. K. Colton, S. Bonner-Weir, and G. C. Weir, “Reversal of hyperglycemia in mice after subcutaneous transplantation of macroencapsulated islets,” Transplantation, vol. 67, no. 5, pp. 665–671, 1999.
View at: Publisher Site | Google Scholar
W. Wang, Y. Gu, H. Hori et al., “Subcutaneous transplantation of macroencapsulated porcine pancreatic endocrine cells normalizes hyperglycemia in diabetic mice,” Transplantation, vol. 76, no. 2, pp. 290–296, 2003.
View at: Publisher Site | Google Scholar
P.-O. Carlsson, P. Liss, A. Andersson, and L. Jansson, “Measurements of oxygen tension in native and transplanted rat pancreatic islets,” Diabetes, vol. 47, no. 7, pp. 1027–1032, 1998.
View at: Publisher Site | Google Scholar
H. Bergert, K.-P. Knoch, R. Meisterfeld et al., “Effect of oxygenated perfluorocarbons on isolated rat pancreatic islets in culture,” Cell Transplantation, vol. 14, no. 7, pp. 441–448, 2005.
View at: Publisher Site | Google Scholar
C. Fraker, M. R. Timmins, R. D. Guarino et al., “The use of the BD oxygen biosensor system to assess isolated human islets of Langerhans: oxygen consumption as a potential measure of islet potency,” Cell Transplantation, vol. 15, no. 8-9, pp. 745–758, 2006.
View at: Publisher Site | Google Scholar
J. Lau, J. Henriksnäs, J. Svensson, and P.-O. Carlsson, “Oxygenation of islets and its role in transplantation,” Current Opinion in Organ Transplantation, vol. 14, no. 6, pp. 688–693, 2009.
View at: Publisher Site | Google Scholar
S. Vériter, N. Aouassar, P.-Y. Adnet et al., “The impact of hyperglycemia and the presence of encapsulated islets on oxygenation within a bioartificial pancreas in the presence of mesenchymal stem cells in a diabetic Wistar rat model,” Biomaterials, vol. 32, no. 26, pp. 5945–5956, 2011.
View at: Publisher Site | Google Scholar
J. Cantley, S. T. Grey, P. H. Maxwell, and D. J. Withers, “The hypoxia response pathway and β-cell function,” Diabetes, Obesity and Metabolism, vol. 12, supplement 2, pp. 159–167, 2010.
View at: Publisher Site | Google Scholar
K. E. Dionne, C. K. Colton, and M. L. Yarmush, “Effect of hypoxia on insulin secretion by isolated rat and canine islets of Langerhans,” Diabetes, vol. 42, no. 1, pp. 12–21, 1993.
View at: Publisher Site | Google Scholar
S. Marzorati, B. Antonioli, R. Nano et al., “Culture medium modulates proinflammatory conditions of human pancreatic islets before transplantation,” American Journal of Transplantation, vol. 6, no. 11, pp. 2791–2795, 2006.
View at: Publisher Site | Google Scholar
K. Vivot, A. Langlois, W. Bietiger et al., “Pro-inflammatory and pro-oxidant status of pancreatic islet in vitro is controlled by TLR-4 and HO-1 pathways,” PLoS ONE, vol. 9, no. 10, Article ID e107656, 2014.
View at: Publisher Site | Google Scholar
M. Kumagai-Braesch, S. Jacobson, H. Mori et al., “The theracyte device protects against islet allograft rejection in immunized hosts,” Cell Transplantation, vol. 22, no. 7, pp. 1137–1146, 2013.
View at: Publisher Site | Google Scholar
P. Buchwald, “FEM-based oxygen consumption and cell viability models for avascular pancreatic islets,” Theoretical Biology and Medical Modelling, vol. 6, article 5, 2009.
View at: Publisher Site | Google Scholar
P. Buchwald, “A local glucose-and oxygen concentration-based insulin secretion model for pancreatic islets,” Theoretical Biology and Medical Modelling, vol. 8, no. 1, article 20, 2011.
View at: Publisher Site | Google Scholar
R. D. Ramnath, E. Maillard, K. Jones et al., “In vitro assessment of human islet vulnerability to instant blood mediated inflammatory reaction (IBMIR) and its use to demonstrate a beneficial effect of tissue culture,” Cell Transplantation, 2014.
View at: Publisher Site | Google Scholar
A. Langlois, W. Bietiger, E. Seyfritz et al., “Improvement of rat islet viability during transplantation: validation of pharmacological approach to induce VEGF overexpression,” Cell Transplantation, vol. 20, no. 9, pp. 1333–1342, 2011.
View at: Publisher Site | Google Scholar
J.-L. Dulong and C. Legallais, “A theoretical study of oxygen transfer including cell necrosis for the design of a bioartificial pancreas,” Biotechnology and Bioengineering, vol. 96, no. 5, pp. 990–998, 2007.
View at: Publisher Site | Google Scholar
U. Barkai, G. C. Weir, C. K. Colton et al., “Enhanced oxygen supply improves islet viability in a new bioartificial pancreas,” Cell Transplantation, vol. 22, no. 8, pp. 1463–1476, 2013.
View at: Publisher Site | Google Scholar
E. Maillard, M. T. Juszczak, A. Langlois et al., “Perfluorocarbon emulsions prevent hypoxia of pancreatic β-cells,” Cell Transplantation, vol. 21, no. 4, pp. 657–669, 2012.
View at: Publisher Site | Google Scholar
X. Li, H. Chen, and P. N. Epstein, “Metallothionein protects islets from hypoxia and extends islet graft survival by scavenging most kinds of reactive oxygen species,” The Journal of Biological Chemistry, vol. 279, no. 1, pp. 765–771, 2004.
View at: Publisher Site | Google Scholar
X. Zheng, X. Zheng, X. Wang et al., “Acute hypoxia induces apoptosis of pancreatic β-cell by activation of the unfolded protein response and upregulation of CHOP,” Cell Death and Disease, vol. 3, no. 6, article e322, 2012.
View at: Publisher Site | Google Scholar
F. Kahles, C. Meyer, J. Möllmann et al., “GLP-1 secretion is increased by inflammatory stimuli in an IL-6-dependent manner, leading to hyperinsulinemia and blood glucose lowering,” Diabetes, vol. 63, no. 10, pp. 3221–3229, 2014.
View at: Publisher Site | Google Scholar
L. E. Padgett, K. A. Broniowska, P. A. Hansen, J. A. Corbett, and H. M. Tse, “The role of reactive oxygen species and proinflammatory cytokines in type 1 diabetes pathogenesis,” Annals of the New York Academy of Sciences, vol. 1281, no. 1, pp. 16–35, 2013.
View at: Publisher Site | Google Scholar
D. Brandhorst, H. Brandhorst, B. J. Hering, K. Federlin, and R. G. Bretzel, “Large variability of the intracellular ATP content of human islets isolated from different donors,” Journal of Molecular Medicine, vol. 77, no. 1, pp. 93–95, 1999.
View at: Publisher Site | Google Scholar
Y. Kuroda, K. Hiraoka, Y. Tanioka et al., “Role of adenosine in preservation by the two-layer method of ischemically damaged canine pancreas,” Transplantation, vol. 57, no. 7, pp. 1017–1020, 1994.
View at: Publisher Site | Google Scholar
M. L. Riess, E. Novalija, A. K. S. Camara, J. T. Eells, Q. Chen, and D. F. Stowe, “Preconditioning with sevoflurane reduces changes in nicotinamide adenine dinucleotide during ischemia-reperfusion in isolated hearts: reversal by 5-hydroxydecanoic acid,” Anesthesiology, vol. 98, no. 2, pp. 387–395, 2003.
View at: Publisher Site | Google Scholar
C. J. Rhodes, C. A. Lucas, R. L. Mutkoski, L. Orci, and P. A. Halban, “Stimulation by ATP of proinsulin to insulin conversion in isolated rat pancreatic islet secretory granules. Association with the ATP-dependent proton pump,” Journal of Biological Chemistry, vol. 262, no. 22, pp. 10712–10717, 1987.
View at: Google Scholar

Copyright

Copyright © 2016 A. Rodriguez-Brotons et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

PDF Download Citation

Download other formats

Order printed copies

Views

2022

Downloads

1130

Citations