Labeling Of Islets Research Articles

Synergistic Effect of Islet Magnetic Resonance Imaging Using Direct Linking of Ferumoxytol to Surface of PEGylated Islet

Purpose: We previously reported the feasibility of islet magnetic resonance imaging (MRI) using ferumoxytol, which is the only clinically-available ultrasmall superparamagnetic iron oxide. However, the labeling efficacy was not sufficient for its clinical use in islet transplantation. We aimed to evaluate the feasibility of islet MRI using direct linking of ferumoxytol to islet surface through PEGylation. Method: Islets were labeled by surface modification with up to 4% PEG-heparin-ferumoxytol. We compared islet function and viability of control islets and ferumoxytol-heparin-PEGylated islets. Efficacy of labeling with ferumoxytol-heparin-PEGylation and ferumoxytol alone was assessed in both ex vivo and in vivo models. Results: Labeling of islets with up to 2% PEG-heparin-ferumoxytol did not derange ex vivo islet viability and function. The T2* relaxation time was optimal when islets were labeled with 1 to 4% PEG-heparin-ferumoxytol. The labeling intensity in the ex vivo MRI of ferumoxytol-heparin-PEGylated islets was stronger than islets labeled with ferumoxytol alone. In syngeneic renal subcapsular islet transplantation, labeling with ferumoxytol-heparin-PEGylation showed better in vivo labeling efficacy than that of islets labeled with ferumoxytol alone. After labeling with ferumoxytol-heparin-PEGylation, there was a correlation between the total area of visualized islets and the transplanted islet mass in syngeneic mouse intraportal islet transplantation, and the visibility was also confirmed in the preliminary analysis of non-human primate intraportal islet transplantation model. Conclusion: Direct linking of ferumoxytol to islet surface through PEGylation improved the labeling efficacy and it could be used for the islet MRI in clinical islet transplantation. Disclosure H. Lee: None. Y. Kwon: None. H. Kim: None. M.R. Haque: None. G. Kim: None. S. Jin: None. M. Lee: None. Y. Byun: None. J. Kim: None.

Improved Labeling of Pancreatic Islets Using Cationic Magnetoliposomes.

Pancreatic islets (PIs) transplantation is an alternative approach for the treatment of severe forms of type 1 diabetes (T1D). To monitor the success of transplantation, it is desirable to follow the location of engrafted PIs non-invasively. In vivo magnetic resonance imaging (MRI) of transplanted PIs is a feasible cell tracking method; however, this requires labeling with a suitable contrast agent prior to transplantation. We have tested the feasibility of cationic magnetoliposomes (MLs), compared to commercial contrast agents (Endorem and Resovist), by labeling insulinoma cells and freshly isolated rat PIs. It was possible to incorporate Magnetic Ressonance (MR)-detectable amounts of MLs in a shorter time (4 h) when compared to Endorem and Resovist. MLs did not show negative effects on the PIs’ viability and functional parameters in vitro. Labeled islets were transplanted in the renal sub-capsular region of healthy mice. Hypointense contrast in MR images due to the labeled PIs was detected in vivo upon transplantation, while MR detection of PIs labeled with Endorem and Resovist was only possible after the addition of transfection agents. These findings indicate that MLs are suitable to image PIs, without affecting their function, which is promising for future longitudinal pre-clinical and clinical studies involving the assessment of PI transplantation.

Multiplex Sequential Immunoprecipitation of Insulin Secretory Granule Proteins from Radiolabeled Pancreatic Islets.

Pulse radiolabeling of cells with radioactive amino acids is a common method for tracking the biosynthesis of proteins. Specific proteins can then be immunoprecipitated and analyzed by electrophoresis and imaging techniques. This chapter presents a protocol for the biosynthetic labeling of pancreatic islets with 35S-methionine, followed by multiplex sequential immunoprecipitation of insulin and three other secretory granule accessory proteins. This provided a means of distinguishing those pancreatic islet proteins with different biosynthetic rates in response to the media glucose concentrations.

Two Dimensional Gel Electrophoresis of Insulin Secretory Granule Proteins from Biosynthetically-Labeled Pancreatic Islets.

Pulse-chase radiolabeling of cells with radioactive amino acids is a common method for tracking the biosynthesis of proteins. Radiolabeled newly synthesized proteins can be analyzed by a number of techniques such as two dimensional gel electrophoresis (2DE). This chapter presents a protocol for the biosynthetic labeling of pancreatic islets with 35S-methionine in the presence of basal and stimulatory concentrations of glucose, followed by subcellular fractionation to produce a secretory granule fraction and analysis of the granule protein contents by 2DE. This provides a means of determining whether or not the biosynthetic rates of the entire granule constituents are coordinately regulated.

Labeling and Tracking of Human Pancreatic Islets Using Carbon Nanotubes.

Limited tools are available for the non-invasive monitoring of transplanted islets. In this study, we have compared the widely used superparamagnetic iron oxide nanoparticle ferumoxide (Endorem) and multiwalled carbon nanotubes (MWCNTs) for islet cell labeling and tracking. INS-1 E cells and human pancreatic islets isolated from 12 non-diabetic cadaveric organ donors (age: 62 ±16 yr, BMI: 24.6 ± 3.3 kg/m2) were incubated with 50 μg/ml Endorem or 15 μg/ml MWCNTs and studied after 7 or 14 days to assess beta cell morphology, ultrastructure, function, cell survival and in-vitro and in-vivo magnetic resonance imaging (MRI). Light and electron (EM) microscopy showed the well-maintained morphology and ultrastructure of both INS-1 E and human islets during the incubation. EM also revealed the presence of Endorem and MWCNTs within the beta but not the alpha cells. The compounds did not affect beta cell function and viability, and in-vitro MRI showed that labeled INS-1 E cells and human islets could be imaged. Finally, MWCNT labeled human islets were successfully transplanted into the subcutis of rats localized in the desired site via magnetic field and tracked by MRI. These data suggest that MWCNTs can be an alternative labeling compound to be used with human islets for experimental and transplantation studies.

Synthesis and preclinical characterization of [64Cu]NODAGA-MAL-exendin-4 with a Nε-maleoyl-l-lysyl-glycine linkage

Renal localization of high radioactivity levels during targeted imaging compromises tissue visualization in the kidney region and limits diagnostic accuracy. Radioiodinated antibody fragments with a renal enzyme-cleavable N(ε)-maleoyl-L-lysyl-glycine (MAL) linkage demonstrated low renal radioactivity levels in mice, from early postinjection times. This study tested the hypothesis whether a (64)Cu-labeled NODAGA-exendin-4 peptide with a MAL linkage ([(64)Cu]NODAGA-MAL-exendin-4) could decrease kidney radioactivity levels in rats, compared to a [(64)Cu]NODAGA-exendin-4 reference, without impairing the radioactivity levels in the target tissue. NODAGA-MAL-exendin-4 was synthesized in a two-phase approach using solid support to prepare maleoyl-derivatized NODAGA followed by Michael addition to cysteine-derivatized exendin-4 in solution. Radiolabeling was performed in buffered aqua with [(64)Cu]CuCl2, which was produced via the (64)Ni(p,n)(64)Cu nuclear reaction. The in vitro and in vivo stability, lipophilicity, and distribution kinetics in major rat organs for [(64)Cu]NODAGA-MAL-exendin-4 were studied and compared to [(64)Cu]NODAGA-exendin-4. Labeling of pancreatic islets was assessed using autoradiography. NODAGA-MAL-exendin-4 was synthesized, with an overall yield of 9%, and radiolabeled with (64)Cu with high specific radioactivity. Serum incubation studies showed high stability for [(64)Cu]NODAGA-MAL-exendin-4. Similar tissue distribution kinetics was observed for [(64)Cu]NODAGA-MAL-exendin-4 and [(64)Cu]NODAGA-exendin-4, with high kidney radioactivity levels. The incorporated MAL linkage in [(64)Cu]NODAGA-MAL-exendin-4 was unable to reduce kidney radioactivity levels, compared to [(64)Cu]NODAGA-exendin-4. The applicability of metabolizable linkages in the design of kidney-saving exendin-4 analogs requires further investigation.

Magnetic separation of encapsulated islet cells labeled with superparamagnetic iron oxide nano particles

Islet cell transplantation is a promising option for the restoration of normal glucose homeostasis in patients with type 1 diabetes. Because graft volume is a crucial issue in islet transplantations for patients with diabetes, we evaluated a new method for increasing functional tissue yield in xenogeneic grafts of encapsulated islets. Islets were labeled with three different superparamagnetic iron oxide nano particles (SPIONs; dextran-coated SPION, siloxane-coated SPION, and heparin-coated SPION). Magnetic separation was performed to separate encapsulated islets from the empty capsules, and cell viability and function were tested. Islets labeled with 1000 μg Fe/ml dextran-coated SPIONs experienced a 69.9% reduction in graft volume, with a 33.2% loss of islet-containing capsules. Islets labeled with 100 μg Fe/ml heparin-coated SPIONs showed a 46.4% reduction in graft volume, with a 4.5% loss of capsules containing islets. No purification could be achieved using siloxane-coated SPIONs due to its toxicity to the primary islets. SPION labeling of islets is useful for transplant purification during islet separation as well as in vivo imaging after transplantation. Furthermore, purification of encapsulated islets can also reduce the volume of the encapsulated islets without impairing their function by removing empty capsules.

Activin receptor-like kinase 5 inhibition reverses impairment of endothelial cell viability by endogenous islet mesenchymal stromal cells.

Following islet transplantation, islet graft revascularization is compromised due to loss of endothelial cells (ECs) during islet culture. TGF-β signaling pathways are essential for vascular homeostasis but their importance for islet EC function is unclear. We have identified a population of multipotent mesenchymal stromal cells (MSCs) within islets and investigated how modulation of TGF-β signaling by these cells influences islet EC viability. Cultured islets exhibited reduced expression of EC markers (VEGFR2, VE-cadherin and CD31), which was associated with diminished but sustained expression of endoglin a marker of both ECs and MSCs. Double fluorescent labeling of islets in situ with the EC marker CD31 disclosed a population of CD31-negative cells which were positive for endoglin. In vitro coculture of microvascular ECs with endoglin-positive, CD31-negative islet MSCs reduced VEGFR2 protein expression, disrupted EC angiogenic behavior, and increased EC detachment. Medium conditioned by islet MSCs significantly decreased EC viability and increased EC caspase 3/7 activity. EC:MSC cocultures showed enhanced Smad2 phosphorylation consistent with altered ALK5 signaling. Pharmacological inhibition of ALK5 activity with SB431542 (SB) improved EC survival upon contact with MSCs, and SB-treated cultured islets retained EC marker expression and sensitivity to exogenous VEGF164 . Thus, endoglin-expressing islet MSCs influence EC ALK5 signaling in vitro, which decreases EC viability, and changes in ALK5 activity in whole cultured islets contribute to islet EC loss. Modifying TGF-β signaling may enable maintenance of islet ECs during islet isolation and thus improve islet graft revascularization post-transplantation.

Processing of superparamagnetic iron contrast agent ferucarbotran in transplanted pancreatic islets

Labeling of pancreatic islets with superparamagnetic iron oxide (SPIO) nanoparticles enables their post-transplant monitoring by magnetic resonance imaging (MRI). Although the nanoparticles are incorporated into islet cells in culture, little is known about their fate in vivo. We studied the morphology of labeled islets after transplantation, aiming to identify the MRI contrast particles and their relationship to transplantation outcomes. Rat islets labeled with the ferucarbotran were transplanted into the liver or under the kidney capsule of syngeneic and allogeneic rats. After in vivo MRI, morphology was studied by light, fluorescence and transmission electron microscopy. Morphology of syngeneic islets transplanted beneath the kidney capsule vs into the liver was similar. Iron particles were almost completely eliminated from the endocrine cells and remained located in host-derived macrophages surrounding the vital islets for the entire study period. In the allogeneic model, islets lost their function and were completely rejected within nine days following transplantation in both transplant models. However, intercellular transport of the SPIO particles and subsequent MRI findings was different in the liver and kidney. In the liver, the decreasing number of islet-related MRI spots corresponded with clearance of iron particles in rejected islets; in contrast, with renal transplants extensive iron deposits with a high effect on MRI signal persisted in phagocytic cells beneath the capsule. We conclude that MRI detection of the iron contrast agent correlates with islet survival and function in islet transplantation into the liver, while it does not correlate in the case of transplantation beneath the renal capsule.

Non-Invasive Imaging of Ferucarbotran Labeled INS-1E Cells and Rodent Islets in Vitro and in Transplanted Diabetic Rats

Transplantation of pancreatic islets is a promising strategy for restoring insulin secretion in diabetes mellitus. To monitor transplanted islets, a method to evaluate the distribution in a non-invasive manner in vivo is needed. INS-1E, a stable differentiated insulin secreting cell line, and rodent islets were used to monitor cell transplantation by MRI. For labeling INS-1E cells in vitro, increasing concentrations of Resovist in culture medium were tested. For MR imaging in a clinical 3T scanner, we placed a layer of labeled INS-1E cells between two layers of 4% gelatin. Viability assay was performed. Cell function was evaluated by static incubation assay to assess insulin secretion. For in vivo imaging, iron labeled rodent islets were transplanted into the liver of streptozotocin induced diabetic rats and visualized by MRI. Blood sugar values were controlled and liver tissue was removed for histological analysis. SPIO labeled INS-1E cells did not show altered viability or reduced glucose stimulated insulin secretion in vitro. Double staining of labeled and unlabeled INS-1E cells showed no difference in the staining pattern. Labeling of rodent islets with SPIOs does not reduce their secretory activity or alter their viability. We visualized SPIO-labeled INS-1E cells and rat islets in vitro using a clinical 3T scanner. Diabetic rats transplanted with SPIO-labeled islets became normoglycemic. MR imaging successfully verified the distribution of labeled transplanted cells in vivo. Labeling INS-1E cells and rat islets with SPIOs does not alter their viability, while enabling MR imaging of labeled cells in vitro and within the living organism.

Magnetic Resonance Imaging of Pancreatic Islets Transplanted Into the Liver in Humans

In vitro labeling of pancreatic islets by iron nanoparticles enables their detection as hypoitnense spots on serial magnetic resonance (MR) images. We report the first results of a pilot trial aiming to test the feasibility and safety of this technique in humans. Islets were labeled in culture with 5 μL/mL ferucarbotran for 6 to 48 hr and transplanted into the portal vein (12 infusions) in 8 C-peptide negative recipients. The liver area was examined the next day and 1, 4, and 24 weeks posttransplant using a 3T MR scanner. In all recipients, significant C-peptide levels and near-normal HbA1c values were achieved with 50% to 80% insulin dose reduction. No side effects related to the labeling procedure were documented. Typically, a significant islet spot number decrease (on average 60%) was detected at week 1 with subsequent only slight decrease for up to 24 weeks. In two subjects with labeling period of less than 6 and 10 hr, only few islet spots were detected corresponding to poor islet visualization in phantoms labeled for the same period of time. Pancreatic islets (PI) visualization was safe and successful in all recipients but was less efficient if labeling period was less than 16 hr. Significant decrease of islet spots occurred at week 1, suggesting early islet destruction or impaired engraftment. Afterward, the islet spot numbers remained stable for up to 24 weeks. Data show that MR detection of ferucarbotran-labeled islets enables their long-term noninvasive visualization and correlates with sustained C-peptide production.

Assessment of Human Islet Labeling with Clinical Grade Iron Nanoparticles Prior to Transplantation for Graft Monitoring by MRI

Ex vivo labeling of islets with superparamagnetic iron oxide (SPIO) nanoparticles allows posttransplant MRI imaging of the graft. In the present study, we compare two clinical grade SPIOs (ferucarbotran and ferumoxide) in terms of toxicity, islet cellular uptake, and MRI imaging. Human islets (80-90% purity) were incubated for 24 h with various concentrations of SPIOs (14-280 μg/ml of iron). Static incubations were performed, comparing insulin response to basal (2.8 mM) or high glucose stimulation (16.7 mM), with or without cAMP stimulation. Insulin and Perl's (assessment of iron content) staining were performed. Electronic microscopy analysis was performed. Labeled islets were used for in vitro or in vivo imaging in MRI 1.5T. Liver section after organ removal was performed in the same plane as MRI imaging to get a correlation between histology and radiology. Postlabeling islet viability (80 ± 10%) and function (in vitro static incubation and in vivo engraftment of human islets in nude mice) were similar in both groups. Iron uptake assessed by electron microscopy showed iron inclusions within the islets with ferucarbotran, but not with ferumoxide. MRI imaging (1.5T) of phantoms and of human islets transplanted in rats, demonstrated a strong signal with ferucarbotran, but only a weak signal with ferumoxide. Signal persisted for >8 weeks in the absence of rejection. An excellent correlation was observed between radiologic images and histology. The hepatic clearance of intraportally injected ferucarbotran was faster than that of ferumoxide, generating less background. A rapid signal decrease was observed in rejecting xenogeneic islets. According to the present data, ferucarbotran is the most appropriate of available clinical grade SPIOs for human islet imaging.

Binding characteristics of 9-fluoropropyl-(+)-dihydrotetrabenzazine (AV-133) to the vesicular monoamine transporter type 2 in rats

The vesicular monoamine transporter type 2 (VMAT2) is highly expressed in pancreatic beta-cells and thus has been proposed to be a potential target for measuring beta-cell mass (BCM) by molecular imaging. C-11- and F-18-labeled tetrabenazine derivatives targeting VMAT2 have shown some promising results as potential biomarkers for BCM. In the present study, we examined the binding characteristics of 9-fluoropropyl-(+)-dihydrotetrabenzazine ([(18)F]AV-133), a potential PET tracer for BCM imaging, in rat pancreas and rat brain. Pancreatic exocrine cells and pancreatic islet cells were isolated and purified from Sprague-Dawley rats. Membrane homogenates, prepared from both pancreatic exocrine and islet cells as well as from brain striatum and hypothalamus regions, were used for in vitro binding studies. In vitro and ex vivo autoradiography studies with [(18)F]AV-133 were performed on rat brain and rat pancreas sections. Immunohistochemistry studies were performed to confirm the distribution of VMAT2 on islet beta-cells. Excellent binding affinities of [(18)F]AV-133 were observed in rat striatum and hypothalamus homogenates with K(d) values of 0.19 and 0.25 nM, respectively. In contrast to single-site binding observed in rat striatum homogenates, rat islet cell homogenates showed two saturable binding sites (site A: K(d)=6.76 nM, B(max)=60 fmol/mg protein; site B: K(d)=241 nM, B(max)=1500 fmol/mg protein). Rat exocrine pancreas homogenates showed only a single low-affinity binding site (K(d)=209 nM), which was similar to site B in islet cells. In vitro autoradiography of [(18)F]AV-133 using frozen sections of rat pancreas showed specific labeling of islets, as evidenced by co-localization with anti-insulin antibody. Ex vivo VMAT2 pancreatic autoradiography in the rat, however, was not successful, in contrast to the excellent ex vivo autoradiography of VMAT2 binding sites in the brain. In vivo/ex vivo islet labeling may be complicated by the presence of the low-affinity/high-capacity site B binding in rat pancreas. [(18)F]AV-133 is an excellent imaging agent for mapping VMAT2 sites in rat brain and specifically binds rat islet cells in vitro and postmortem. Additional optimization may be required to achieve ex vivo islet beta-cell labeling in rats.

Glucose Regulates Steady-state Levels of PDX1 via the Reciprocal Actions of GSK3 and AKT Kinases

The pancreatic beta cell is sensitive to even small changes in PDX1 protein levels; consequently, Pdx1 haploinsufficiency can inhibit beta cell growth and decrease insulin biosynthesis and gene expression, leading to compromised glucose-stimulated insulin secretion. Using metabolic labeling of primary islets and a cultured beta cell line, we show that glucose levels modulate PDX1 protein phosphorylation at a novel C-terminal GSK3 consensus that maps to serines 268 and 272. A decrease in glucose levels triggers increased turnover of the PDX1 protein in a GSK3-dependent manner, such that PDX1 phosphomutants are refractory to the destabilizing effect of low glucose. Glucose-stimulated activation of AKT and inhibition of GSK3 decrease PDX1 phosphorylation and delay degradation. Furthermore, direct pharmacologic inhibition of AKT destabilizes, and inhibition of GSK3 increases PDX1 protein stability. These studies define a novel functional role for the PDX1 C terminus in mediating the effects of glucose and demonstrate that glucose modulates PDX1 stability via the AKT-GSK3 axis.

Prolactin Receptors Are Critical to the Adaptation of Islets to Pregnancy

During pregnancy there is an enhanced need for insulin to accommodate the growing fetal compartment as well as the substantial increase in insulin resistance. Failure of the islets to adapt to this increased demand for insulin leads to gestational diabetes. The report by Huang et al. (1), using an in vivo model of prolactin (PRL) receptor deficiency, provides an important validation of the hypothesis that -cell PRL receptors are central to mechanisms whereby islets adapt to pregnancy (Fig. 1). This study showed not only that PRL receptor deficiency leads to gestational diabetes, but the genetic phenotype of the mother influences the outcome of islet development in the fetus. That islets undergo changes during pregnancy was observed as early as 1930 (2), when Cramer concluded that islets are a very plastic tissue that undergo considerable changes, especially during pregnancy. The changes he observed included increased secretory activity, islet growth, and neogenesis. Direct evidence for functional changes in islets did not occur until the development of a sensitive insulin assay in the 1960s, when it was reported that there was a progressive increase in both fasting and glucosestimulated insulin secretion throughout the course of human pregnancy (3). This and subsequent research led to the characterization of pregnancy as a condition of elevated serum insulin levels, slightly lower blood glucose levels, and peripheral insulin resistance. The short-term regulation of insulin secretion is achieved by elevating blood glucose. However, if this were the only mechanism available for increasing insulin secretion during pregnancy, there would be a need for persistent hyperglycemia, a condition detrimental both to the mother and the developing fetus. Thus, when there is an increased need for insulin over a prolonged period of time, such as occurs in pregnancy, islets must undergo adaptive changes. The outcome of the up-regulation must be such that there is enhanced insulin secretion at normal glucose levels. There are three basic mechanisms whereby one can increase insulin secretion at normal glucose concentrations: increase the islet -cell mass, increase the sensitivity of insulin secretion in response to glucose, or both. Evidence that there is an increase islet/ -cell mass comes from a number of studies (4–7). These studies indicate that there is an approximate 2-fold increase in islet mass. DNA content per islet also indicates an increase in islet mass, and both morphometric and DNA to protein ratio methods indicate -cell hypertrophy as well as -cell hyperplasia (8– 12). Evidence for increased -cell mitosis comes from tritiated thymidine and bromodeoxyuridine labeling of islets during pregnancy (4, 13, 14). Overall, these reports indicate that islet mass doubles, and the increase is a consequence of new -cell formation as well as an increase in -cell size. There is less information on whether islet neogenesis occurs during pregnancy. One report failed to detect evidence for islet neogenesis during pregnancy but did show that another condition of persistent hyperlactogenemia may result in islet neogenesis (15). There is also evidence for an increase in glucose-sensitive insulin secretion. During rodent pregnancy, fasting serum insulin levels are increased, and glucose levels are decreased (8, 16, 17), similar to that observed in human pregnancy. Green and Taylor (9) showed a leftward shift of the glucose-stimulated insulin secretion response curve in islets isolated from pregnant rats. In a similar study, we used perfused pancreas preparations to examine insulin secretion throughout rat pregnancy. A leftward shift in glucose-responsive insulin secretion as well as above-threshold insulin release was first noted on d 10 and peaked by d 15 (4). The threshold for glucose-stimulated insulin secretion decreased from 5.7–3.3 mM by d 15 pregnancy. The lowering of the threshold for glucose-stimulated insulin secretion is a key feature of islets as they adapt to pregnancy. It is through this maneuver that a large increase in insulin secretion can be achieved at fasting blood glucose levels, as is seen during pregnancy. The most important changes in islet adaptation to pregnancy are enhanced insulin secretion and enhanced -cell mass. Candidate hormones must be shown to induce these changes. Although a variety of hormones increase during pregnancy, only PRL and placental lactogen, which acts through PRL receptors, are capable of inducing the changes that occur in islets during

Multifunctional Magnetic Nanocarriers for Image-Tagged SiRNA Delivery to Intact Pancreatic Islets

With the ultimate hope of finding a cure for diabetes, researches are looking into altering the genetic profile of the beta cell as a way to manage metabolic dysregulation. One of the most powerful new approaches for the directed regulation of gene expression uses the phenomenon of RNA interference. Here, we establish the feasibility of a novel technology centered around multifunctional magnetic nanocarriers, which concurrently deliver siRNA to intact pancreatic islets and can be detected by magnetic resonance and optical imaging. In the proof-of-principle studies described here, we demonstrate that, after in vitro incubation, magnetic nanoparticles carrying siRNA designed to target the model gene for enhanced green fluorescent protein are efficiently taken up by murine pancreatic islets, derived from egfp transgenic animals. This uptake can be visualized by magnetic resonance imaging and near-infrared fluorescence optical imaging and results in suppression of the target gene. These results illustrate the value of our approach in overcoming the challenges associated with genetic modification of intact pancreatic islets in a clinically acceptable manner. Furthermore, an added advantage of our technology derives from the combined capability of our magnetic nanoparticles for siRNA delivery and magnetic labeling of pancreatic islets.

Labeling of Pancreatic Islets With Iron Oxide Nanoparticles for In Vivo Detection With Magnetic Resonance

In vitro labeling of pancreatic islets with iron nanoparticles enables their direct posttransplant visualization by magnetic resonance; however, there is still a discrepancy in the fate of iron nanoparticles. This study was performed to detail the labeling process, consequently to improve the labeling efficacy and to confirm safety for islet cells. The islets were visible on T2*-weighted magnetic resonance images as hypointense spots immediately after 1-hr cultivation. Although at this time already the sufficient superparamagnetic effect was achieved, most of the particles were deposed in islet macrophages and only later were they found in endosomes of endocrine islet cells. The iron content depended on length of culture period. The labeled islets showed an intact ultrastructure, responded normally to glucose stimulation in vitro, and were able to treat experimental diabetes. For purpose of subsequent magnetic resonance imaging, a 24-hr culture with ferucarbotran leads to sufficient labeling with no apparent adverse effect on beta cell morphology or function.

Positron-Emission Tomography Imaging of Early Events after Transplantation of Islets of Langerhans

The aim of our study was to assess cell trafficking and early events after intraportal islet transplantation. Sprague-Dawley rat islets were incubated for various times, with various concentrations of 2-[F]fluoro-2deoxy-D-glucose (FDG), and in presence of various glucose concentrations. FDG-labeled syngeneic islets or FDG alone were injected in rats. Radioactivity was measured in the liver and in various organs by positron-emission tomography for 6 hours. FDG uptake increased with incubation time or FDG concentration and decreased in presence of glucose. In vivo, all islets implanted in the liver, with an uptake 4.4 times higher than controls (44.2% vs. 10.1%, P=0.02). Radioactivity in the liver decreased at the same rate after injection of labeled-islets and FDG alone. Ex vivo labeling of islets and imaging of posttransplant early events were feasible. Islets engrafted exclusively in the liver. No islet loss could be demonstrated 6 hours after transplantation.

Mapping protein expression in mouse pancreatic islets by immunolabeling and electron energy loss spectrum-imaging.

A combination of immuno-electron microscopy and electron energy-loss spectrum-imaging was used to map the distributions of endocrine polypeptide hormones and proteins in mouse pancreatic islet of Langerhans. Tissue was analyzed from control animals and from mice that were heterozygous for the Anx7 gene, which defines a Ca2+/GTP-dependent membrane fusion and ion channel protein. The heterozygous Anx7 (+/-) mouse displays defects in IP3 receptor mediated Ca2+ signaling and insulin secretion. Therefore, information was obtained about the distributions of the hormones insulin and glucagon, as well as the proteins ANX7 and the IP3 receptor. Insulin secretion appears to be defective in the mutants. It was found from immunolabeling experiments that expression of the IP3 receptor is reduced in mutant islets compared to control islets. Subcellular distributions of sulfur and nitrogen obtained by electron energy-loss spectrum-imaging showed that the insulin concentrations of beta granules were essentially the same in control and mutant islets. By contrast, immunogold labeling of mutant islets shows more insulin immunoreactivity in the beta granules. It follows that insulin may be packaged differently in mutant islets, making antigenic determinants more available to the labeling antibody. The increased rate of insulin secretion in the hyperplastic mutant islets can be explained by compensatory increases in islet size, rather than by an increased insulin concentration in the beta cells. The results indicate that reduced ANX7 expression leads to defects in the IP3 receptor expression in the endocrine cells of the mutant mouse. Increased size of the islet or of adrenal medulla may be a compensatory mechanism for secretion defect by individual endocrine cells. Defects in IP3 receptor expression, and documented consequences of a Ca2+ signaling defect, lead to other changes in organelles such as the mitochondrial number in islet beta-cells. The effects and consequences of reduced ANX7 expression on mitochondria are evident in ultrastructural observations.

Unspecific Labeling of Pancreatic Islets by Antisera Against Fibroblast Growth Factors and Their Receptors

Six distinct fibroblast growth factors (FGFs) have been detected in pancreatic islets by immunohistochemistry (IHC) using commercially available antisera. We show here that these antisera are useful for Western blotting but that only two are suited for IHC. By Western blotting, these antisera detect recombinant FGFs. Detection can be eliminated by preabsorption with immunizing peptide but not with irrelevant peptide. By IHC we find specific labeling of islets with anti-FGF1 and anti-FGF2 antisera. Labeling can be abolished by preabsorption with the immunizing peptides. In contrast, prominent staining of islets by anti-FGF4, -FGF5, -FGF7, and -FGF10 antisera is unspecific because the staining cannot be competed by preabsorption with the immunizing peptides.