The role of infiltrating macrophages in islet destruction and regrowth in a transgenic model

Interleukin-21 is required for the development of type 1 diabetes in NOD mice

OBJECTIVE

Interleukin (IL)-21 is a type 1 cytokine that has been implicated in the pathogenesis of type 1 diabetes via the unique biology of the nonobese diabetic (NOD) mouse strain. The aim of this study was to investigate a causal role for IL-21 in type 1 diabetes.

RESEARCH DESIGN AND METHODS

We generated IL-21R-deficient NOD mice and C57Bl/6 mice expressing IL-21 in pancreatic beta-cells, allowing the determination of the role of insufficient and excessive IL-21 signaling in type 1 diabetes.

RESULTS

Deficiency in IL-21R expression renders NOD mice resistant to insulitis, production of insulin autoantibodies, and onset of type 1 diabetes. The lymphoid compartment in IL-21R-/- NOD is normal and does not contain an increased regulatory T-cell fraction or diminished effector cytokine responses. However, we observed a clear defect in autoreactive effector T-cells in IL-21R-/- NOD by transfer experiments. Conversely, overexpression of IL-21 in pancreatic beta-cells induced inflammatory cytokine and chemokines, including IL-17A, IL17F, IFN-gamma, monocyte chemoattractant protein (MCP)-1, MCP-2, and interferon-inducible protein-10 in the pancreas. The ensuing leukocytic infiltration in the islets resulted in destruction of beta-cells and spontaneous type 1 diabetes in the normally diabetes-resistant C57Bl/6 and NOD x C57Bl/6 backgrounds.

CONCLUSIONS

This work provides demonstration of the essential prodiabetogenic activities of IL-21 on diverse genetic backgrounds (NOD and C57BL/6) and indicates that IL-21 blockade could be a promising strategy for interventions in human type 1 diabetes.

The stromal cell-derived factor-1alpha/CXCR4 ligand-receptor axis is critical for progenitor survival and migration in the pancreas

The SDF-1α/CXCR4 ligand/chemokine receptor pair is required for appropriate patterning during ontogeny and stimulates the growth and differentiation of critical cell types. Here, we demonstrate SDF-1α and CXCR4 expression in fetal pancreas. We have found that SDF-1α and its receptor CXCR4 are expressed in islets, also CXCR4 is expressed in and around the proliferating duct epithelium of the regenerating pancreas of the interferon (IFN) γ–nonobese diabetic mouse. We show that SDF-1α stimulates the phosphorylation of Akt, mitogen-activated protein kinase, and Src in pancreatic duct cells. Furthermore, migration assays indicate a stimulatory effect of SDF-1α on ductal cell migration. Importantly, blocking the SDF-1α/CXCR4 axis in IFNγ-nonobese diabetic mice resulted in diminished proliferation and increased apoptosis in the pancreatic ductal cells. Together, these data indicate that the SDF-1α–CXCR4 ligand receptor axis is an obligatory component in the maintenance of duct cell survival, proliferation, and migration during pancreatic regeneration.

Sex steroids influence pancreatic islet hypertrophy and subsequent autoimmune infiltration in nonobese diabetic (NOD) and NODscid mice

Female nonobese diabetic (NOD) mice more frequently develop autoimmune diabetes than NOD males. Orchidectomy of the latter aggravates insulitis and diabetes. Because clear differences in immune function have not been observed between prediabetic females and males, before or after castration, we hypothesized that sex-related differences in diabetes incidence are related to target organ-specific actions of sex steroids. Previously, we showed that prediabetic NOD females develop hyperinsulinemia and subsequently mega-islets. Infiltration of the first inflammatory leukocytes is predominantly associated with these mega-islets. Here, we determined the relationship between sex hormones, mega-islet formation, and infiltrating cells in NOD and nonobese diabetic/severe combined immune-deficient (NODscid) mice. Mega-islet formation was reduced in NOD males compared with NOD females, and orchidectomy increased it, indicating a relationship between androgen levels and mega-islet formation. Moreover, enhanced mega-islet formation in castrated NOD males was associated with increased numbers of infiltrating leukocytes. Castrated NODscid males also exhibited increased mega-islet formation and dendritic cell infiltration, indicating that lymphocytes are not required for castration-induced effects. In conclusion, we show that androgens influence pancreatic islets and autoimmune infiltration in NOD and NODscid mice. This suggests that the gender difference in diabetes incidence in NOD mice is related to target organ-specific androgen effects.

Cytokines that regulate autoimmune responses

Autoimmune responses are controlled by complex regulatory circuits. Previous work has revealed that factors controlling autoimmunity can act both as potentiating and inhibitory agents, depending upon the site and timing of exposure. Recent advances in this complex field have at least partially uncovered the mechanism whereby these regulatory molecules participate in autoimmune processes. IL-12 production in the absence of infection may predispose to autoimmunity. IL-4 and transforming growth factor beta may suppress autoreactive T cells. Proinflammatory cytokines may ameliorate autoimmunity, dependent on the timing and level of production. In many cases, cytokines may act via antigen-presenting cells.

Autoimmune diabetes: the involvement of benign and malignant autoimmunity

Our studies in the NOD mouse demonstrate that the autoimmune response can be either benign or malignant. In the former case </=10% of the islets in the pancreas are damaged. The latter is associated with massive islet damage which leads to the development of clinical disease within 2-3 weeks. From the time of weaning up to 70-80 days of age all male and female NOD mice are in a benign state of autoimmunity. After that time animals move, in an unpredictable way, into the malignant state of autoimmunity. As a result, animals >/=100 days of age make up a heterogeneous group where some are in a benign state of autoimmunity, which can continue for a further |LX200 days, others are in a state of transition to the malignant state of autoimmunity, and others have a fully malignant autoimmune response and are diabetic. This heterogeneity developing within members of the population, in terms of pancreatic damage, is not consistent with the proposal that autoimmune islet damage in the NOD mouse is a slow, progressive process affecting all disease prone members of the population. In the NOD mouse, massive islet destruction is a late event in the autoimmune process and only develops following the conversion of the autoimmune response from the benign to the malignant state.

Antigen-presenting dendritic cells as regulators of the growth of thyrocytes: a role of interleukin-1beta and interleukin-6

An accumulation of antigen-presenting dendritic cells (DC) in the thyroid gland, followed by thyroid autoimmune reactivity, occurs in normal Wistar rats during iodine deficiency, and spontaneously in diabetic-prone Biobreeding rats. This intrathyroidal DC accumulation coincides with an enhanced growth rate and metabolism of the thyrocytes, suggesting that both phenomena are related. Because DC are known to regulate the hormone synthesis and growth in other endocrine systems (i.e. the pituitary, the ovary, and the testis), we tested the hypothesis that DC, known for their superb accessory cell function in T cell stimulation, act as regulators of thyrocyte proliferation (and hormone secretion). We investigated the effect of (Nycodenz density gradient) purified splenic DC from Wistar rats on the growth rate of and thyroid hormone secretion by Wistar thyroid follicles (collagenase dispersion) in culture. Various numbers of DC and follicles were cocultured during 24 h. The proliferative capacity of thyrocytes was measured by adding tritiated thymidine (3H-TdR) and bromodeoxyuridine, the hormone secretion into the culture fluid was measured by using a conventional T3 RIA. Furthermore, antibodies directed against interleukin-1beta (IL-1beta), IL-6, and tumor necrosis factor-alpha (TNF-alpha) were added to these cocultures to determine the role of these cytokines in a possible DC regulation of thyrocyte growth. Cocultures were also carried out in the presence of antimajor histocompatibility complex-class I (MHC I), anti-MHC II, antiintercellular adhesion molecule-1 (ICAM-1), and antilymphocyte function-associated antigen-1alpha (LFA-1alpha) antibodies to possibly interfere with DC-thyrocyte interactions. The addition of DC to thyroid follicles clearly inhibited their 3H-TdR uptake, particularly at a 10:1 ratio, in comparison to follicle cultures alone, both under basal conditions and after TSH stimulation (75 +/- 7% and 49 +/- 11% reduction, respectively, n = 4). The follicle T3 secretion (after TSH stimulation) was also suppressed by DC in this system, but to a lesser extent (at best at an 1:1 ratio, 25 +/- 7% reduction, n = 4). The DC-induced inhibition of thyroid follicle growth was totally abrogated after addition of anti-IL-1beta antibodies; anti-IL-6 only had effect on the DC inhibition of non-TSH-stimulated thyrocytes, whereas anti-TNF-alpha demonstrated no effect at all. The antibodies to MHC and to adhesion molecules had also no effect on this DC-induced growth inhibition. The effect of the different anti-cytokine and anti-adhesion antibodies on the T3 secretion from thyroid follicles was not investigated. The clear inhibition of thyrocyte growth by splenic DC (classical antigen-presenting cells) again demonstrates the regulatory role of DC in endocrine systems. Proinflammatory cytokines such as IL-1beta and IL-6 are important mediators in this regulation. The here shown dual role of DC represents a link between the immune and endocrine system, which may form the gateway to the understanding of the initiation of thyroid autoimmune reactions and the thyroid autoimmune phenomena seen in iodine deficiency.