Coxsackie B4 virus induces short-term changes in the metabolic functions of mouse pancreatic islets in vitro

Prevention or acceleration of type 1 diabetes by viruses

Type 1 diabetes is an autoimmune disease characterized by the destruction of insulin-producing pancreatic β-cells. Even though extensive scientific research has yielded important insights into the immune mechanisms involved in pancreatic β-cell destruction, little is known about the events that trigger the autoimmune process. Recent epidemiological and experimental data suggest that environmental factors are involved in this process. In this review, we discuss the role of viruses as an environmental factor on the development of type 1 diabetes, and the immune mechanisms by which they can trigger or protect against this pathology.

Immunology in the clinic review series; focus on type 1 diabetes and viruses: the innate immune response to enteroviruses and its possible role in regulating type 1 diabetes

Type 1 diabetes (T1D) is an autoimmune disease arising as a consequence of a misdirected T cell response to the pancreatic beta cell. In recent years, there has been a growing interest in the innate immune system as a regulator of disease development. Genome-wide association studies have identified diabetes-associated polymorphisms in genes encoding proteins with functions related to the innate immune response. Moreover, enteroviruses, known to activate a strong innate immune response, have been implicated in the disease pathogenesis. In this review, we discuss the innate immune response elicited by enteroviruses and how this response may regulate T1D development.

Group B coxsackievirus diabetogenic phenotype correlates with replication efficiency

Group B coxsackieviruses can initiate rapid onset type 1 diabetes (T1D) in old nonobese diabetic (NOD) mice. Inoculating high doses of poorly pathogenic CVB3/GA per mouse initiated rapid onset T1D. Viral protein was detectable in islets shortly after inoculation in association with beta cells as well as other primary islet cell types. The virulent strain CVB3/28 replicated to higher titers more rapidly than CVB3/GA in the pancreas and in established beta cell cultures. Exchange of 5'-nontranslated regions between the two CVB3 strains demonstrated a variable impact on replication in beta cell cultures and suppression of in vivo replication for both strains. While any CVB strain may be able to induce T1D in prediabetic NOD mice, T1D onset is linked both to the viral replication rate and infectious dose.

RNase L and double-stranded RNA-dependent protein kinase exert complementary roles in islet cell defense during coxsackievirus infection

Coxsackievirus (CV) is an important human pathogen that has been linked to the development of autoimmunity. An intact pancreatic beta cell IFN response is critical for islet cell survival and protection from type 1 diabetes following CV infection. In this study, we show that IFNs trigger an antiviral state in beta cells by inducing the expression of proteins involved in intracellular antiviral defense. Specifically, we demonstrate that 2',5'-oligoadenylate synthetases (2-5AS), RNase L, and dsRNA-dependent protein kinase (PKR) are expressed by pancreatic islet cells and that IFNs (IFN-alpha and IFN-gamma) increase the expression of 2-5AS and PKR, but not RNase L. Moreover, our in vitro studies uncovered that these pathways play important roles in providing unique and complementary antiviral activities that critically regulate the outcome of CV infection. The 2-5AS/RNase L pathway was critical for IFN-alpha-mediated islet cell resistance from CV serotype B4 (CVB4) infection and replication, whereas an intact PKR pathway was required for efficient IFN-gamma-mediated repression of CVB4 infection and replication. Finally, we show that the 2-5AS/RNase L and the PKR pathways play important roles for host survival during a challenge with CVB4. In conclusion, this study has dissected the pathways used by distinct antiviral signals and linked their expression to defense against CVB4.

Coxsackievirus B3 infection and type 1 diabetes development in NOD mice: insulitis determines susceptibility of pancreatic islets to virus infection

Group B coxsackieviruses (CVB) are believed to trigger some cases of human type 1 diabetes (T1D), although the mechanism by which this may occur has not been shown. We demonstrated previously that inoculation of young nonobese diabetic (NOD) mice with any of several different CVB strains reduced T1D incidence. We also observed no evidence of CVB replication within islets of young NOD mice, suggesting no role for CVB in T1D induction in the NOD mouse model. The failure to observe CVB replication within islets of young NOD mice has been proposed to be due to interferon expression by insulin-producing beta cells or lack of expression of the CVB receptor CAR. We found that CAR protein is detectable within islets of young and older NOD mice and that a CVB3 strain, which expresses murine IL-4, can replicate in islets. Mice inoculated with the IL-4 expressing CVB3 chimeric strain were better protected from T1D onset than were mock-infected control mice despite intraislet viral replication. Having demonstrated that CVB can replicate in healthy islets of young NOD mice when the intraislet environment is suitably altered, we asked whether islets in old prediabetic mice were resistant to CVB infection. Unlike young mice in which insulitis is not yet apparent, older NOD mice demonstrate severe insulitis in all islets. Inoculating older prediabetic mice with different pathogenic CVB strains caused accelerated T1D onset relative to control mice, a phenomenon that was preceded by detection of virus within islets. Together, the results suggest a model for resolving conflicting data regarding the role of CVB in human T1D etiology.

Diabetogenic potential of human pathogens uncovered in experimentally permissive beta-cells

Pancreatic beta-cell antiviral defense plays a critical role in protection from coxsackievirus B4 (CVB4)-induced diabetes. In the present study, we tested the hypothesis that interferon (IFN)-induced antiviral defense determines beta-cell survival after infection by the human pathogen CVB3, cytomegalovirus (CMV), and lymphocytic choriomeningitis virus (LCMV). We demonstrated that mice harboring beta-cells that do not respond to IFN because of the expression of the suppressor of cytokine signaling-1 (SOCS-1) succumb to an acute form of type 1 diabetes after infection with CVB3. Interestingly, the tropism of the virus was altered in SOCS-1 transgenic (Tg) mice, and CVB3 was detected in islet cells of SOCS-1-Tg mice before beta-cell loss and the onset of diabetes. Furthermore, insulitis was increased in SOCS-1-Tg mice after infection with murine CMV, and a minority of the mice developed overt diabetes. However, infection with LCMV failed to cause beta-cell destruction in SOCS-1 Tg mice. These findings suggest that CVB3 can cause diabetes in a host lacking adequate beta-cell antiviral defense, and that incomplete target cell antiviral defense may enhance susceptibility to diabetes triggered by CMV. In conclusion, suppressed beta-cell antiviral defense reveals the diabetogenic potential of two pathogens previously linked to the onset of type 1 diabetes in humans.

Target cell defense prevents the development of diabetes after viral infection

The mechanisms that regulate susceptibility to virus-induced autoimmunity remain undefined. We establish here a fundamental link between the responsiveness of target pancreatic beta cells to interferons (IFNs) and prevention of coxsackievirus B4 (CVB4)-induced diabetes. We found that an intact beta cell response to IFNs was critical in preventing disease in infected hosts. The antiviral defense, raised by beta cells in response to IFNs, resulted in a reduced permissiveness to infection and subsequent natural killer (NK) cell-dependent death. These results show that beta cell defenses are critical for beta cell survival during CVB4 infection and suggest an important role for IFNs in preserving NK cell tolerance to beta cells during viral infection. Thus, alterations in target cell defenses can critically influence susceptibility to disease.

Enterovirus infections and type 1 diabetes

Type 1 (insulin-dependent) diabetes is a typical organ-specific autoimmune disease where insulin-producing beta cells are destroyed by immune mediated mechanisms. The risk of the disease is modulated by genetic factors, mainly genes coding for human leukocyte antigens (HLA), but environmental factors are needed to trigger the process in genetically susceptible individuals. Possible viral triggers of the disease have been sought for years but their identification has been very difficult. Recently, considerable progress has been made by employing new research methods which have supported the idea that the group of enteroviruses may be particularly important in the pathogenesis. An association between enterovirus infections and type 1 diabetes was first reported 30 years ago and since then evaluated in several studies. Recent molecular studies have considerably strengthened this hypothesis by showing that enterovirus genome is present in the blood of diabetic patients. In addition, the first prospective studies have suggested that enterovirus infections may initiate the beta-cell damaging process several years before clinical diabetes is diagnosed. Ecological studies have also indicated similarities in the epidemiology of type 1 diabetes and poliomyelitis - a well-known enterovirus disease. Experimental models, like enterovirus-infected mice or in vitro-cultured beta cells, have provided important information about possible mechanisms, but still it is not known how beta cells are destroyed in human beings. The ongoing prospective studies will answer many open questions, and should the association still hold true, intervention trials will be needed to confirm causality. Even if enterovirus infections were not associated with all diabetes cases but rather with a subgroup of them, this would offer attractive possibilities to prevent the disease or part of it, for example, by an enterovirus vaccine.

A critical role for inducible nitric oxide synthase in host survival following coxsackievirus B4 infection

Coxsackieviral infections have been linked etiologically to multiple diseases. The serotype CB4 is associated with acute pancreatitis and autoimmune type 1 diabetes. To delineate the mechanisms of host survival after an acute infection with CB4 (strain E2), we have investigated the role of nitric oxide (NO), generated by the inducible form of nitric oxide synthase (NOS2), in viral clearance and pancreatic beta-cell maintenance. Mice deficient in NOS2 (NOS2-/- mice) and their wild-type (wt) counterparts were injected with CB4, after which both groups developed severe pancreatitis, hepatitis, and hypoglycemia within 3 days. Within 4 to 7 days postinfection (p.i.), most of the NOS2-/- mice died and at a strikingly higher mortality rate than wt mice. Histological examination of pancreata from both infected NOS2-/- and infected wt mice revealed early and complete destruction of the pancreatic acinar tissue, but intact, insulin-stained islets. When examined up to 8 weeks p.i., neither surviving NOS2-/-mice nor surviving wt mice developed hyperglycemia. However, the clearance of infectious CB4 was different between the mice. The spleens of NOS2-/- survivors were cleared of infectious virus with kinetics similar to that of wt mice, but the livers, pancreata, kidneys, and hearts of the NOS2-/- groups cleared virus more slowly than those of the wt group. This delayed clearance was particularly prominent in the livers of infected NOS2-/- mice, which also showed prolonged histopathological features of viral hepatitis. Taken together, this outcome suggests that NOS2 (and NO) is not required for the prevention of pancreatic beta-cell depletion after CB4 infection. Instead the critical actions of NOS2 apparently occur early in the host immune response, allowing mice to survive and clear virus. Moreover, the data support the existence of an organ-specific dependency on NO for a rapid clearance of CB4.

Group B coxsackievirus myocarditis and pancreatitis: connection between viral virulence phenotypes in mice

The group B coxsackieviruses (CVB) induce experimental pancreatitis and myocarditis in mice and are established agents of human myocarditis, especially in children. We tested the hypothesis that the development of CVB-induced myocarditis is linked to CVB-induced pancreatitis by studying the replication of different CVB strains in mice. Eight of nine genotypically different type 3 CVB (CVB3) strains induced acute pancreatitis in mice; of these, three viruses also induced acute myocarditis. One CVB3 strain was avirulent for both organs. Myocarditis was not observed in the absence of pancreatitis. The results obtained by inoculation of mice with strains of other CVB serotypes were consistent with these data. Infectious virus titers were measured in serum, pancreas, and heart as a function of time after inoculation of mice with three CVB3 strains. Each strain was representative of one of the three viral virulence phenotypes: avirulent, pancreovirulent only, and cardiovirulent. All strains replicated well and persisted in the pancreas through 8 days post-inoculation, but the cardiovirulent CVB3 strain tended to replicate to higher titer earlier and persist longer in sera, pancreatic, and cardiac tissues than the noncardiovirulent strains. Replication of the CVB3 strains were studied in two human pancreatic tumor lines and in primary human endothelial cell cultures derived from cardiac artery. Cardiovirulent strains, both individually and as a group, tended to replicate to titers as high as, or higher than, noncardiovirulent strains did in cell culture. The data are consistent with the possibility of an etiologic link between CVB-induced pancreatic and heart disease.

Impaired Ca2+ response to glucose in mouse beta-cells infected with coxsackie B or Echo virus

Five strains of Coxsackie B4 virus and one of Echo 11 virus were tested with regard to their ability to replicate in pancreatic mouse beta-cells and interfere with the alterations of the cytoplasmic Ca2+ concentration ([Ca2+]i) induced by glucose. All strains except one both multiplied and caused cytopathic effect. In a control group 68% of the beta-cells responded to 11 mM glucose with large amplitude oscillations of [Ca2+]i. After inoculation with the infectious strains these oscillations appeared in only 5% of the beta-cells, whereas the non-infectious strain did not modify the glucose effect on [Ca2+]i. Despite the virus interference with the glucose response, [Ca2+]i was increased after depolarization with excessive extracellular K+ and the oscillations were induced in most beta-cells when glucose was combined with the insulin-releasing sulfonylurea tolbutamide.

Complete nucleotide sequence of a beta-cell tropic variant of coxsackievirus B4

A mouse pancreas-adapted variant of coxsackievirus B4 (P-CB4) has been shown to replicate in, and cause an excessive release of insulin from, pancreatic beta cells cultured in vitro. The prototype CB4 strain (JVB Benschoten), from which the adapted variant was derived, although able to replicate in cultured islets does not cause a similar release of insulin from the beta cells. The pancreas-adapted virus has also been shown to cause host cell protein synthesis shut-off in beta cells and to inhibit (pro)insulin biosynthesis. These metabolic changes occur in the absence of cytolytic damage [Szopa et al.: Bioscience Reports 5:63-69, 1985 and Cell Biochemistry and Function 4:181-187, 1986]. To investigate the genetic basis for this beta cell tropism, the complete nucleotide sequence of P-CB4 has been determined and compared to that of the previously published sequence of the prototype CB4 strain (JVB Benschoten) [Jenkins et al.: Journal of General Virology 68:1835-1848, 1987]. Twenty-five nucleotide sequence differences were observed. Of these, six occur in the 5' noncoding region of the genome and 19 in the coding region (resulting in seven amino acid changes). The possible significance of these changes in relation to the beta cell tropism of the pancreas-adapted virus is discussed.

Diabetes mellitus due to viruses--some recent developments

Many different viruses belonging to several genera have the potential to damage beta cells. The mechanisms they employ are varied, and infection may result in either a direct destruction of islets and rapid insulin deficiency, or in a more gradual loss of functioning islets with the onset of diabetes many years later. Several case histories involving extensive cytolysis of beta cells can be directly linked to viral infection, whilst an example of diabetes occurring many years after viral infection is found in individuals who had a congenital infection with rubella virus. Here, the virus induces an autoimmune reaction against beta cells. Autoimmune phenomena have also been observed in islets following infections with viruses other than rubella, and thus activation of autoimmune mechanisms leading to beta-cell destruction may be a relatively frequent occurrence. Recent evidence shows that picornaviruses are not exclusively lytic, and can induce more subtle, long-term changes in beta cells, which may be important in the aetiology of diabetes. The exact mechanisms involved are not known, but it is clear that several viruses can directly inhibit insulin synthesis and induce the expression of other proteins such as interferons, and the HLA antigens. Strain differences in viruses are important since not all variants are tropic for the beta cells. Several laboratories are in the process of identifying the genetic determinants of tropism and diabetogenicity, especially amongst the Coxsackie B (CB) virus group. The sequence of one such diabetogenic CB4 strain virus has been determined.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of a diabetogenic strain of encephalomyocarditis (EMC) virus on protein synthesis in mouse islets of Langerhans

The effects of a diabetogenic strain of encephalomyocarditis (EMC) virus on total protein and insulin biosynthesis in mouse islets of Langerhans have been studied in tissue culture. In dispersed mouse islets, the rates of protein biosynthesis were assessed by measuring the incorporation of [3H]leucine into proteins. In infected dispersed islets incubated in 20 mM-glucose, both insulin and total protein biosynthesis were decreased at 6 h; only insulin biosynthesis was significantly decreased at 3 h. In whole islets, EMC virus brought about a decrease in glucose-stimulated protein and insulin biosynthesis as early as 2 h after infection without concomitant effects on insulin release. This inhibition of protein biosynthesis was still apparent at 20 h post-infection, at which time insulin release was found to be markedly elevated, and the islet insulin content was moderately decreased. At 44 h post-infection, glucose-induced insulin biosynthesis was preferentially inhibited. Infected islets at this later time point also displayed elevated levels of insulin release, and a marked loss of islet insulin content. When insulin mRNA and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) mRNA levels were assessed by dot-blot hybridization using appropriate cDNA probes, levels of insulin mRNA were shown to decrease steadily during the first 20 h of infection, in contrast with the levels of GAPDH mRNA. At 44 h post-infection, both types of mRNA were markedly decreased. It is suggested that there is an initial early 'shut-off' of protein synthesis without other detectable changes in islet function. This is followed by a phase where both insulin mRNA levels and insulin synthesis are dramatically decreased.

Coxsackie B4 viruses with the potential to damage beta cells of the islets are present in clinical isolates

Infections with Coxsackie viruses (especially Coxsackie B4) are thought to be involved in the pathogenesis of diabetes. Many interdependent variables determine the outcome of an infection with a Coxsackie virus, one of them being the tropism of the virus for a specific tissue. The extent to which Beta cell tropic variants of Coxsackie B4 virus occur naturally was assessed. Human isolates of this virus were tested in an in vitro system in which elevated insulin release from infected islets incubated at a non-stimulatory (2 mmol/l) glucose concentration appears to be related to viral attack. Using this technique, 8/24 isolates tested, impaired secretory function in mouse islets. Some strains of Coxsackie B4 virus, therefore, will directly infect mouse islets in vitro leading to changes in islet cell function. In conclusion, these findings confirm that variants of Coxsackie B4 virus with the potential to damage Beta cells occur quite frequently in the natural population. In certain circumstances the damage they inflict on Beta cells may cause destruction of these cells, or precipitate overt diabetes.

In vivo infection of mice with Coxsackie B4 virus induces long-term functional changes in pancreatic islets with minimal alteration in blood glucose

The long-term effects of Coxsackie B4 (CB4) infection of mice on pancreatic islet function were investigated. Mice were inoculated with various strains of CB4 virus and 2, 3 and 6 months later islet insulin synthesis and release from isolated islets were measured. Insulin release at basal glucose concentration (2 mmol l-1) was higher in islets from mice inoculated with pancreas-adapted CB4 strains than in control islets or those from mice inoculated with tissue culture-adapted CB4. Thus, two strains of pancreas-adapted virus (P11 and P12) increased basal insulin release by 72% compared with control islets (p less than 0.05) 1 month after inoculation. Another strain (P13) increased insulin release by 421% at 3 months post-inoculation (p less than 0.01) and by 192% at 6 months (p less than 0.05) compared with control islets. The rate of total protein synthesis in islets from P11-inoculated mice 1 month later was 61% lower than in control islets at basal glucose levels (p less than 0.001), and was 25% lower at 20 mmol l-1 glucose (p less than 0.01). There were no significant changes in protein synthesis in islets from infected mice at 3 or 6 months. The abnormal insulin release occurred with minimal changes in random blood glucose concentrations. Histologically the islets were unchanged and there were no detectable islet cell antibodies. These results show that CB4 infection may lead to a persistent metabolic dysfunction in islets with minimal changes in blood glucose levels.