Immunology of diabetic and polyglandular neuropathy

The immunofluorescence techniques in the diagnosis of endocrine autoimmune diseases

In the study of autoimmune diseases, the laboratory plays a very important role. We describe the immunofluorescence techniques (direct, indirect, complement-fixing, double) for determining the presence of autoantibodies and their role in the autoimmune endocrine diseases.

Altered nerve excitability in subclinical/early diabetic neuropathy: evidence for early neurovascular process in diabetes mellitus?

We sought to investigate the peripheral nerve excitability property of early diabetic neuropathy (DN) and provide a logical hypothesis regarding the pathophysiology of subclinical/early stage of DN. The automated nerve excitability test (NET) utilizing the threshold tracking technique (TTT) was performed to measure multiple excitability indices in 30 early DN and 30 normal subjects. Early DN was defined as N0 or N1 stage of Dyck's staging method. The protocols calculated strength-duration time constant (SDTC) from duration-charge curve, parameters of threshold electrotonus (TE) and current-threshold relationship (CTR) from sequential sub-threshold current, and recovery cycle (RC) from double supra-threshold stimulation. Each parameter of test was co-analyzed with clinical and laboratory data including age, sex, BMI, HgbA1c, lipid profile, and estimated glomerular filtration rate (eGFR). Compared to normal or N0 groups, N1 group had 'fanning-in' phenomenon in TE, increased refractory period, and decreased supernormality/subnormality. Linear regression showed that parameters associated with vascular factor were significantly related with STDC: absolute TG values were positively associated with STDC, whereas eGFR values were inversely related with STDC. Nerve excitability can be altered even in the early mild DN. The pattern of alteration suggests depolarizing nerve or nerve ischemia in pathophysiology of subclinical/early DN.

Effect of various nerve decompression procedures on the functions of distal limbs in streptozotocin-induced diabetic rats: further optimism in diabetic neuropathy

It is known that diabetic neuropathy is the result of endoneurial edema caused by various biochemical reactions triggered by hyperglycemia. This sequence of events can cause cessation of circulation at the perineurial level, or the tough layer, which is not resilient enough to spread intraneural pressure. Internal and external limiting structures create a double crush phenomenon to the nerve structure. Decompression of the nerve trunk at separate levels is one of the adjuncts to the overall treatment plan for diabetic neuropathy. In this study, the right sciatic nerves of 30 rats with streptozotocin-induced diabetes were used; three groups were created. In the control group, the sciatic nerves were explored and dissected only. In group II, tarsal tunnel release was performed and accompanied by epineurotomy of the sciatic nerve and its peroneal and tibial extensions. In group III, in addition to the procedures performed in group II, perineural sheaths, exposed through the epineurotomy sites at both the peroneal and tibial nerves, were incised for decompression of the fascicles. Improvement in diabetic neuropathy was evaluated by using footprint parameters. The last print length values, estimated according to the 38-month measurements, were 26.1 +/- 0.12 mm in the control group, 23.2 +/- 0.07 mm in group II, and 22.2 +/- 0.1 mm in group III. The toe spread and intermediate toe spread values of the groups were parallel to improvements in print lengths throughout the study. The best improvement was observed in the perineurotomy group. Finally, an electron microscopic study revealed variable degenerative changes in all groups, but they were milder in groups II and III. This experimental study reveals that adding internal decompression to external release doubled the effect in reducing derangement in the sciatic nerves of the rats and, in the authors' opinion, offers cause for further optimism in the treatment of diabetic neuropathy.

Developmental expression of the type I diabetes related antigen sulfatide and sulfated lactosylceramide in mammalian pancreas

Previous studies have shown that sulfatide is present and functionally involved in beta cells, and that anti-sulfatide antibodies (ASA) exist during development of type I diabetes mellitus. To further explore the possible role of sulfatide in type I diabetes, developmental expression was examined in human pancreas and in pancreas of the type I diabetes models BB rat and NOD mouse compared to Lewis rat and BALB/c mouse, respectively. Sulfatide was not only expressed in adult pancreas, but also in human fetal and rodent neonatal pancreas, i.e., during the growing period of the immunological self. Sulfatide had a different expression pattern in human beings and rodents, concerning both the amounts of sulfatide and expression during development. There was no change in the sulfatide fatty acid isoform expression during development. The pancreatic expression of another sulfated glycosphingolipid, sulfated lactosylceramide, indicated that this molecule is a potential fetal/neonatal marker, which was further expressed in the type I diabetic models. In conclusion, these findings give further support to the possibility that sulfatide is a relevant autoantigen in type I diabetes and that sulfated lactosylceramide might function as a potential risk factor for disease development, at least in the animal models.

Sulfatide controls insulin secretion by modulation of ATP-sensitive K(+)-channel activity and Ca(2+)-dependent exocytosis in rat pancreatic beta-cells

The glycosphingolipid sulfatide is present in secretory granules and at the surface of pancreatic beta-cells, and antisulfatide antibodies (ASA; IgG1) are found in serum from the majority of patients with newly diagnosed type 1 diabetes. Here we demonstrate that sulfatide produced a glucose- and concentration-dependent inhibition of insulin release from isolated rat pancreatic islets. This inhibition of insulin secretion was due to activation of ATP-sensitive K(+)-(K(ATP)) channels in single rat beta-cells. No effect of sulfatide was observed on whole-cell Ca(2+)-channel activity or glucose-induced elevation of cytoplasmic Ca(2+) concentration. It is interesting that sulfatide stimulated Ca(2+)-dependent exocytosis determined by capacitance measurements and depolarized-induced insulin secretion from islets exposed to diazoxide and high external KCl. The monoclonal sulfatide antibody Sulph I as well as ASA-positive serum reduced glucose-induced insulin secretion by inhibition of Ca(2+)-dependent exocytosis. Our data suggest that sulfatide is important for the control of glucose-induced insulin secretion and that both an increase and a decrease in the sulfatide content have an impact on the secretory capacity of the individual beta-cells.

Relation between homocysteinaemia and diabetic neuropathy in patients with Type 2 diabetes mellitus

AIMS

Limited data are available on determinants of diabetic neuropathy as its pathogenesis is multifactorial. Since homocysteine exhibits toxic effects on vascular endothelial cells, the association between homocysteine and the prevalence of neuropathy in Type 2 diabetes mellitus was investigated.

METHODS

A total of 65 Type 2 diabetic patients were consecutively enrolled into the study. Neuropathy was diagnosed according to clinical symptoms, clinical examination, electrophysiological sensory testing and autonomic function testing. With regard to homocysteine-related parameters, plasma homocysteine, folate, vitamin B12, vitamin B6 and renal function (creatinine, ceratinine clearance, cystatin C) were measured, and the C677T polymorphism of the methylenetetrahydrofolate reductase gene was determined.

RESULTS

Forty-three of the Type 2 diabetic patients were classified as suffering from neuropathy. Both patient groups were comparable with regard to demographic data, blood pressure, glucose metabolism, renal function and homocysteine-related vitamins. In contrast, homocysteine levels (P = 0.04) and the frequency of hyperhomocysteinemia (>or= 15 micromol/l) (P = 0.01) were significantly increased in neuropathic patients. In a logistic regression model with neuropathy as dependent variable, homocysteine (adjusted for creatinine, homocysteine-related vitamins, HbA1c and duration of diabetes) was the only significant variable associated with the prevalence of neuropathy (odds ratio for homocysteine per 5 micromol/l increase: 2.60 (95% confidence interval 1.07-6.33)).

CONCLUSION

The data indicate that homocysteine is independently associated with the prevalence of diabetic neuropathy in a collective of Type 2 diabetic patients. A larger, prospective study would be desirable to clarify the role of homocysteine in the pathogenesis of diabetic neuropathy.

Autonomic function and autoantibodies to autonomic nervous structures, glutamic acid decarboxylase and islet tyrosine phosphatase in adolescent patients with IDDM

Recent studies have linked autoimmunity to nervous tissue structures and diabetic autonomic neuropathy, but data on the early stage of IDDM and on the natural history of this association are not available. For this reason, we investigated autonomic nervous function, and the presence of autoantibodies to sympathetic and parasympathetic nervous structures, to glutamic acid decarboxylase (GAD) and tyrosine phosphatase (IA-2/ICA512) in 85 adolescents with insulin-dependent diabetes mellitus (IDDM) (mean age 14.7+/-1.6 yr, mean duration of diabetes 6.8+/-3.5 yr), and 45 age and sex-matched healthy subjects. Nervous tissues autoantibodies were detected using an indirect immunofluorescent complement-fixation technique, with monkey adrenal gland, rabbit cervical ganglia and vagus nerve as substrates. GAD and IA-2/ICA512 autoantibodies were detected by radioimmunoprecipitation assay. Seven patients (8%) had anti-vagus nerve autoantibodies, 7 other patients (8%) had anti-cervical ganglia autoantibodies, while all controls were negative (P < 0.05). Anti-adrenal medulla antibodies were detected in 16 patients (19%) and in 2 control subjects (P<0.02). None of the patients had autonomic symptoms. When patients were divided according to the presence or absence of autoantibodies, values of the cardiovascular tests (deep breathing, 30:15 ratio, Valsalva ratio) were similar in the two groups and similar to those in healthy subjects. However, when considered together, patients positive for one or more autoantibody showed a trend for lower values of deep breathing test and 30:15 ratio test, compared with healthy control subjects, which failed to reach conventional significance values (P=0.17 and P=0.07, respectively). No correlation was found between cardiovascular parameters and metabolic control or diabetes duration. There was no association between autoimmunity to nervous tissue structures and presence of GAD and IA-2/ICA512 Ab, and no correlation between these two autoantibodies and values of cardiovascular tests. Our data indicate that autonomic dysfunction is not a characteristic of young diabetic patients, but that autoantibodies against autonomic nervous structures are present during the first 1 to 15 yr of diabetes. GAD and tyrosine phosphatase appear to be excluded as target autoantigens within autonomic structures. Follow-up studies are required to evaluate future autonomic dysfunction and symptoms in these patients, and to establish whether the subtle autonomic dysfunction detected and/or the nervous tissue autoantibodies, are predictive of the development of this complication.

Presence of sulphatide (3'-sulphogalactosylceramide) in pericytes in the choroid layer of the eye: sharing of this glycolipid autoantigen with islets of Langerhans

The aim of the study was to investigate the distribution in the eye of sulphatide, an acid glycolipid which has previously been demonstrated in islets of Langerhans, nervous tissue and in kidney glomeruli of diabetic patients, and against which antibodies have been found in patients with newly diagnosed insulin-dependent diabetes mellitus. A specific monoclonal antibody, Sulph I, was used for detection of sulphatide by thin-layer chromatography, and light and electron microscope immunohistochemistry. A distinct, patchy staining was found in the choroid layer and the ciliary processes. The antigen was confirmed to be sulphatide and its concentration in human eyes was 30 nmol sulphatide/g wet tissue. By electron microscopy, anti-sulphatide choroid labelling was demonstrated in pericytes and in smooth muscle cells surrounding vessels. No Sulph I-negative pericytes were seen. Double labelling with Sulph I and anti-smooth muscle actin revealed that only pericytes in the eye contained sulphatide and not those in heart, lung, liver, adrenal, spleen, lymph node, thymus, or pancreatic tissue. Thus, sharing of the autoantigen sulphatide has been demonstrated between islets of Langerhans and pericytes in the choroid layer of the eye.

Satoyoshi syndrome: an unusual postnatal multisystemic disorder

Satoyoshi syndrome is a rare disorder of unknown cause characterized by progressive, painful intermittent muscle spasms, malabsorption, alopecia, amenorrhea, and skeletal abnormalities mimicking a skeletal dysplasia. We describe a 19-year-old Caucasian woman with characteristic manifestations starting at age 9. The report of this patient confirms that this condition is not limited to the Asian population.

Sulphatide in islets of Langerhans and in organs affected in diabetic late complications: a study in human and animal tissue

Sulphatide has been found in rat islets of Langerhans and anti-sulphatide antibodies have been demonstrated in patients with insulin-dependent diabetes mellitus. Using a specific monoclonal antibody, Sulph I, directed against sulphatide, we investigated the in situ distribution of this glycolipid immunohistochemically; furthermore, the sulphatide concentration was determined in several organs and cells by thin-layer chromatography. The islets of Langerhans in all species examined, mouse, rat, pig, and monkey were intensively stained but exocrine tissue remained unlabelled. The sulphatide concentration in human islets was 150 +/- 46 pmol/100 islets. The only glycolipid-antigen detected was sulphatide. Regarding other tissues, sulphatide was found to be located in distal tubules in the kidney, peripheral nerves, distinct scattered spot-like structures in the choreoid layer of the eye, the ovum, and peripheral granulocytes. Sulph I injection in mice showed homing to kidney tubules, Lung, heart, liver, adrenal, spleen, lymph node and thymus were not stained by Sulph I. Thus, the distribution of sulphatide shows an association with organs known to be affected in diabetes, either initially or in late complications.

Prevalence and forms of neuropathic morbidity in 800 diabetics

We prospectively determined the prevalence of morbidity from the various forms of diabetic neuropathy over one year in a population of 800 patients with diabetes mellitus (336 type 1, 464 type 2 DM). Symptoms documented were: pain/paraesthesia in the feet, loss of feeling and the restless legs syndrome. We also documented the prevalence of: neuropathic ulcers, amyotrophy, foot drop, and oculomotor palsy. Autonomic symptoms documented were: impotence, postural hypotension and diarrhoea. The only symptoms reported by 100 non-diabetic control subjects were: loss of feeling in 2% and restless legs syndrome in 7%. In the diabetics; pain/paraesthesia was present in 13%, feeling loss in 7% and neuropathic ulcers in 2%. The prevalence of Diabetic amyotrophy (proximal femoral neuropathy) was 0.8%, oculomotor palsy 0.1% and peroneal nerve palsy 0.1%. Erectile impotence was present in 20%, symptomatic postural hypotension in 1% and diabetic diarrhoea in 1%. Overall; 22.9% of the population was afflicted by one or more problems resulting from neuropathy. Neuropathy was associated with older age (p < 0.001), and serious retinopathy (p < 0.001) in both groups of diabetics and with duration of diabetes, proteinuria (p < 0.02), hypertension (p < 0.01) and ischaemic heart disease (p < 0.02) in type 1 diabetics.

Sulphatide antigen in islets of Langerhans and in diabetic glomeruli, and anti-sulphatide antibodies in type 1 diabetes mellitus

Clinical coincidence between diabetes and neurological disorders, and sharing of antigen determinants between islets of Langerhans and neural tissue, has been suggested. Sulphatide is a neural epitope which can be visualized with a monoclonal antibody Sulph I. Different tissues were examined by immunohistological methods. Sulphatide and anti-sulphatide antibodies were determined by thin-layer chromatographic techniques. IgG was isolated using protein A columns. A specific staining by Sulph I was found of rat islets, assigned to the secretory granules of both alpha and beta cells. No labelling of the exocrine tissue or other body tissues was seen, except for nerve and kidney structures. The latter showed staining of the distal tubules and, in addition, but only in the diabetic kidney, of glomeruli located in the subendothelial area in the capillary loops and the mesangial space. Sera from 38% of 40 spontaneously diabetic BB rats displayed anti-sulphatide antibodies, mainly IgG, whereas all 30 control Lewis rats were negative. Most recently we have demonstrated anti-sulphatide antibodies in 88% of 57 patients with newly diagnosed Type 1 diabetes (titres of > 1:400); all 135 healthy control persons were negative. The sulphatide antibody reactivity was present in the IgG fractions of the patients' sera. Thus, sulphatide is demonstrated in islets of Langerhans and in kidney related to the diabetic lesion, and, furthermore, anti-sulphatide antibodies exist in Type 1 diabetes mellitus.

The toxic effects of serum from patients with type 1 diabetes mellitus on mouse neuroblastoma cells: a new mechanism for development of diabetic autonomic neuropathy

The pathogenesis of diabetic neuropathy is incompletely understood. The possibility that humoral neurotoxic factors contribute as a cause of diabetic neuropathy was tested by application of serum from patients with Type 1 and Type 2 diabetes to mouse neuroblastoma cells, which have the characteristics of adrenergic neurons in culture. Serum from patients with Type 1 diabetes and somatic neuropathy significantly inhibited both proliferation and differentiation of neuroblastoma cells, while serum from patients with Type 1 diabetes but no symptoms of neuropathy and patients with Type 2 diabetes and neuropathy had no effect on proliferation, and serum from Type 2 patients only marginally inhibited differentiation. The effects of Type 1 diabetic serum could be reversed by pre-absorption of the serum to neuroblastoma cells, and were independent of glucose levels. Immunoglobulins precipitated from the sera mimicked the effects of whole sera. These results suggest that Type 1 diabetes mellitus causes a change in serum composition, possibly related to autoimmunity, that is capable of contributing to adrenergic autonomic neuropathy in diabetic patients.

Sulphatide and sulphatide antibodies in insulin-dependent diabetes mellitus

Insulin-dependent diabetes mellitus (IDDM) is associated with neurological disorders. Sulph I, a monoclonal antibody to sulphatide (a neural epitope), stained secretory granules in alpha and beta cells of rat islets of Langerhans, but not exocrine tissue. Sera from 88% of 57 newly diagnosed IDDM patients was anti-sulphatide positive, and 76% were positive 6 months later. All 135 healthy controls were negative. Sulphatide antibody may be an IDDM marker.

Relationships between dyspeptic symptoms and gastrointestinal motility in patients with type 1 (insulin-dependent) diabetes mellitus

Reports on motor abnormalities in Type 1 (insulin-dependent) diabetes mellitus are inconsistent. In 20 Type 1 diabetic patients and in 11 control subjects antroduodenojejunal manometry was performed under euglycaemic conditions in order to examine the prevalence of gastric and small intestinal motor abnormalities in relation to dyspeptic symptoms and the degree of cardiac autonomic neuropathy. In diabetic patients compared to control subjects phase III (regular, high-amplitude contractile activity at maximal frequency) involved the gastric antrum less often (12 vs 35%, p < 0.05), the duration of phase I (motor quiescence) was shorter (6 +/- 1 vs 21 +/- 4 min, p < 0.002) and in phase II (irregular motor activity) the frequency of duodenal and jejunal contractions was higher. After a meal the duration of the fed state was shorter in diabetic patients with symptoms during the study than in diabetic patients without symptoms and than in control subjects (57 +/- 27 vs 157 +/- 11 and 140 +/- 13 min, p < 0.02). Postprandial antral hypomotility was seen in diabetic patients with symptoms only in the first 30 min after the meal. One hour after the meal the frequency of duodenal and jejunal contractions was again higher in diabetic patients. In diabetic patients compared to control subjects more burst activity (clusters of non-propagated high-amplitude contractile activity at maximal frequency) was seen (7.9 +/- 1.6 vs 0.8 +/- 0.5% of the total time of study, p < 0.002). No correlation was found between manometric parameters and the degree of cardiac autonomic neuropathy.(ABSTRACT TRUNCATED AT 250 WORDS)

Autoantibodies to nervous tissue structures are associated with autonomic neuropathy in type 1 (insulin-dependent) diabetes mellitus

There is evidence that the immune system may play a role in the pathogenesis of autonomic neuropathy in Type 1 (insulin-dependent) diabetes mellitus. In the present study, we investigated the presence of autoantibodies to sympathetic and parasympathetic nervous structures and their correlation with other conventional autoantibodies in well-characterised diabetic populations, with or without diabetic neuropathy, and normal subjects. An indirect immunofluorescent complement-fixation technique was used, with monkey adrenal gland, rabbit cervical ganglia and vagus nerve as substrates. Of the patients with symptomatic autonomic neuropathy 33% were positive for at least one autoantibody (20% anti-sympathetic ganglia, 10% anti-vagus nerve and 13% anti-adrenal medulla). The frequency of having one or more antibodies to nervous tissues and the prevalence of anti-cervical ganglia antibodies were significantly higher in the neuropathic patients than in the diabetic control subjects with disease of similar duration and in the normal subjects (p < 0.05). Of the patients without complications with diabetes of shorter duration 33% were also positive for at least one autoantibody (13% anti-ganglia, 13% anti-vagus nerve and 13% anti-adrenal medulla). No correlation was found with other tissue autoantibodies, including islet cell antibodies. Our data indicate that nervous tissue autoantibodies are associated with symptomatic autonomic neuropathy. Anti-sympathetic ganglia and anti-vagus nerve antibodies seem to be more disease-specific. Patients with diabetes of shorter duration who were positive for these autoantibodies may represent pre-neuropathic patients.

Clinical observations and experiments in diabetic neuropathy

Diabetic neuropathies form a group of diverse conditions, which can be distinguished between those which recover (acute painful neuropathies, radiculopathies, mononeuropathies) and those which progress (sensory and autonomic neuropathies). These two main groups can be distinguished in several ways: sensory and autonomic neuropathies are classic diabetic complications progressing gradually in patients with long-standing diabetes who often have other specific complications, while the reversible neuropathies do not have these features. The latter are characterised by their occurrence at any stage of diabetes, often at diagnosis, they may be precipitated on starting insulin treatment, and they are more common in men; they can occur at any age, though more often in older patients, and are unrelated to other diabetic complications. The two groups of neuropathies also show differences in nerve structural abnormalities and with regard to distinctive blood flow responses. The underlying mechanisms responsible for these very different forms of neuropathy remain speculative, but evidence for an immunological basis for the development of severe symptomatic autonomic neuropathy is presented.