Effector mechanisms of the autoimmune syndrome in the murine model of autoimmune polyglandular syndrome type 1

Mutations in the Aire gene result in a clinical phenomenon known as Autoimmune Polyglandular Syndrome (APS) Type I, which classically manifests as a triad of adrenal insufficiency, hypoparathyroidism, and chronic mucocutaneous infections. In addition to this triad, a number of other autoimmune diseases have been observed in APS1 patients including Sj?gren's syndrome, vitiligo, alopecia, uveitis, and others. Aire-deficient mice, the animal model for APS1, have highlighted the role of the thymus in the disease process and demonstrated a failure in central tolerance in aire-deficient mice. However, autoantibodies have been observed against multiple organs in both mice and humans, making it unclear what the specific role of B and T cells are in the pathogenesis of disease. Using the aire-deficient mouse as a preclinical model for APS1, we have investigated the relative contribution of specific lymphocyte populations, with the goal of identifying the cell populations which may be targeted for rational therapeutic design. In this study, we show that T cells are indispensable to the breakdown of self-tolerance, in contrast to B cells which play a more limited role in autoimmunity. Th1 polarized CD4(+) T cells, in particular, are major contributors to the autoimmune response. With this knowledge, we go on to use therapies targeted at T cells to investigate their ability to modulate disease in vivo. Depletion of CD4(+) T cells using a neutralizing Ab ameliorated the disease process. Thus, therapies targeted specifically at the CD4(+) T cell subset may help control autoimmune disease in patients with APS1.     

Genetic homogeneity of autoimmune polyglandular disease type I.

Autoimmune polyglandular disease type I (APECED) is an autosomal recessive autoimmune disease (MIM 240300) characterized by hypoparathyroidism, primary adrenocortical failure, and chronic mucocutaneous candidiasis. The disease is highly prevalent in two isolated populations, the Finnish population and the Iranian Jewish one. Sporadic cases have been identified in many other countries, including almost all European countries. The APECED locus has previously been assigned to chromosome 21q22.3 by linkage analyses in 14 Finnish families. Locus heterogeneity is a highly relevant question in this disease affecting multiple tissues and with great phenotypic diversity. To solve this matter, we performed linkage and haplotype analyses on APECED families rising from different populations. Six microsatellite markers on the critical chromosomal region of 2.6 cM on 21q22.3 were analyzed. Pairwise linkage analyses revealed significant LOD scores for all these markers, maximum LOD score being 10.23. The obtained haplotype data and the geographic distribution of the great-grandparents of the Finnish APECED patients suggest the presence of one major, relatively old mutation responsible for approximately 90% of the Finnish cases. Similar evidence for one founder mutation was also found in analyses of Iranian Jewish APECED haplotypes. These haplotypes, however, differed totally from the Finnish ones. The linkage analyses in 21 non-Finnish APECED families originating from several European countries provided independent evidence for linkage to the same chromosomal region on 21q22.3 and revealed no evidence for locus heterogeneity. The haplotype analyses of APECED chromosomes suggest that in different populations APECED is due to a spectrum of mutations in a still unknown gene on chromosome 21.     

Characterization of mutations in patients with autoimmune polyglandular syndrome type 1 (APS1)

Autoimmune polyglandular syndrome type 1 (APS1), also known as autoimmune polyendocrinopathy candidiasis ectodermal dystrophy (APECED), is an autosomal recessive disorder characterized by the failure of several endocrine glands as well as nonendocrine organs. The autoimmune regulator (AIRE) gene responsible for APS1 on chromosome 21q22.3 has recently been identified. Here, we have characterized mutations in the AIRE gene by direct DNA sequencing in 16 unrelated APS1 families ascertained mainly from the USA. Our analyses identified four different mutations (a 13-bp deletion, a 2-bp insertion, one nonsense mutation, and one potential splice/donor site mutation) that are likely to be pathogenic. Fifty-six percent (9/16) of the patients contained at least one copy of a 13-bp deletion (1094–1106del) in exon 8 (seven homozygotes and two compound heterozygotes). A nonsense mutation (R257X) in exon 6 was also found in 31.3% (5/16) of the USA patients. These data are important for genetic diagnosis and counseling for families with autoimmune endocrine syndromes. Received: 24 August 1998 / Accepted: 29 September 1998     

HLA-DQA1*0301-associated susceptibility for autoimmune polyglandular syndrome type II and III.

No significant differences were reported for the frequency of DR3-DQ2 and DR4-DQ8 haplotypes in a recent study of one of the largest cohorts worldwide of patients with isolated Addison's disease compared to patients with APS II. However, previous studies had suggested that the HLA-DQ genes, especially DQA1*0102, may be a genetic marker for resistance to autoimmune thyroid disease, which is the most frequent disease in APS II or III. Until now, HLA-DQA1 alleles have not been systematically investigated in APS. We determined the HLA-DR and HLA-DQA1 association in 112 unrelated patients with APS II (n = 29), APS III (n = 83) and 184 unrelated patients with single-component diseases without further manifestations of APS: Graves' disease (n = 70), Hashimoto's thyroiditis (n = 53), autoimmune Addison's disease (n = 15), vitiligo (n = 16) and alopecia (n = 30), and 72 healthy controls - German Caucasians - to identify possible predisposing and protective HLA class II alleles in APS. In agreement with previous studies, we detected a significantly higher frequency of DR 3 and/or DR 4 in patients with APS II and III compared to controls. In patients with APS II, we detected a significantly higher frequency of DQA1*0301 and *0501 compared to controls confirming the increased frequency of an extended HLA DRB1-*04-DQA1-*03-DQB-*03 haplotype as previously described. In contrast, only DQA1*0301 was increased in our patients with APS III compared to controls. Moreover, we detected an increased frequency of DQA1*0301 in patients with APS, whereas DQA1*0301 was only significantly elevated in alopecia in patients with single-component diseases without APS. Therefore, our results indicate an association between DQA1*0301 and APS II or III since this allele was otherwise not significantly associated with any of its component diseases except alopecia. Moreover, our data imply that the allele DQA1*0301 is a marker of increased risk for further APS manifestations in patients who suffer from an organ-specific autoimmune disease.     

Goldenhar syndrome associated with growth hormone deficiency

Goldenhar syndrome is a rare disorder of unknown etiology. The most frequent findings are vertebral defects, hemifacial microsomia and ear abnormalities. We present an 8-year-old boy with oculo-auriculo-vertebral (Goldenhar) syndrome. He also had a parachute mitral valve and growth hormone deficiency. Parachute mitral valve is a previously unreported finding while growth hormone deficiency was reported just in one case in the literature.     

Acquired von Willebrand's disease in the course of severe primary hypothyroidism in a patient with autoimmune polyglandular syndrome type 3

The case of a 20-year old female, who had been followed because of von Willebrand disease (vWD) was presented in this paper . She had a past history of menorrhagia and bleeding after dental procedures and the activity of von Willebrand factor (vWF) was decreased. Because of suggestive clinical features, the workup for hypothyroidism was performed and the patient was found to have severe hypothyroidism due to Hashimoto thyroiditis. After the institution of replacement therapy with levothyroxine, von Willebrand factor activity returned to normal range and symptoms of von Willebrand disease disappeared. Based on these findings, the diagnosis of acquired von Willebrand syndrome (AvWS) due to hypothyroidism was made. The development of myasthenia led to the final diagnosis of autoimmune polyglandular syndrome type 3 (APS) with myasthenia gravis and vitiligo.     

Age-related prevalence of platelet-associated immunoglobulins G in nonthrombocytopenic patients with autoimmune thyroid disease and autoimmune polyglandular syndrome

OBJECTIVE: The prevalence of platelet-associated IgG (paIgG) in nonthrombocytopenic patients with autoimmune thyroid disease (AITD) alone or associated with autoimmune polyglandular syndrome (APS) has been studied. SUBJECTS: A total of 164 individuals were enrolled in this study: 81 patients with AITD alone, 33 patients with APS, and 50 healthy controls. RESULTS: The presence of paIgG was recorded in 41 of 81 patients with AITD (51%) as compared with 2 of 50 control subjects (4%, p < 0.0001). The prevalence of paIgG in patients with APS was higher even when compared with patients with AITD alone (25/33, 76%; p = 0.02). The presence of paIgG was not related to the functional thyroid parameters. The prevalence of paIgG was higher in the older than in the younger patients (75 vs. 47%, p = 0.0037). CONCLUSIONS: The results indicate that the prevalence of paIgG in patients with AITD is higher than previously thought, namely in elderly patients and in patients with APS, and not related to the thyroid function.     

Dosing of growth hormone in growth hormone deficiency

Growth hormone (GH) treatment of GH-deficient (GHD) children is to a certain extent standardized worldwide. Recombinant 22 kDa GH is injected once daily by the subcutaneous route, mostly in the evening. The amount of GH injected (calculated per kg body weight or body surface area, expressed in terms of IU or mg) in prepubertal children mimics the known production rate (approximately 0.02 mg [0. 06 IU]/kg body weight per day). However, there is a wide variation in dosage, the reasons for which are partly unknown and partly due to national traditions and regimes imposed by authorities regulating reimbursement. The situation during puberty is less standardized, with most clinicians still not increasing the dosage according to known production rates. The results of these approaches in terms of adult height outcome are not always satisfactory. In order to achieve optimal height development during childhood, puberty and adulthood, strategies must be developed to individualize GH dosing according to set therapeutical goals taking into account efficacy, safety and cost. The implementation of prediction algorithms will help us to reach these goals. In addition, other response variables will have to be monitored during treatment in order to correct for deficits resulting from GHD.     

Radiation-induced growth hormone deficiency

Deficiency of one or more anterior pituitary hormones may follow treatment with external irradiation when the hypothalamic-pituitary axis falls within the fields of irradiation. Hypopituitarism occurs in patients who receive radiation therapy for pituitary tumours, nasopharyngeal cancer and primary brain tumours, as well as in children who undergo prophylactic cranial irradiation for acute lymphoblastic leukaemia, or total body irradiation for a variety of tumours and other diseases. The degree of pituitary hormonal deficit is related to the radiation dose received by the hypothalamic-pituitary axis. Thus, after lower radiation doses isolated growth hormone deficiency ensues, whilst higher doses may produce hypopituitarism. The timing of onset of the radiation-induced pituitary hormone deficit is also dose-dependent. The main site of radiation damage is the hypothalamus rather than the pituitary, although the latter may be affected directly.     

Cognitive function in growth hormone deficiency and growth hormone replacement

There is converging evidence from neuropsychological studies that growth hormone (GH) is associated with cognitive function. The aim of the current study was to review the existing neuropsychological literature for studies in which cognitive assessment had been conducted in patients with GH deficiency (GHD), and where change in cognitive function had been assessed following treatment with GH. Studies that have investigated relationships between GH and cognitive function and those that have developed methodological and statistical approaches that could be useful in future GH studies were identified. In this review, GH levels were found to be associated with cognitive function. Untreated individuals with GHD showed reliable impairment in memory and attentional functions when compared with matched controls. Appropriately designed prospective studies also indicated that cognitive function improved with GH treatment. It was concluded that individuals with GHD do show cognitive impairment and that this is ameliorated to some extent by GH treatment. It is now important to establish the clinical importance of these findings, and further work is required to understand better the nature, magnitude and meaning of GH-related cognitive impairments and improvements.     

Insulin sensitivity in adults with growth hormone deficiency and effect of growth hormone treatment

Adult growth hormone deficiency (GHD) is a multifactorial disorder in which pituitary dysfunction associated with pituitary adenomas or their treatment plays a major role. The introduction of recombinant growth hormone (GH) for the treatment of GHD has opened up new treatment avenues but has also raised concerns about possible untoward long-term metabolic effects of GH, such as the potential effect of GH on insulin sensitivity and a deterioration in glucose tolerance. Research has shown that GH induces insulin resistance by the stimulation of lipolysis and a concomitant switch from oxidation of glucose to oxidation of lipids, during both acute and chronic treatment. However, although this is a consistent effect of GH therapy, it does not mean per se that it leads to abnormal glucose tolerance and diabetes mellitus. This article discusses this and other potential long-term metabolic effects of GH, and raises a number of questions to be addressed by future research.     

Immunogenetics of the polyglandular failure syndrome

Addison's disease, Graves' disease, thyroiditis, hypoparathyroidism, hypogonadism, diabetes mellitus, myasthenia gravis, vitiligo and pernicious anemia are included in the polyglandular failure syndrome. This review focuses on the association of these illnesses with specific human leukocyte antigens (HLA) and organ specific autoimmunity. The prevalence of HLA-B8, HLA-Bw15 and HLA-Dw3 is increased in these disorders. The HLA region of chromosome 6 controls multiple immune functions. The common HLA associations and evidence of autoimmunity in the polyglandular failure diseases suggests that gene products of chromosome 6 contribute to the pathogenesis of these disorders.     

The molecular basis of growth hormone deficiency

A well-known law states that 'if a thing can go wrong it will go wrong'. This clearly applies to the hypothalamic-pituitary-somatic axis as to many other physiological and biochemical systems. Defects of this axis, giving rise to stunted growth, can occur at several different points, as has been discussed in detail in this review. Defects at the level of the brain can lead to inadequate production or secretion of the factors that control growth hormone secretion. Defects at the level of the pituitary can lead to failure to produce or secrete adequate quantities of growth hormone, or to production of inactive hormone. Defects at the level of target organs can lead to inability to respond to growth hormone or somatomedins. The axis involved in the production and effects of growth hormone is a complex one, and defects have been identified at most of the points that 'could go wrong', although in many cases the molecular details are far from fully understood. Increased understanding of the biochemistry and physiology of the hormonal control of growth, and of the impairments to which it is subject, should provide an improved basis for treatment of growth defects. Nevertheless, there remain many points at which our knowledge is very incomplete. The field is a rapidly moving one and further developments in both basic understanding and clinical treatment are to be expected during the next few years.