[Intratympanic Steroid Treatment for Severe Idiopathic Sudden Sensorineural Hearing Loss].

Systemic steroid therapy is the only standard drug therapy for severe idiopathic sudden sensorineural hearing loss (ISSHL). We have treated severe ISSHL patients with double combined therapy, intravenous steroids (IVS) and hyperbaric oxygen (HBO). In this study, we retrospectively examined the effects of intratympanic steroids (ITS) by adding it to the double combined therapy. The study subjects were 172 patients with severe ISSHL. Eighty patients (38 men and 42 women) were treated with the double combined IVS and HBO therapy between April, 2007 and July, 2010 (A group: Historical control arm). Ninety-two patients (51 men and 41 women) were treated with triple therapy, combined therapy with IVS and HBO plus ITS, between August, 2010 and October, 2013 (B group: Current protocol arm). Each group was divided into two subgroups; one with a pure-tone average (PTA) between 60 and 89 dB (A1 and B1) and the other with a PTA ≥ 90 dB. A 1, A2, B1, and B2 sub-groups had 56 (29 men, 27 women), 24 (9 men, 15 women), 64 (36 men, 28 women), and 28 (15 men, 13 women) patients, respectively. All patients were treated within 30 days from the onset. There was a statistically significant difference in hearing improvement between the A2 and B2 groups, whereas no significant difference was observed between the A1 and B1 groups. Furthermore, a significant difference was observed in all frequencies but 2 kHz between at the A2 group and B2 group, but not between the A1 and B1 groups. Multivariate logistic analysis revealed that the treatment method (double vs.. triple combined therapies) had the strongest impact on hearing improvement in the ISSHL patients with a PTA ≥ 90 dB. These results indicated that the B2 group demonstrated better hearing improvement than the A2 group and suggested that the addition of the ITS could be effective for profound ISSHL patients with a PTA ≥ 90 dB.

Targeted deletion of the murine corneodesmosin gene delineates its essential role in skin and hair physiology.

Controlled proteolytic degradation of specialized junctional structures, corneodesmosomes, by epidermal proteases is an essential process for physiological desquamation of the skin. Corneodesmosin (CDSN) is an extracellular component of corneodesmosomes and, although considerable debate still exists, genetic studies have suggested that the CDSN gene in the major psoriasis-susceptibility locus (PSORS1) may be responsible for susceptibility to psoriasis, a human skin disorder characterized by excessive growth and aberrant differentiation of keratinocytes. CDSN is also expressed in the inner root sheath of hair follicles, and a heterozygous nonsense mutation of the CDSN gene in humans is associated with scalp-specific hair loss of poorly defined etiology. Here, we have investigated the pathogenetic roles of CDSN loss of function in the development of skin diseases by generating a mouse strain with targeted deletion of the Cdsn gene. Cdsn-deficient mouse skin showed detachment of the stratum corneum from the underlying granular layer and/or detachment within the upper granular layers due to the disrupted integrity of the corneodesmosomes. When grafted onto immunodeficient mice, Cdsn-deficient skin showed rapid hair loss together with epidermal abnormalities resembling psoriasis. These results underscore the essential roles of CDSN in hair physiology and suggest functional relevance of CDSN gene polymorphisms to psoriasis susceptibility.

Alteration of intra-pancreatic target-organ specificity by abrogation of Aire in NOD mice.

Factors that determine the spectrum of target organs involved in autoimmune destruction are poorly understood. Although loss of function of autoimmune regulator (AIRE) in thymic epithelial cells is responsible for autoimmunity, the pathogenic roles of AIRE in regulating target-organ specificity remain elusive. In order to gain insight into this issue, we have established NOD mice, an animal model of type 1 diabetes caused by autoimmune attack against beta cell islets, in which Aire has been abrogated. Remarkably, acinar cells rather than beta cell islets were the major targets of autoimmune destruction in Aire-deficient NOD mice, and this alteration of intra-pancreatic target-organ specificity was associated with production of autoantibody against pancreas-specific protein disulfide isomerase (PDIp), an antigen expressed predominantly by acinar cells. Consistent with this pathological change, the animals were resistant to the development of diabetes. The results suggest that Aire not only is critical for the control of self-tolerance but is also a strong modifier of target-organ specificity through regulation of T cell repertoire diversification. We also demonstrated that transcriptional expression of PDIp was retained in the Aire-deficient NOD thymus, further supporting the concept that Aire may regulate the survival of autoreactive T cells beyond transcriptional control of self-protein expression in the thymus.

Essential role of IkappaB kinase alpha in thymic organogenesis required for the establishment of self-tolerance.

IkappaB kinase (IKK) alpha exhibits diverse biological activities through protein kinase-dependent and -independent functions, the former mediated predominantly through a noncanonical NF-kappaB activation pathway. The in vivo function of IKKalpha, however, still remains elusive. Because a natural strain of mice with mutant NF-kappaB-inducing kinase (NIK) manifests autoimmunity as a result of disorganized thymic structure with abnormal expression of Rel proteins in the thymic stroma, we speculated that the NIK-IKKalpha axis might constitute an essential step in the thymic organogenesis that is required for the establishment of self-tolerance. An autoimmune disease phenotype was induced in athymic nude mice by grafting embryonic thymus from IKKalpha-deficient mice. The thymic microenvironment that caused autoimmunity in an IKKalpha-dependent manner was associated with defective processing of NF-kappaB2, resulting in the impaired development of thymic epithelial cells. Thus, our results demonstrate a novel function for IKKalpha in thymic organogenesis for the establishment of central tolerance that depends on its protein kinase activity in cooperation with NIK.

Development of autoimmunity against transcriptionally unrepressed target antigen in the thymus of Aire-deficient mice.

Autoimmune regulator (AIRE) gene mutation is responsible for the development of organ-specific autoimmune disease with monogenic autosomal recessive inheritance. Although Aire has been considered to regulate the elimination of autoreactive T cells through transcriptional control of tissue-specific Ags in thymic epithelial cells, other mechanisms of AIRE-dependent tolerance remain to be investigated. We have established Aire-deficient mice and examined the mechanisms underlying the breakdown of self-tolerance. The production and/or function of immunoregulatory T cells were retained in the Aire-deficient mice. The mice developed Sjogren's syndrome-like pathologic changes in the exocrine organs, and this was associated with autoimmunity against a ubiquitous protein, alpha-fodrin. Remarkably, transcriptional expression of alpha-fodrin was retained in the Aire-deficient thymus. These results suggest that Aire regulates the survival of autoreactive T cells beyond transcriptional control of self-protein expression in the thymus, at least against this ubiquitous protein. Rather, Aire may regulate the processing and/or presentation of self-proteins so that the maturing T cells can recognize the self-Ags in a form capable of efficiently triggering autoreactive T cells. With the use of inbred Aire-deficient mouse strains, we also demonstrate the presence of some additional factor(s) that determine the target-organ specificity of the autoimmune disease caused by Aire deficiency.

Subcellular expression of autoimmune regulator is organized in a spatiotemporal manner.

Autoimmune regulator (AIRE) is responsible for the development of organ-specific autoimmune disease in a monogenic fashion. Rare and low levels of tissue expression together with the lack of AIRE-expressing cell lines have hampered a detailed analysis of the molecular dynamics of AIRE. Here we have established cell lines stably transfected with AIRE and studied the regulatory mechanisms for its subcellular expression. We found that nuclear body (NB) formation by AIRE was dependent on the cell cycle. Biochemical fractionation revealed that a significant proportion of AIRE is associated with the nuclear matrix, which directs the functional domains of chromatin to provide sites for gene regulation. Upon proteasome inhibition, AIRE NBs were increased with concomitant reduced expression in the cytoplasm, suggesting that subcellular targeting of AIRE is regulated by a ubiquitin-proteasome pathway. We also found that AIRE NBs compete for cAMP-response element-binding protein-binding protein/p300, a common coactivator of transcription, with the promyelocytic leukemia gene product. These results suggest that the transcriptional regulating activities of AIRE within a cell are controlled and organized in a spatiotemporal manner.

NF-kappa B-inducing kinase establishes self-tolerance in a thymic stroma-dependent manner.

Physical contact between thymocytes and the thymic stroma is essential for T cell maturation and shapes the T cell repertoire in the periphery. Stromal elements that control these processes still remain elusive. We used a mouse strain with mutant NF-kappaB-inducing kinase (NIK) to examine the mechanisms underlying the breakdown of self-tolerance. This NIK-mutant strain manifests autoimmunity and disorganized thymic structure with abnormal expression of Rel proteins in the stroma. Production of immunoregulatory T cells that control autoreactive T cells was impaired in NIK-mutant mice. The autoimmune disease seen in NIK-mutant mice was reproduced in athymic nude mice by grafting embryonic thymus from NIK-mutant mice, and this was rescued by supply of exogenous immunoregulatory T cells. Impaired production of immunoregulatory T cells by thymic stroma without normal NIK was associated with altered expression of peripheral tissue-restricted Ags, suggesting an essential role of NIK in the thymic microenvironment in the establishment of central tolerance.

AIRE functions as an E3 ubiquitin ligase.

Autoimmune regulator (AIRE) gene mutation is responsible for the development of autoimmune-polyendocrinopathy-candidiasis ectodermal dystrophy, an organ-specific autoimmune disease with monogenic autosomal recessive inheritance. AIRE is predominantly expressed in medullary epithelial cells of the thymus and is considered to play important roles in the establishment of self-tolerance. AIRE contains two plant homeodomain (PHD) domains, and the novel role of PHD as an E3 ubiquitin (Ub) ligase has just emerged. Here we show that the first PHD (PHD1) of AIRE mediates E3 ligase activity. The significance of this finding was underscored by the fact that disease-causing missense mutations in the PHD1 (C311Y and P326Q) abolished its E3 ligase activity. These results add a novel enzymatic function for AIRE and suggest an indispensable role of the Ub proteasome pathway in the establishment of self-tolerance, in which AIRE is involved.