Early-onset sarcoidosis (EOS) and inheritable Blau syndrome (BS) share characteristic clinical features of juvenile-onset systemic granulomatosis syndrome that mainly affects skin, joints, and eyes. However, no direct evidence has been shown for the possible common origin of these 2 diseases. Recent discovery of CARD15 mutations in BS families encouraged us to investigate similar CARD15 mutations in EOS patients. Among 10 EOS cases retrospectively collected in Japan, heterozygous missense mutations were found in 9 cases; 4 showed a 1000C>T (R334W in amino acid change) that has been reported in BS, 4 showed novel 1487A>T (H496L) , IntroductionSarcoidosis is a multiorganic inflammatory disease with unknown etiology, characterized by the histologic features of noncaseating epithelioid granulomas. In childhood, 2 distinct types of sarcoidosis have been described. 1 Usually the disease is detected in older children by chest radiography and the clinical manifestations are characterized by a classical triad of lung, lymph node, and eye involvement, similar to those in adults. In contrast, early-onset sarcoidosis (EOS), which usually appears in those younger than 4 years of age, is quite rare and has a distinct triad of skin, joint, and eye disorders, without apparent pulmonary involvement. Compared with an asymptomatic and sometimes naturally disappearing course of the disease in older children, EOS is progressive and in many cases causes severe complications, such as blindness, joint destruction, and visceral involvement. 2 Blau syndrome (BS), also showing early-onset granulomatous arthritis, uveitis, and skin rash, is a rare familial disease transmitted in an autosomal dominant manner. 3 By linkage analysis, the responsible locus for BS was mapped to chromosome 16,4 in which CARD15 has recently been identified as the susceptibility gene. 5 CARD15 (NOD2) is a member of the growing family of nucleotide-binding oligomerization domain (NOD) proteins and composed of 2 amino-terminal caspase recruitment domains (CARDs), one NOD, and carboxy-terminal leucinerich repeats (LRRs). 6,7 While mutations in LRRs are reportedly associated with Crohn disease (CD) and psoriatic arthritis, 8-10 3 types of missense point mutations in the NOD, 1000CϾT (R334W in amino acid change), 1001GϾA (R334Q), and 1405CϾT (L469F), have been discovered in BS families. 5,11,12 It has been discussed since the first report of BS whether EOS and BS are the same diseases. 13 However, no direct evidence of their common origin has been shown and confusion still remains. 14 In the first paper describing genetic abnormalities in BS, the authors recognized no CARD15 mutation in 2 EOS patients and therefore proposed a different etiology of BS and EOS. 5 However, we have recently described a sporadic case of systemic granulomatosis syndrome with clinical features of EOS that showed the same CARD15 mutation as detected in BS. 15 In this report, therefore, we retrospectively collected Japanese EOS cases and searched for CARD15 mutations, to further evaluate the re...
Objective Chronic infantile neurologic, cutaneous, articular (CINCA) syndrome, also known as neonatal-onset multisystem inflammatory disease (NOMID), is a dominantly inherited systemic autoinflammatory disease. Although heterozygous germline gain-of-function NLRP3 mutations are a known cause of this disease, conventional genetic analyses fail to detect disease-causing mutations in ~40% of patients. Since somatic NLRP3 mosaicism has been detected in several mutation-negative NOMID/CINCA syndrome patients, we undertook this study to determine the precise contribution of somatic NLRP3 mosaicism to the etiology of NOMID/CINCA syndrome. Methods An international case–control study was performed to detect somatic NLRP3 mosaicism in NOMID/CINCA syndrome patients who had shown no mutation during conventional sequencing. Subcloning and sequencing of NLRP3 was performed in these mutation-negative NOMID/CINCA syndrome patients and their healthy relatives. Clinical features were analyzed to identify potential genotype–phenotype associations. Results Somatic NLRP3 mosaicism was identified in 18 of the 26 patients (69.2%). Estimates of the level of mosaicism ranged from 4.2% to 35.8% (mean ± SD 12.1 ± 7.9%). Mosaicism was not detected in any of the 19 healthy relatives (18 of 26 patients versus 0 of 19 relatives; P < 0.0001). In vitro functional assays indicated that the detected somatic NLRP3 mutations had disease-causing functional effects. No differences in NLRP3 mosaicism were detected between different cell lineages. Among nondescript clinical features, a lower incidence of mental retardation was noted in patients with somatic mosaicism. Genotype-matched comparison confirmed that patients with somatic NLRP3 mosaicism presented with milder neurologic symptoms. Conclusion Somatic NLRP3 mutations were identified in 69.2% of patients with mutation-negative NOMID/CINCA syndrome. This indicates that somatic NLRP3 mosaicism is a major cause of NOMID/CINCA syndrome.
Under physiological conditions, skin mast cells preferentially localize around nerves, blood vessels and hair follicles. This observation, which dates back to Paul Ehrlich, intuitively suggests that these enigmatic, multifacetted protagonists of natural immunity are functionally relevant to many more aspects of tissue physiology than just to the generation of inflammatory and vasodilatory responses to IgE-dependent environmental antigens. And yet, for decades, mainstream-mast cell research has been dominated by a focus on the -undisputedly prominent and important - mast cell functions in type I immune responses and in the pathogenesis and management of allergic diseases. Certainly, it is hard to believe that the very large and rather selectively distributed number of mast cells in normal, uninflamed, non-infected, non-traumatized mammalian skin or mucosal tissue simply hanging around there lazily day and night, just wait for the odd allergen or parasite-associated antigen to come by so the mast cell can finally swing into action. Indeed, the past decade has witnessed a renaissance of mast cell research 'beyond allergy', along with a more systematic exploration of the surprisingly wide range of physiological functions that mast cells may be involved in. The current debate sketches many exciting horizons that have recently come into our vision during this intriguing, ongoing search.
Role of the NOD2 genotype in the clinical phenotype of Blau syndrome and early‐onset sarcoidosis
Objective. Blau syndrome and its sporadic counterpart, early-onset sarcoidosis (EOS), share a phenotype featuring the symptom triad of skin rash, arthritis, and uveitis. This systemic inflammatory granulomatosis is associated with mutations in the NOD2 gene. The aim of this study was to describe the clinical manifestations of Blau syndrome/EOS in Japanese patients and to determine whether the NOD2 genotype and its associated basal NF-B activity predict the Blau syndrome/ EOS clinical phenotype.Methods. Twenty Japanese patients with Blau syndrome/EOS and NOD2 mutations were recruited. Mutated NOD2 was categorized based on its basal NF-B activity, which was defined as the ratio of NF-B activity without a NOD2 ligand, muramyldipeptide, to NF-B activity with muramyldipeptide.Results. All 9 mutations, including E383G, a novel mutation that was identified in 20 patients with Blau syndrome/EOS, were detected in the centrally located NOD region and were associated with ligandindependent NF-B activation. The median age of the patients at disease onset was 14 months, although in 2 patients in Blau syndrome families (with mutations R334W and E383G, respectively) the age at onset was 5 years or older. Most patients with Blau syndrome/EOS had the triad of skin, joint, and ocular symptoms, the onset of which was in this order. Clinical manifestations varied even among familial cases and patients with the same mutations. There was no clear relationship between the clinical phenotype and basal NF-B activity due to mutated NOD2. However, when attention was focused on the 2 most frequent mutations, R334W and R334Q, R334W tended to cause more obvious visual impairment.
IntroductionGain-of-function mutations in the c-kit receptor induce factorindependent proliferation of mast cells, thereby resulting in neoplastic transformation. 1 Various c-kit receptor mutations have been identified in different mast cell lines that have an ability to proliferate in the absence of any growth factor. 2-6 HMC-1 cells, which were derived from human mast cell leukemia, have 2 point mutations in the intracellular juxtamembrane domain (Val560Gly) and in the catalytic domain (Asp816Val) of the c-kit receptor. 2,6 The former mutation was also found in the c-kit receptor in cells from gastrointestinal stromal tumor (GIST), and the latter is known to exist most commonly in cells from human mastocytosis. 7,8 Because of these mutations, the tyrosine kinase of the c-kit receptor is automatically phosphorylated, and the related growth signal is activated. Several signaling molecules have been identified as candidates for transducing c-kit receptor signals, including mitogenactivated protein (MAP) kinase, phosphatidylinositol 3 (PI3) kinase, protein kinase C (PKC), and the Janus kinase/signal transducer and activator of transcription (JAK/STAT) pathways. [9][10][11] Recently available tyrosine kinase inhibitors have been applied to c-kit-dependent diseases, including GIST and mastocytosis; however, therapeutic effects have been limited in the treatment of mastocytosis in contrast to the great success in the treatment of GIST. [12][13][14] Mutational analysis has revealed some variants of the c-kit gene in patients with mastocytosis. Imatinib mesylate (STI571) was shown to be effective against mast cell diseases involving wild-type c-kit and mutants with Val560Gly or Phe522Cys substitutions. 14,15 However, STI571 was not effective against aggressive systemic mastocytosis involving an Asp816Val mutation in the c-kit receptor. 15 Homeostatic or nonhomeostatic cell renewal is controlled through cell cycle progression. Entry into the S phase normally relies on mitogenic stimulation, involving growth factors, and is regulated by cell cycle regulatory molecules, such as cyclins, cyclin-dependent kinases (CDKs), and a retinoblastoma protein (pRb). 16,17 D-type cyclins, namely cyclin D 1 , D 2 , and D 3 , are growth factor sensitive, and their expression is facilitated in response to growth factor stimulation. Byl binding with CDK4 and CDK6, D-type cyclins control a kinase activity of CDK and phosphorylate substrates that are required for G 1 progression and S phase entry. [18][19][20] One of their important targets is pRb. [18][19][20] We have already reported that the expression of cyclin D 3 and the phosphorylation of pRb are accelerated in mouse bone marrow-derived cultured mast cells (BMCMCs) incubated with stem cell factor (SCF), indicating that these regulatory molecules are essential for cell cycle progression in mast cell proliferation. 21 NF-B, a dimeric transcription factor of the rel family, exists as an inactive form in the cytoplasm by binding its endogenous Materials and methods Cell cultureHMC-1 cel...
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