Your search keyword '"90634931"' showing total 5 results

1. STING signalling is terminated through ESCRT-dependent microautophagy of vesicles originating from recycling endosomes

Author

90634931, Kuchitsu, Yoshihiko, Mukai, Kojiro, Uematsu, Rei, Takaada, Yuki, Shinojima, Ayumi, Shindo, Ruri, Shoji, Tsumugi, Hamano, Shiori, Ogawa, Emari, Sato, Ryota, Miyake, Kensuke, Kato, Akihisa, Kawaguchi, Yasushi, Nishitani-Isa, Masahiko, Izawa, Kazushi, Nishikomori, Ryuta, Yasumi, Takahiro, Suzuki, Takehiro, Dohmae, Naoshi, Uemura, Takefumi, Barber, Glen N., Arai, Hiroyuki, Waguri, Satoshi, Taguchi, Tomohiko, 90634931, Kuchitsu, Yoshihiko, Mukai, Kojiro, Uematsu, Rei, Takaada, Yuki, Shinojima, Ayumi, Shindo, Ruri, Shoji, Tsumugi, Hamano, Shiori, Ogawa, Emari, Sato, Ryota, Miyake, Kensuke, Kato, Akihisa, Kawaguchi, Yasushi, Nishitani-Isa, Masahiko, Izawa, Kazushi, Nishikomori, Ryuta, Yasumi, Takahiro, Suzuki, Takehiro, Dohmae, Naoshi, Uemura, Takefumi, Barber, Glen N., Arai, Hiroyuki, Waguri, Satoshi, and Taguchi, Tomohiko

Abstract

Stimulator of interferon genes (STING) is essential for the type I interferon response against a variety of DNA pathogens. Upon emergence of cytosolic DNA, STING translocates from the endoplasmic reticulum to the Golgi where STING activates the downstream kinase TBK1, then to lysosome through recycling endosomes (REs) for its degradation. Although the molecular machinery of STING activation is extensively studied and defined, the one underlying STING degradation and inactivation has not yet been fully elucidated. Here we show that STING is degraded by the endosomal sorting complexes required for transport (ESCRT)-driven microautophagy. Airyscan super-resolution microscopy and correlative light/electron microscopy suggest that STING-positive vesicles of an RE origin are directly encapsulated into Lamp1-positive compartments. Screening of mammalian Vps genes, the yeast homologues of which regulate Golgi-to-vacuole transport, shows that ESCRT proteins are essential for the STING encapsulation into Lamp1-positive compartments. Knockdown of Tsg101 and Vps4, components of ESCRT, results in the accumulation of STING vesicles in the cytosol, leading to the sustained type I interferon response. Knockdown of Tsg101 in human primary T cells leads to an increase the expression of interferon-stimulated genes. STING undergoes K63-linked ubiquitination at lysine 288 during its transit through the Golgi/REs, and this ubiquitination is required for STING degradation. Our results reveal a molecular mechanism that prevents hyperactivation of innate immune signalling, which operates at REs.

Published

2023

2. Trapping of CDC42 C-terminal variants in the Golgi drives pyrin inflammasome hyperactivation

Author

00869381, 00881301, 60773520, 90634931, 00359621, Nishitani-Isa, Masahiko, Mukai, Kojiro, Honda, Yoshitaka, Nihira, Hiroshi, Tanaka, Takayuki, Shibata, Hirofumi, Kodama, Kumi, Hiejima, Eitaro, Izawa, Kazushi, Kawasaki, Yuri, Osawa, Mitsujiro, Katata, Yu, Onodera, Sachiko, Watanabe, Tatsuya, Uchida, Takashi, Kure, Shigeo, Takita, Junko, Ohara, Osamu, Saito, Megumu K, Nishikomori, Ryuta, Taguchi, Tomohiko, Sasahara, Yoji, Yasumi, Takahiro, 00869381, 00881301, 60773520, 90634931, 00359621, Nishitani-Isa, Masahiko, Mukai, Kojiro, Honda, Yoshitaka, Nihira, Hiroshi, Tanaka, Takayuki, Shibata, Hirofumi, Kodama, Kumi, Hiejima, Eitaro, Izawa, Kazushi, Kawasaki, Yuri, Osawa, Mitsujiro, Katata, Yu, Onodera, Sachiko, Watanabe, Tatsuya, Uchida, Takashi, Kure, Shigeo, Takita, Junko, Ohara, Osamu, Saito, Megumu K, Nishikomori, Ryuta, Taguchi, Tomohiko, Sasahara, Yoji, and Yasumi, Takahiro

Published

2022

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Author

00881301, 50737880, 90634931, 60773520, 90335266, Muramoto, Yuya, Nihira, Hiroshi, Shiokawa, Masahiro, Izawa, Kazushi, Hiejima, Eitaro, Seno, Hiroshi, Japan Pediatric Inflammatory Bowel Disease Working Group, 00881301, 50737880, 90634931, 60773520, 90335266, Muramoto, Yuya, Nihira, Hiroshi, Shiokawa, Masahiro, Izawa, Kazushi, Hiejima, Eitaro, Seno, Hiroshi, and Japan Pediatric Inflammatory Bowel Disease Working Group

Published

2022

4. Accurate clinical genetic testing for autoinflammatory diseases using the next-generation sequencing platform MiSeq

Author

00511891, 90634931, Nakayama, Manabu, Oda, Hirotsugu, Nakagawa, Kenji, Yasumi, Takahiro, Kawai, Tomoki, Izawa, Kazushi, Nishikomori, Ryuta, Heike, Toshio, Ohara, Osamu, 00511891, 90634931, Nakayama, Manabu, Oda, Hirotsugu, Nakagawa, Kenji, Yasumi, Takahiro, Kawai, Tomoki, Izawa, Kazushi, Nishikomori, Ryuta, Heike, Toshio, and Ohara, Osamu

Abstract

Autoinflammatory diseases occupy one of a group of primary immunodeficiency diseases that are generally thought to be caused by mutation of genes responsible for innate immunity, rather than by acquired immunity. Mutations related to autoinflammatory diseases occur in 12 genes. For example, low-level somatic mosaic NLRP3 mutations underlie chronic infantile neurologic, cutaneous, articular syndrome (CINCA), also known as neonatal-onset multisystem inflammatory disease (NOMID). In current clinical practice, clinical genetic testing plays an important role in providing patients with quick, definite diagnoses. To increase the availability of such testing, low-cost high-throughput gene-analysis systems are required, ones that not only have the sensitivity to detect even low-level somatic mosaic mutations, but also can operate simply in a clinical setting. To this end, we developed a simple method that employs two-step tailed PCR and an NGS system, MiSeq platform, to detect mutations in all coding exons of the 12 genes responsible for autoinflammatory diseases. Using this amplicon sequencing system, we amplified a total of 234 amplicons derived from the 12 genes with multiplex PCR. This was done simultaneously and in one test tube. Each sample was distinguished by an index sequence of second PCR primers following PCR amplification. With our procedure and tips for reducing PCR amplification bias, we were able to analyze 12 genes from 25 clinical samples in one MiSeq run. Moreover, with the certified primers designed by our short program--which detects and avoids common SNPs in gene-specific PCR primers--we used this system for routine genetic testing. Our optimized procedure uses a simple protocol, which can easily be followed by virtually any office medical staff. Because of the small PCR amplification bias, we can analyze simultaneously several clinical DNA samples with low cost and can obtain sufficient read numbers to detect a low level of somatic mosaic mutations.

Published

2017

5. A Case with Spondyloenchondrodysplasia Treated with Growth Hormone

Author

90634931, 00869381, Utsumi, Takanori, Okada, Satoshi, Izawa, Kazushi, Honda, Yoshitaka, Nishimura, Gen, Nishikomori, Ryuta, Okano, Rika, Kobayashi, Masao, 90634931, 00869381, Utsumi, Takanori, Okada, Satoshi, Izawa, Kazushi, Honda, Yoshitaka, Nishimura, Gen, Nishikomori, Ryuta, Okano, Rika, and Kobayashi, Masao

Abstract

Spondyloenchondrodysplasia (SPENCD) is an autosomal recessive skeletal dysplasia caused by loss of function mutations in acid phosphatase 5, tartrate resistant (ACP5). Hypomorphic ACP5 mutations impair endochondral bone growth and create an interferon (INF) signature, which lead to distinctive spondylar and metaphyseal dysplasias, and extraskeletal morbidity, such as neurological involvement and immune dysregulation, respectively. We report an affected boy with novel ACP5 mutations, a splice-site mutation (736-2 A>C) and a nonsense mutation (R176X). He presented with postnatal short stature, which led to a diagnosis of partial growth hormone (GH) deficiency at 3 years of age. GH therapy was beneficial in accelerating his growth velocity. At 6 years of age, however, metaphyseal abnormalities of the knee attracted medical attention, and subsequent assessment ascertained the typical skeletal phenotype of SPENCD, brain calcifications, and an INF signature. This anecdotal experience indicates the potential efficacy of GH for growth failure in SPENCD.

Published

2017