Satoshi Yamashita scite author profile

Analyzing the type and frequency of patient-specific mutations that give rise to Duchenne muscular dystrophy (DMD) is an invaluable tool for diagnostics, basic scientific research, trial planning, and improved clinical care. Locus-specific databases allow for the collection, organization, storage, and analysis of genetic variants of disease. Here, we describe the development and analysis of the TREAT-NMD DMD Global database (http://umd.be/TREAT_DMD/). We analyzed genetic data for 7,149 DMD mutations held within the database. A total of 5,682 large mutations were observed (80% of total mutations), of which 4,894 (86%) were deletions (1 exon or larger) and 784 (14%) were duplications (1 exon or larger). There were 1,445 small mutations (smaller than 1 exon, 20% of all mutations), of which 358 (25%) were small deletions and 132 (9%) small insertions and 199 (14%) affected the splice sites. Point mutations totalled 756 (52% of small mutations) with 726 (50%) nonsense mutations and 30 (2%) missense mutations. Finally, 22 (0.3%) mid-intronic mutations were observed. In addition, mutations were identified within the database that would potentially benefit from novel genetic therapies for DMD including stop codon read-through therapies (10% of total mutations) and exon skipping therapy (80% of deletions and 55% of total mutations).

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MicroRNA-140 plays dual roles in both cartilage development and homeostasis

Miyaki

Sato²,

Inoue³

et al. 2010

Genes Dev.

482

483

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Osteoarthritis (OA), the most prevalent aging-related joint disease, is characterized by insufficient extracellular matrix synthesis and articular cartilage degradation, mediated by several proteinases, including Adamts-5. miR-140 is one of a very limited number of noncoding microRNAs (miRNAs) specifically expressed in cartilage; however, its role in development and/or tissue maintenance is largely uncharacterized. To examine miR-140 function in tissue development and homeostasis, we generated a mouse line through a targeted deletion of miR-140. miR-140−/− mice manifested a mild skeletal phenotype with a short stature, although the structure of the articular joint cartilage appeared grossly normal in 1-mo-old miR-140−/− mice. Interestingly, miR-140−/− mice showed age-related OA-like changes characterized by proteoglycan loss and fibrillation of articular cartilage. Conversely, transgenic (TG) mice overexpressing miR-140 in cartilage were resistant to antigen-induced arthritis. OA-like changes in miR-140-deficient mice can be attributed, in part, to elevated Adamts-5 expression, regulated directly by miR-140. We show that miR-140 regulates cartilage development and homeostasis, and its loss contributes to the development of age-related OA-like changes.

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Spinal cord endoplasmic reticulum stress associated with a microsomal accumulation of mutant superoxide dismutase-1 in an ALS model

Kikuchi

Almer

Yamashita

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

269

222

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Mutation in superoxide dismutase-1 (SOD1), which is a cause of ALS, alters the folding patterns of this protein. Accumulation of misfolded mutant SOD1 might activate endoplasmic reticulum (ER) stress pathways. Here we show that transgenic mice expressing ALS-linked SOD1 mutants exhibit molecular alterations indicative of a recruitment of ER's signaling machinery. We demonstrate by biochemical and morphological methods that mutant SOD1 accumulates inside the ER, where it forms insoluble high molecular weight species and interacts with the ER chaperone immunoglobulin-binding protein. These alterations are age-and regionspecific, because they develop over the course of the disease and occur in the affected spinal cord but not in the nonaffected cerebellum in transgenic mutant SOD1 mice. Our results suggest a toxic mechanism for mutant SOD1 by which this ubiquitously expressed pathogenic protein could affect motor neuron survival and contribute to the selective motor neuronal degeneration in ALS.neurodegeneration ͉ protein misfolding A LS is the most common adult-onset paralytic disease characterized by a loss of motor neurons in the cerebral cortex, brainstem, and spinal cord. Insights into the neurodegenerative mechanisms followed the discovery that dominant mutations in the gene for superoxide dismutase-1 (SOD1) cause familial ALS. Overexpression of SOD1 mutants in rodents recapitulates ALS clinical and pathological hallmarks through a toxic gain of function (1). Many mutations in SOD1 decrease its stability and increase its unfolding rates and propensity to aggregate (2). High molecular weight complexes of SOD1 are observed in mammalian cells and spinal cords of transgenic mice expressing this mutant protein (3). In these animals, intracellular ubiquitin-positive proteinaceous inclusions are also often seen in spinal cord motor neurons and, in some cases, in neighboring astrocytes (3-5). These findings posit that accumulation of misfolded mutant SOD1 could contribute to the demise of motor neurons.Endoplasmic reticulum (ER) stress signaling, otherwise known as the unfolded protein response (UPR), is triggered by an increased load of misfolded proteins in the organelle (6). Herein, we show that transgenic mice expressing mutant SOD1 exhibit age-and region-specific molecular alterations indicative of a broad recruitment of ER signaling pathways, including caspase-12, a prototypical ER cell death effector (7). We also show that mutant SOD1, and to a lesser extent wild-type SOD1 (SOD1 WT ), do accumulate in the ER. Within this organelle, mutant, but not SOD1 WT , forms high molecular weight species and interacts with the ER chaperone immunoglobulin-binding protein (BiP), which is a key component of the ER misfolded protein recognition machinery (6). The preferential accumulation of mutant SOD1 in the ER in the spinal cord cells and the ensuing stress response may represent novel aspects of motor neuron degeneration in this ALS model.

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Efficient and Reproducible Myogenic Differentiation from Human iPS Cells: Prospects for Modeling Miyoshi Myopathy In Vitro

Tanaka

Woltjen

Miyake

et al. 2013

PLoS ONEHas correction 2013-12-20

181

209

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The establishment of human induced pluripotent stem cells (hiPSCs) has enabled the production of in vitro, patient-specific cell models of human disease. In vitro recreation of disease pathology from patient-derived hiPSCs depends on efficient differentiation protocols producing relevant adult cell types. However, myogenic differentiation of hiPSCs has faced obstacles, namely, low efficiency and/or poor reproducibility. Here, we report the rapid, efficient, and reproducible differentiation of hiPSCs into mature myocytes. We demonstrated that inducible expression of myogenic differentiation1 (MYOD1) in immature hiPSCs for at least 5 days drives cells along the myogenic lineage, with efficiencies reaching 70–90%. Myogenic differentiation driven by MYOD1 occurred even in immature, almost completely undifferentiated hiPSCs, without mesodermal transition. Myocytes induced in this manner reach maturity within 2 weeks of differentiation as assessed by marker gene expression and functional properties, including in vitro and in vivo cell fusion and twitching in response to electrical stimulation. Miyoshi Myopathy (MM) is a congenital distal myopathy caused by defective muscle membrane repair due to mutations in DYSFERLIN. Using our induced differentiation technique, we successfully recreated the pathological condition of MM in vitro, demonstrating defective membrane repair in hiPSC-derived myotubes from an MM patient and phenotypic rescue by expression of full-length DYSFERLIN (DYSF). These findings not only facilitate the pathological investigation of MM, but could potentially be applied in modeling of other human muscular diseases by using patient-derived hiPSCs.

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Chemical genomic screening for methylation-silenced genes in gastric cancer cell lines using 5-aza-2'-deoxycytidine treatment and oligonucleotide microarray

Yamashita

Yamashita²,

Tsujino³

et al. 2006

Cancer Science

220

177

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To identify novel methylation-silenced genes in gastric cancers, we carried out a chemical genomic screening, a genome-wide search for genes upregulated by treatment with a demethylating agent, 5-aza-2′ ′ ′ ′-deoxycytidine (5-aza-dC). After 5-aza-dC treatment of a gastric cancer cell line (AGS) 579 genes were upregulated 16-fold or more, using an oligonucleotide microarray with 39 000 genes. From these genes, we selected 44 known genes on autosomes whose silencing in gastric cancer has not been reported. Thirty-two of these had CpG islands (CGI) in their putative promoter regions, and all of the CGI were methylated in AGS, giving an estimated number of 421 ± ± ± ± 75 (95% confidence interval) methylation-silenced genes. Additionally, we analyzed the methylation status of 16 potential tumor-related genes with promoter CGI that were upregulated four-fold or more, and 14 of these were methylated in AGS. Methylation status of the 32 randomly selected and 16 potential tumor-related genes was analyzed in 10 primary gastric cancers, and 42 genes (ABHD9 , ADFP, ALDH1A3, ANXA5, AREG, BDNF, BMP7, CAV1, CDH2, CLDN3, CTSL, EEF1A2, F2R, FADS1, FSD1, FST, FYN, GPR54, GREM1, IGFBP3, IGFBP7, IRS2, KISS1, MARK1, MLF1, MSX1, MTSS1, NT5E, PAX6, PLAGL1, PLAU, PPIC, RBP4, RORA, SCRN1, TBX3, TFAP2C, TNFSF9, (1) In various human cancers, silencing of tumorsuppressor genes, such as CDKN2A (p16), CDH1 (Ecadherin) and MLH1, is known to be one of the major mechanisms for their inactivation, along with mutations and LOH. To identify genes silenced by promoter methylation by genome-wide screenings, various techniques have been developed.(2) Most techniques are based on the methylation status of genomic DNA, including MS-RDA and restriction landmark genomic scanning. In contrast, Suzuki et al. developed a technique that screens genes re-expressed after treatment with a demethylating agent, 5-aza-dC, using a microarray.(3) The chemical genomic screening technique is simple and is effective in identifying genes silenced in cell lines. It has been applied to colon, bladder, esophageal, pancreatic and prostate cancers.Gastric cancer is the second most common cause of cancer death in the world.(8) As its molecular basis, deep involvement of aberrant DNA methylation has been indicated by the higher incidences of aberrant DNA methylation of known tumorsuppressor genes than of mutations.(9) We previously searched for genes silenced in MKN28 and MKN74 cell lines using MS-RDA, (10) and identified lysyl oxidase as a novel tumorsuppressor gene.(11) However, the entire picture of methylation-silenced genes in gastric cancers is still unclear, and further searches for methylation-silenced genes are necessary.In the present study, we carried out a chemical genomic screening of methylation-silenced genes in the human gastric cancer cell line AGS.

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Rapid generation of mouse models with defined point mutations by the CRISPR/Cas9 system

Inui¹,

Miyado²,

Igarashi³

et al. 2014

Sci Rep

177

161

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Introducing a point mutation is a fundamental method used to demonstrate the roles of particular nucleotides or amino acids in the genetic elements or proteins, and is widely used in in vitro experiments based on cultured cells and exogenously provided DNA. However, the in vivo application of this approach by modifying genomic loci is uncommon, partly due to its technical and temporal demands. This leaves many in vitro findings un-validated under in vivo conditions. We herein applied the CRISPR/Cas9 system to generate mice with point mutations in their genomes, which led to single amino acid substitutions in proteins of interest. By microinjecting gRNA, hCas9 mRNA and single-stranded donor oligonucleotides (ssODN) into mouse zygotes, we introduced defined genomic modifications in their genome with a low cost and in a short time. Both single gRNA/WT hCas9 and double nicking set-ups were effective. We also found that the distance between the modification site and gRNA target site was a significant parameter affecting the efficiency of the substitution. We believe that this is a powerful technique that can be used to examine the relevance of in vitro findings, as well as the mutations found in patients with genetic disorders, in an in vivo system.

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FrequentPTPRK-RSPO3fusions andRNF43mutations in colorectal traditional serrated adenoma

Sekine¹,

Yamashita

et al. 2016

J. Pathol.

128

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The molecular mechanisms underlying the serrated pathway of colorectal tumourigenesis, particularly those related to traditional serrated adenomas (TSAs), are still poorly understood. In this study, we analysed genetic alterations in 188 colorectal polyps, including hyperplastic polyps, sessile serrated adenomas/polyps (SSA/Ps), TSAs, tubular adenomas, and tubulovillous adenomas by using targeted next-generation sequencing and reverse transcription-PCR. Our analyses showed that most TSAs (71%) contained genetic alterations in WNT pathway components. In particular, PTPRK-RSPO3 fusions (31%) and RNF43 mutations (24%) were frequently and almost exclusively observed in TSAs. Consistent with the WNT pathway activation, immunohistochemical analysis showed diffuse and focal nuclear accumulation of β-catenin in 53% and 30% of TSAs, respectively. APC mutations were observed in tubular and tubulovillous adenomas and in a subset of TSAs. BRAF mutations were exclusively and frequently encountered in serrated lesions. KRAS mutations were observed in all types of polyps, but were most commonly encountered in tubulovillous adenomas and TSAs. This study has demonstrated that TSAs frequently harbour genetic alterations that lead to WNT pathway activation, in addition to BRAF and KRAS mutations. In particular, PTPRK-RSPO3 fusions and RNF43 mutations were found to be characteristic genetic features of TSAs. Copyright © 2016 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.

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A Systems Approach Reveals that the Myogenesis Genome Network Is Regulated by the Transcriptional Repressor RP58

Yokoyama¹,

Ito²,

Ueno-Kudoh³

et al. 2009

Developmental Cell

127

134

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SUMMARY We created a whole-mount in situ hybridization (WISH) database, termed EMBRYS, containing expression data of 1520 transcription factors and cofactors expressed in E9.5, E10.5, and E11.5 mouse embryos—a highly dynamic stage of skeletal myogenesis. This approach implicated 43 genes in regulation of embryonic myogenesis, including a transcriptional repressor, the zinc-finger protein RP58 (also known as Zfp238). Knockout and knockdown approaches confirmed an essential role for RP58 in skeletal myogenesis. Cell-based high-throughput transfection screening revealed that RP58 is a direct MyoD target. Microarray analysis identified two inhibitors of skeletal myogenesis, Id2 and Id3, as targets for RP58-mediated repression. Consistently, MyoD-dependent activation of the myogenic program is impaired in RP58 null fibroblasts and downregulation of Id2 and Id3 rescues MyoD’s ability to promote myogenesis in these cells. Our combined, multi-system approach reveals a MyoD-activated regulatory loop relying on RP58-mediated repression of muscle regulatory factor (MRF) inhibitors.

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