ABSTRACT
Dysregulation of the DNA/RNA-binding protein FUS causes certain subtypes of ALS/FTD by largely unknown mechanisms. Recent evidence has shown that FUS toxic gain of function due either to mutations or to increased expression can disrupt critical cellular processes, including mitochondrial functions. Here, we demonstrate that in human cells overexpressing wild-type FUS or expressing mutant derivatives, the protein associates with multiple mRNAs, and these are enriched in mRNAs encoding mitochondrial respiratory chain components. Notably, this sequestration leads to reduced levels of the encoded proteins, which is sufficient to bring about disorganized mitochondrial networks, reduced aerobic respiration and increased reactive oxygen species. We further show that mutant FUS associates with mitochondria and with mRNAs encoded by the mitochondrial genome. Importantly, similar results were also observed in fibroblasts derived from ALS patients with FUS mutations. Finally, we demonstrate that FUS loss of function does not underlie the observed mitochondrial dysfunction, and also provides a mechanism for the preferential sequestration of the respiratory chain complex mRNAs by FUS that does not involve sequence-specific binding. Together, our data reveal that respiratory chain complex mRNA sequestration underlies the mitochondrial defects characteristic of ALS/FTD and contributes to the FUS toxic gain of function linked to this disease spectrum.
Subject(s)
Amyotrophic Lateral Sclerosis/genetics , Amyotrophic Lateral Sclerosis/physiopathology , Gene Expression Regulation/genetics , Mitochondria/pathology , RNA, Messenger/metabolism , RNA-Binding Protein FUS/genetics , RNA-Binding Protein FUS/metabolism , Cell Line , Cell Respiration/genetics , Cells, Cultured , Electron Transport/genetics , Genome, Mitochondrial , Humans , Mitochondria/genetics , Mutation , Protein Aggregation, Pathological/genetics , Protein Binding/geneticsABSTRACT
Ribosome structure and activity are challenged at high temperatures, often demanding modifications to ribosomal RNAs (rRNAs) to retain translation fidelity. LC-MS/MS, bisulfite-sequencing, and high-resolution cryo-EM structures of the archaeal ribosome identified an RNA modification, N4,N4-dimethylcytidine (m42C), at the universally conserved C918 in the 16S rRNA helix 31 loop. Here, we characterize and structurally resolve a class of RNA methyltransferase that generates m42C whose function is critical for hyperthermophilic growth. m42C is synthesized by the activity of a unique family of RNA methyltransferase containing a Rossman-fold that targets only intact ribosomes. The phylogenetic distribution of the newly identified m42C synthase family implies that m42C is biologically relevant in each domain. Resistance of m42C to bisulfite-driven deamination suggests that efforts to capture m5C profiles via bisulfite sequencing are also capturing m42C.
Subject(s)
Cytidine , Ribosomes , Cytidine/analogs & derivatives , Cytidine/metabolism , Cytidine/chemistry , Ribosomes/metabolism , Methyltransferases/metabolism , Methyltransferases/genetics , Methyltransferases/chemistry , Archaea/genetics , Archaea/metabolism , RNA, Ribosomal, 16S/genetics , RNA, Ribosomal, 16S/metabolism , Archaeal Proteins/metabolism , Archaeal Proteins/genetics , Archaeal Proteins/chemistry , Phylogeny , RNA, Archaeal/genetics , RNA, Archaeal/metabolism , RNA, Archaeal/chemistryABSTRACT
The COVID-19 pandemic has had an unprecedented impact on society, especially in densely populated areas. Schools have implemented distance learning, which has spawned many related problems. This paper focuses on the difficulties arising from the epidemic in indigenous communities and how appropriate information strategies may be used to solve these. Four main suggestions are provided to assist indigenous students and their teachers to protect themselves and learn during the pandemic and to ensure that educational goals are achieved.
Subject(s)
COVID-19 , Education, Distance , Humans , Pandemics , Students , LearningABSTRACT
Firefly luminescence is an intriguing phenomenon with potential technological applications, whose biochemistry background was only recently established. The physics side of this phenomenon, however, was still unclear, specifically as far as the oxygen supply mechanism for light flashing is concerned. This uncertainty is due to the complex microscopic structure of the tracheal system: without fully knowing its geometry, one cannot reliably test the proposed mechanisms. We solved this problem using synchrotron phase contrast microtomography and transmission x-ray microscopy, finding that the oxygen consumption corresponding to mitochondria functions exceeds the maximum rate of oxygen diffusion from the tracheal system to the photocytes. Furthermore, the flashing mechanism uses a large portion of this maximum rate. Thus, the flashing control requires passivation of the mitochondria functions, e.g., by nitric oxide, and switching of the oxygen supply from them to photoluminescence.
Subject(s)
Fireflies/metabolism , Oxygen/metabolism , Animals , Luminescence , Mitochondria/metabolism , Nitric Oxide/metabolism , Oxygen Consumption , X-Ray Microtomography/methodsABSTRACT
RNAs are often modified to invoke new activities. While many modifications are limited in frequency, restricted to non-coding RNAs, or present only in select organisms, 5-methylcytidine (m5C) is abundant across diverse RNAs and fitness-relevant across Domains of life, but the synthesis and impacts of m5C have yet to be fully investigated. Here, we map m5C in the model hyperthermophile, Thermococcus kodakarensis. We demonstrate that m5C is ~25x more abundant in T. kodakarensis than human cells, and the m5C epitranscriptome includes ~10% of unique transcripts. T. kodakarensis rRNAs harbor tenfold more m5C compared to Eukarya or Bacteria. We identify at least five RNA m5C methyltransferases (R5CMTs), and strains deleted for individual R5CMTs lack site-specific m5C modifications that limit hyperthermophilic growth. We show that m5C is likely generated through partial redundancy in target sites among R5CMTs. The complexity of the m5C epitranscriptome in T. kodakarensis argues that m5C supports life in the extremes.
Subject(s)
Cytidine , Methyltransferases , Thermococcus , Transcriptome , Thermococcus/genetics , Thermococcus/metabolism , Thermococcus/enzymology , Methyltransferases/metabolism , Methyltransferases/genetics , Cytidine/metabolism , Cytidine/analogs & derivatives , Cytidine/genetics , Humans , RNA, Archaeal/genetics , RNA, Archaeal/metabolism , Archaeal Proteins/metabolism , Archaeal Proteins/genetics , RNA, Ribosomal/metabolism , RNA, Ribosomal/geneticsABSTRACT
Fused in Sarcoma (FUS) is a nuclear RNA/DNA binding protein that mislocalizes to the cytoplasm in the neurodegenerative diseases ALS and FTD. Despite the existence of FUS pathogenic mutations that result in nuclear import defects, a subset of ALS/FTD patients display cytoplasmic accumulation of wild-type FUS, although the underlying mechanism is unclear. Here we confirm that transcriptional inhibition, specifically of RNA polymerase II (RNAP II), induces FUS cytoplasmic translocation, but we show that several other stresses do not. We found unexpectedly that the epitope specificity of different FUS antibodies significantly affects the apparent FUS nucleocytoplasmic ratio as determined by immunofluorescence, explaining inconsistent observations in previous studies. Significantly, depletion of the nuclear mRNA export factor NXF1 or RNA exosome cofactor MTR4 promotes FUS nuclear retention, even when transcription is repressed, while mislocalization was independent of the nuclear protein export factor CRM1 and import factor TNPO1. Finally, we report that levels of nascent RNAP II transcripts, including those known to bind FUS, are reduced in sporadic ALS iPS cells, linking possible aberrant transcriptional control and FUS cytoplasmic mislocalization. Our findings thus reveal that factors that influence accumulation of nuclear RNAP II transcripts modulate FUS nucleocytoplasmic homeostasis, and provide evidence that reduced RNAP II transcription can contribute to FUS mislocalization to the cytoplasm in ALS.
Subject(s)
Amyotrophic Lateral Sclerosis , Frontotemporal Dementia , RNA-Binding Protein FUS , Amyotrophic Lateral Sclerosis/genetics , Amyotrophic Lateral Sclerosis/metabolism , Cytoplasm/metabolism , Frontotemporal Dementia/genetics , Frontotemporal Dementia/metabolism , Humans , Mutation , RNA, Nuclear/genetics , RNA, Nuclear/metabolism , RNA-Binding Protein FUS/genetics , RNA-Binding Protein FUS/metabolismABSTRACT
Amyotrophic Lateral Sclerosis (ALS) is a deadly neuromuscular disorder caused by progressive motor neuron loss in the brain and spinal cord. Over the past decades, a number of genetic mutations have been identified that cause or are associated with ALS disease progression. Numerous genes harbor ALS mutations, and they encode proteins displaying a wide range of physiological functions, with limited overlap. Despite the divergent functions, mutations in these genes typically trigger protein aggregation, which can confer gain- and/or loss-of-function to a number of essential cellular processes. Nuclear processes such as mRNA splicing and the response to DNA damage are significantly affected in ALS patients. Cytoplasmic organelles such as mitochondria are damaged by ALS mutant proteins. Processes that maintain cellular homeostasis such as autophagy, nonsense-mediated mRNA decay and nucleocytoplasmic transport, are also impaired by ALS mutations. Here, we review the multiple mechanisms by which mutations in major ALS-associated genes, such as TARDBP, C9ORF72 and FUS, lead to impairment of essential cellular processes.
Subject(s)
Amyotrophic Lateral Sclerosis/genetics , C9orf72 Protein/genetics , Cell Death/physiology , DNA-Binding Proteins/genetics , Mutation/physiology , RNA-Binding Protein FUS/genetics , Amyotrophic Lateral Sclerosis/metabolism , Amyotrophic Lateral Sclerosis/pathology , Animals , Autophagy/physiology , C9orf72 Protein/metabolism , DNA Damage/physiology , DNA-Binding Proteins/metabolism , Humans , RNA-Binding Protein FUS/metabolismABSTRACT
SETX (senataxin) is an RNA/DNA helicase that has been implicated in transcriptional regulation and the DNA damage response through resolution of R-loop structures. Mutations in SETX result in either of two distinct neurodegenerative disorders. SETX dominant mutations result in a juvenile form of amyotrophic lateral sclerosis (ALS) called ALS4, whereas recessive mutations are responsible for ataxia called ataxia with oculomotor apraxia type 2 (AOA2). How mutations in the same protein can lead to different phenotypes is still unclear. To elucidate AOA2 disease mechanisms, we first examined gene expression changes following SETX depletion. We observed the effects on both transcription and RNA processing, but surprisingly observed decreased R-loop accumulation in SETX-depleted cells. Importantly, we discovered a strong connection between SETX and the macroautophagy/autophagy pathway, reflecting a direct effect on transcription of autophagy genes. We show that SETX depletion inhibits the progression of autophagy, leading to an accumulation of ubiquitinated proteins, decreased ability to clear protein aggregates, as well as mitochondrial defects. Analysis of AOA2 patient fibroblasts also revealed a perturbation of the autophagy pathway. Our work has thus identified a novel function for SETX in the regulation of autophagy, whose modulation may have a therapeutic impact for AOA2.Abbreviations: 3'READS: 3' region extraction and deep sequencing; ACTB: actin beta; ALS4: amyotrophic lateral sclerosis type 4; AOA2: ataxia with oculomotor apraxia type 2; APA: alternative polyadenylation; AS: alternative splicing; ATG7: autophagy-related 7; ATP6V0D2: ATPase H+ transporting V0 subunit D2; BAF: bafilomycin A1; BECN1: beclin 1; ChIP: chromatin IP; Chloro: chloroquine; CPT: camptothecin; DDR: DNA damage response; DNMT1: DNA methyltransferase 1; DRIP: DNA/RNA IP; DSBs: double strand breaks; EBs: embryoid bodies; FTD: frontotemporal dementia; GABARAP: GABA type A receptor-associated protein; GO: gene ontology; HR: homologous recombination; HTT: huntingtin; IF: immunofluorescence; IP: immunoprecipitation; iPSCs: induced pluripotent stem cells; KD: knockdown; MAP1LC3/LC3: microtubule associated protein 1 light chain 3; MN: motor neuron; MTORC1: mechanistic target of rapamycin kinase complex 1; PASS: PolyA Site Supporting; PFA: paraformaldehyde; RNAPII: RNA polymerase II; SCA: spinocerebellar ataxia; SETX: senataxin; SMA: spinal muscular atrophy; SMN1: survival of motor neuron 1, telomeric; SQSTM1/p62: sequestosome 1; TFEB: transcription factor EB; TSS: transcription start site; TTS: transcription termination site; ULK1: unc-51 like autophagy activating kinase 1; WB: western blot; WIPI2: WD repeat domain, phosphoinositide interacting 2; XRN2: 5'-3' exoribonuclease 2.
Subject(s)
Amyotrophic Lateral Sclerosis/metabolism , Autophagy/physiology , DNA Helicases/metabolism , Multifunctional Enzymes/metabolism , RNA Helicases/metabolism , Gene Expression Regulation/genetics , Humans , Motor Neurons/metabolismABSTRACT
BACKGROUND: The preferential occurrence of certain skin neoplasms on the scalp of children raises concerns from their parents and warrants special diagnostic and therapeutic approaches. OBJECTIVE: To explore the demographic and clinical characteristics of scalp neoplasms in the pediatric population, with attention to malignant tumors and systemic syndromes. METHODS: Scalp neoplasms in patients aged 12 years or younger were retrospectively collected in 1990-2010 from two tertiary referral centers in Taiwan. RESULTS: A total of 267 scalp neoplasms in 265 pediatric patients were recruited. Among the 209 neoplasms with a histopathological diagnosis, nevus sebaceus was the most common (67.9%), followed by melanocytic nevus (6.2%) and juvenile xanthogranuloma (6.2%). Most of the scalp neoplasms (77.9%) were seen at birth or before 1 month of age. Infantile hemangioma was clinically diagnosed without histology in 41.4% of cases. Malignant scalp tumors were identified in two patients (0.95%), with one basal cell carcinoma and one precursor B-cell lymphoblastic lymphoma, respectively. Scalp neoplasms in association with systemic syndromes were found in two cases. One had neurofibromatosis type I with juvenile xanthogranuloma and the other basal cell nevus syndrome with basal cell carcinoma. CONCLUSIONS: Most pediatric scalp neoplasms in our study were hamartomas or teratomas. Malignant scalp tumors and malignant transformation of nevus sebaceus were rare. A detailed medical history taking and complete physical examinations are needed to exclude possible associations with systemic syndromes or malignancies.