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1 e with the ability to activate pre-messenger RNA splicing.
2 ene expression, chromatin accessibility, and RNA splicing.
3 chromatin remodeler could indirectly affect RNA splicing.
4 vesicular trafficking, DNA damage repair and RNA splicing.
5 reviously implicated in the control of HIV-1 RNA splicing.
6 ydroxyvitamin D (1,25(OH)2D) with subsequent RNA splicing.
7 etain function due to their direct impact on RNA splicing.
8 w role for this central kinase in regulating RNA splicing.
9 B cell receptors (BCRs) through alternative RNA splicing.
10 ived from this individual show altered UPF3B RNA splicing.
11 while not impairing full-length SON-mediated RNA splicing.
12 proteins involved in nucleotide binding and RNA splicing.
13 abundance of several proteins that regulate RNA splicing.
14 ticipated in rapalog-induced deregulation of RNA splicing.
15 ld maintain function through their impact on RNA splicing.
16 cripts resulting from erroneous SON-mediated RNA splicing.
17 nELAVL target binding, and altered neuronal RNA splicing.
18 nition factor U2AF1 alter its normal role in RNA splicing.
19 liceosome before the first catalytic step of RNA splicing.
20 d, and many disease-causing mutations affect RNA splicing.
21 nd-to-last nucleotide of exon 2 and possibly RNA splicing.
22 omplex genes, via aberrant transcription and RNA splicing.
23 ir C termini as a consequence of alternative RNA splicing.
24 of RNA metabolism that control premessenger RNA splicing.
25 l role in RNA metabolism by facilitating pre-RNA splicing.
26 tophagy, global transcriptional control, and RNA splicing.
27 trimethylation, nucleosome positioning, and RNA splicing.
28 hibiting T cell activation and by modulating RNA splicing.
29 failure, presumably through altering cardiac RNA splicing.
30 icases, we examined cancer-specific roles in RNA splicing.
31 ylation at splice acceptor sites may inhibit RNA splicing.
32 o humans that are reported to have a role in RNA splicing.
33 ns are orthologues of proteins implicated in RNA splicing.
34 ed to regulate gene expression by modulating RNA splicing.
35 support the potential link between HDACs and RNA splicing.
36 nt both SRSF3 degradation and alterations in RNA splicing.
37 ugh coordinated effects on the epigenome and RNA splicing.
38 the complex and tightly regulated process of RNA splicing.
39 in the same RNA sequence when joined through RNA splicing.
40 expression cassette to prevent its loss from RNA splicing.
41 , introns are removed through the process of RNA splicing.
42 AR-FL and AR-V proteins without altering AR RNA splicing.
43 -requiring enzyme 1alpha-dependent messenger RNA splicing (activation) of X-box-binding protein-1 (XB
48 -mutant tumours have significantly disrupted RNA splicing and an excess of 5' cryptic splicing events
49 s (RTs) function in both intron mobility and RNA splicing and are evolutionary predecessors of retrot
52 rylation sites involved in transcription and RNA splicing and decreased abundance of enzymes in lipid
53 f histone/protein modifications and HDACs in RNA splicing and discuss the convergence of two parallel
54 rewiring of the transcriptome that involved RNA splicing and enriched for targets of RNA binding pro
55 ovel pathways in MDS pathogenesis, including RNA splicing and epigenetic regulation of gene expressio
56 e data identify a specific role for ZRSR2 in RNA splicing and highlight dysregulated splicing of U12-
58 s and reduced synaptic signaling and between RNA splicing and increased oligodendrocyte development a
59 criptase, which function together to promote RNA splicing and intron mobility via reverse splicing of
60 role in the regulation of malarial parasite RNA splicing and is essential for the survival of blood
61 ermined that RBFox1 is a potent regulator of RNA splicing and is required for a conserved splicing pr
62 itination at damaged DNA, but also regulates RNA splicing and mitotic spindle formation in its integr
63 as cellular maintenance pathways, including RNA splicing and nuclear-cytoplasmic transport have been
64 These tumor-specific mutations alter UPF1 RNA splicing and perturb NMD, leading to upregulated lev
66 lions of protein variants due to alternative RNA splicing and post-translational modifications, and v
68 in a variety of cellular processes including RNA splicing and resistance to agents that cause DNA int
72 f a deep connection between the mechanism of RNA splicing and small-RNA-mediated gene silencing, the
73 ved in other functions such as modulation of RNA splicing and specific regulation of gene expression,
78 insights into cell type-specific control of RNA splicing and underscores the importance of consideri
79 ng causes of aberrant HDACs and dysregulated RNA splicing and, thus, further support the potential li
81 ively, these studies reveal ZMAT3 as a novel RNA-splicing and homeostasis regulator and a key compone
82 utionalized' for non-conflict roles, e.g. in RNA-splicing and in RNAi systems (e.g. in kinetoplastids
83 Three variants were not predicted to alter RNA splicing, and 13 essential splice dinucleotide, nons
85 sequencing confirmed the effect of hDBR1 on RNA splicing, and metabolite profiling supported the obs
87 imate link across telomere biology, aberrant RNA splicing, and myeloid progenitor differentiation.
88 d minor spliceosome, the factors controlling RNA splicing, and the role of alternative splicing in ca
90 roteins resulting in disruption of messenger RNA splicing; and (ii) licensing of expanded C9orf72 pre
93 t the regulations of cellular mRNA decay and RNA splicing are compromised by Zika virus infection as
94 ions, genomic rearrangements, and defects in RNA splicing are included among the most sensitive acces
95 al process of gene regulation, and errors in RNA splicing are known to be associated with a variety o
101 to downregulate gene expression or to modify RNA splicing, but antisense technology has not previousl
102 ols (odds ratio 1.26-1.9); it did not affect RNA splicing, but it was in strong linkage disequilibriu
103 at inhibition of transcription initiation or RNA splicing, but not translation, leads to spindle defe
104 RNA and influences both gene expression and RNA splicing, but these actions do not appear to be link
105 provide new insights into the regulation of RNA splicing by Akt isoforms through phosphorylation of
106 also establish a role for Myc in regulating RNA splicing by controlling the incorporation of nonsens
107 ogether, this study identifies regulation of RNA splicing by RBFox1 as an important player in transcr
108 The effect of the c.5461-10T-->C variant on RNA splicing by reverse-transcription polymerase chain r
111 anscriptional regulation, DNA damage repair, RNA splicing, cell differentiation, and metastasis.
112 l program and activating genes essential for RNA splicing, cell migration, controlled cellular prolif
114 MCPs of RPL13, a ribosomal gene and SON, an RNA splicing cofactor, reduced proliferation and differe
115 ing chromatin modification, DNA methylation, RNA splicing, cohesin complex, transcription factors, ce
118 Consistent with the central role of CWC15 in RNA splicing, cwc15 mutants are embryo lethal and additi
120 re, we characterize previously uncategorized RNA splicing defects involving widespread intron retenti
123 tions, typically affecting genes involved in RNA splicing, dictate future trajectories of disease evo
124 ons of cancer cell lines to include genetic, RNA splicing, DNA methylation, histone H3 modification,
125 identified mutations in genes implicated in RNA splicing, DNA modification, chromatin regulation, an
126 ion-induced joined neoantigen (NINJA), using RNA splicing, DNA recombination and three levels of regu
128 trates and is involved in DNA transcription, RNA splicing, DNA repair, cell differentiation, and meta
131 SRSF3 expression was similarly decreased and RNA splicing dysregulated in mouse models of NAFLD and N
132 been shown to sequester proteins involved in RNA splicing, editing, nuclear export and nucleolar func
133 ere, we uncover sequence-specific changes in RNA splicing enforced by mutant p53 which enhance KRAS a
135 al protein kinase (PK)/ribonuclease, IRE1, a RNA splicing enzyme, and another involving membrane-asso
136 ited number of cellular processes, including RNA splicing, epigenetic and traditional transcriptional
138 ce variants demonstrated a key role for this RNA splicing event in the resistance of cells to anoikis
139 we identify novel genome-wide, race-specific RNA splicing events as critical drivers of PCa aggressiv
140 covering and quantifying circular and linear RNA splicing events at both annotated and un-annotated e
144 round Variants in the cardiomyocyte-specific RNA splicing factor RBM20 have been linked to familial c
146 , we report that SON, previously known as an RNA splicing factor, controls MLL complex-mediated trans
147 PER 17 (bZIP17), and the membrane-associated RNA splicing factor, INOSITOL REQUIRING ENZYME1 (IRE1).
148 st report suggesting that MCM7 is a critical RNA splicing factor, thus giving significant new insight
150 olyglutamine-binding protein 1 (PQBP1) is an RNA-splicing factor that, when mutated, in humans causes
151 ancer-associated mutations in genes encoding RNA splicing factors (SFs) commonly occur in leukemias,
153 QKI-7 expression is tightly controlled by RNA splicing factors CUG-BP and hnRNPM through direct bi
154 ontaining non-coding mutations in well-known RNA splicing factors exhibit similar gene expression sig
156 me-wide screen revealed that depletion of 14 RNA splicing factors leads to a specific defect in centr
157 These toxic RNAs alter the activities of RNA splicing factors resulting in alternative splicing m
160 Under ADT conditions, recruitment of several RNA splicing factors to the 3' splicing site for AR-V7 w
161 f TOP1 to RNAPIIo and for the recruitment of RNA splicing factors to the actively transcribed chromat
163 he primary cell affected by mutations in the RNA splicing factors, and these changes occur at an earl
164 uncovered recurrent somatic mutations within RNA splicing factors, including SF3B1, SRSF2, U2AF1 and
167 nalyses revealed that both drugs altered E1A RNA splicing (favoring the production of 13S over 12S RN
173 matic mutations in epigenetic regulators and RNA splicing genes frequently constitute isolated diseas
174 natural product and synthetic modulators of RNA splicing has opened new access to this field, allowi
176 discovery in 1977, the study of alternative RNA splicing has revealed a plethora of mechanisms that
177 ng factors contributing to HPV18 alternative RNA splicing have been discovered in this study for the
178 Together, these data demonstrate a role for RNA splicing homeostasis in dietary restriction longevit
179 equencing and analysis of global alternative RNA splicing identified that the mRNA splicing of cytopl
180 termines strain-specific differences in cell RNA splicing.IMPORTANCE Efficient viral replication requ
181 ous mutations in SMC3 or SMC1A that affected RNA splicing in 2 independent patients with combined CdL
182 rations of H3K36me3 associated with aberrant RNA splicing in a SETD2 mutant RCC and SETD2 knockout ce
189 ere are many important examples of regulated RNA splicing in Saccharomyces cerevisiae Here, we report
190 e, there are important examples of regulated RNA splicing in Saccharomyces cerevisiae, such as splici
191 ine-rich (SR) proteins involved in messenger RNA splicing, including the splicing factor SRm300 (SRRM
193 after treating virus-infected cells with the RNA splicing inhibitor spliceostatin A to prevent M2 mRN
203 onclude post-transcriptional control of Xist RNA splicing is an essential regulatory step of Xist ind
204 ur laboratory previously reported that Bcl-x RNA splicing is dysregulated in a large percentage of hu
205 n generating transcriptome diversity through RNA splicing is independently unmasked by two studies in
208 e propose a model wherein a modest effect on RNA splicing is sufficient to mediate the CD33 associati
210 action networks to describe the formation of RNA splicing machinery complexes and splicing processes
211 The dependence of adenovirus on the host pre-RNA splicing machinery for expression of its complete ge
212 s affecting genes encoding components of the RNA splicing machinery in hematological malignancies.
213 ic mutations of SF3B1 and other genes of the RNA splicing machinery in patients with myelodysplastic
214 dary-type AML carrying mutations in genes of RNA splicing machinery, TP53-mutated AML, or de novo AML
217 tronic mutation as the molecular basis for a RNA splicing-mediated RAF inhibitor resistance mechanism
218 suggest a novel model wherein SNP-modulated RNA splicing modulates CD33 function and, thereby, AD ri
219 udemycin E is an analog of the pre-messenger RNA splicing modulator FR901464 and its derivative splic
221 s, chromatin, long noncoding RNAs (lncRNAs), RNA splicing, nuclear topology and the 3D conformation o
223 We investigated the effect on pre-messenger RNA splicing of 14 ATP8B1 mutations at exon-intron bound
224 In this manuscript, we demonstrated that RNA splicing of AR-V7 in response to ADT was closely ass
225 ore, we investigated whether the alternative RNA splicing of Bcl-x pre-mRNA was modulated by MDA-7/IL
226 en 1q21-amplified ILF2 and the regulation of RNA splicing of DNA repair genes may be exploited to opt
227 es important observations on how alternative RNA splicing of HPV18 pre-mRNAs is subject to regulation
228 vide the first evidence that the alternative RNA splicing of HPV18 pre-mRNAs is subject to regulation
230 onucleotide drug that modifies pre-messenger RNA splicing of the SMN2 gene and thus promotes increase
232 n of HPV18 genes is regulated by alternative RNA splicing of viral polycistronic pre-mRNAs to produce
233 te degradation of target mRNAs or to inhibit RNA splicing or translation of several genes of P. falci
234 e disease patients suggests that identifying RNA splicing outliers is particularly useful for determi
236 Based on this finding, we hypothesized that RNA splicing plays a role in mediating vWF expression in
237 ear protein that regulates transcription and RNA splicing, plays an important role in tumorigenesis b
240 n/cytoskeletal protein binding, RNA binding, RNA splicing/processing, chromatin modifying, intracellu
241 or up to three months, redistribution of the RNA-splicing protein muscleblind-like splicing regulator
242 f RALY and hnRNP-C increased levels of viral RNA splicing, protein abundance and progeny production d
243 n a random forest classifier that integrates RNA splicing, protein structure, and evolutionary conser
244 aling, chromatin, and epigenomic regulation; RNA splicing; protein homeostasis; metabolism; and linea
246 S69 connects histone H3.3K36me3 to regulated RNA splicing, providing significant, important insights
248 3ss) is an essential early step in mammalian RNA splicing reactions, but the processes involved are u
250 d identified a muscle-specific isoform of an RNA splicing regulator, RBFox1 (also known as A2BP1), as
251 We further identify BS69 association with RNA splicing regulators, including the U5 snRNP componen
252 with mutations in genes encoding chromatin, RNA-splicing regulators, or both (in 18% of patients); A
256 rated as two isoform families by alternative RNA splicing, represented by VEGF-A165a and VEGF-A165b.
257 identified in cardiomyopathy patients alter RNA splicing, representing a 50% increase in the numbers
259 gle intra-otic dose of ASO corrects harmonin RNA splicing, restores harmonin protein expression in se
260 y while studying transcription, translation, RNA splicing, ribosome biogenesis, and more recently, di
261 fect genetic instability, promoter activity, RNA splicing, RNA stability, and neurite mRNA localizati
263 tes evolved from DNA encoding a pre-existing RNA splicing signal, effectively linking dosage compensa
268 in processes such as chromatin modification, RNA splicing, T- and B-cell activation, and NF-kappaB si
269 atio-temporally coordinated, indicating that RNA splicing takes place in the context of chromatin.
270 ed additional changes in gene expression and RNA splicing that may underlie the effects of this mutat
271 ting to transcript type, gene expression and RNA splicing that would be lost with other approaches us
274 data demonstrating the influence of HYAL2 on RNA splicing, these findings begin to explain the broad
275 ntiation from neural stem cells and mediates RNA splicing through interactions with polypyrimidine tr
276 pre-mRNAs that are regulated by alternative RNA splicing to produce a repertoire of viral transcript
277 uman TACI undergoes alternative messenger (m)RNA splicing to produce isoforms with 1 or 2 ligand-bind
278 ous mechanisms by which cancer cells exploit RNA splicing to promote tumor growth and the current the
279 ted role of RBM3 in linking stress-regulated RNA splicing to tumorigenesis, with potential prognostic
282 protein synthesis, ARSs are also involved in RNA splicing, transcriptional regulation, translation, a
283 fect promoter activity, genetic instability, RNA splicing, translation, and neurite mRNA localization
286 V1), RHOA/cytoskeleton remodeling (ARHGEF3), RNA splicing (U2AF1), T-cell receptor signaling (PTPRN2,
287 suggest that a conserved role in chloroplast RNA splicing underlies the physiological defects describ
289 open reading frame usage, and translation of RNA splicing variants) has been reported, and autoreacti
290 ion of Bcl-x(L) is regulated at the level of RNA splicing via alternative 5' splice site selection wi
293 involved in regulation of transcription and RNA splicing were enriched in the group of cell types wi
294 of protein-coding messenger RNAs (mRNAs) via RNA splicing, whereby the spliceosome removes non-coding
295 esses in eukaryotic gene expression, such as RNA splicing, which can cause a pre-mRNA to produce one
296 a rapid change in alternative pre-messenger RNA splicing, which is later followed by changes in over
298 scores how strongly genetic variants affect RNA splicing, whose alteration contributes to many disea
300 pores, exposing the dynamics and patterns of RNA splicing without biases introduced by amplification.