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Transcription[JOURNAL]

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A link between transcription fidelity and pausing in vivo.

Gamba P, James K, Zenkin N

Transcription · 2017 Mar · PMID 28072558 · Full text

Pausing by RNA polymerase is a major mechanism that regulates transcription elongation but can cause conflicts with fellow RNA polymerases and other cellular machineries. Here, we summarize our recent finding that misinc... Pausing by RNA polymerase is a major mechanism that regulates transcription elongation but can cause conflicts with fellow RNA polymerases and other cellular machineries. Here, we summarize our recent finding that misincorporation could be a major source of transcription pausing in vivo, and discuss the role of misincorporation-induced pausing.

The seven faces of SIRT7.

Blank MF, Grummt I

Transcription · 2017 Mar · PMID 28067587 · Full text

SIRT7, a member of the sirtuin family of NAD-dependent protein deacetylases, is a key mediator of many cellular activities. SIRT7 expression is linked to cell proliferation and oncogenic activity, connecting SIRT7-depend... SIRT7, a member of the sirtuin family of NAD-dependent protein deacetylases, is a key mediator of many cellular activities. SIRT7 expression is linked to cell proliferation and oncogenic activity, connecting SIRT7-dependent regulation of ribosome biogenesis with checkpoints controlling cell cycle progression, metabolic homeostasis, stress resistance, aging and tumorigenesis. Despite this important functional link, the enzymatic activity, the molecular targets and physiological functions of SIRT7 are poorly defined. Here, we review recent progress in SIRT7 research and elaborate the main pathways in which SIRT7 participates.

Dynamic chromatin regulation at Notch target genes.

Giaimo BD, Oswald F, Borggrefe T

Transcription · 2017 Jan · PMID 28027012 · Full text

RBPJ is the central transcription factor that controls the Notch-dependent transcriptional response by coordinating repressing histone H3K27 deacetylation and activating histone H3K4 methylation. Here, we discuss the mol... RBPJ is the central transcription factor that controls the Notch-dependent transcriptional response by coordinating repressing histone H3K27 deacetylation and activating histone H3K4 methylation. Here, we discuss the molecular mechanisms how RBPJ interacts with opposing NCoR/HDAC-corepressing or KMT2D/UTX-coactivating complexes and how this is controlled by phosphorylation of chromatin modifiers.

CDK regulation of transcription by RNAP II: Not over 'til it's over?

Fisher RP

Transcription · 2017 Mar · PMID 28005463 · Full text

Transcription by RNA polymerase (RNAP) II is regulated at multiple steps by phosphorylation, catalyzed mainly by members of the cyclin-dependent kinase (CDK) family. The CDKs involved in transcription have overlapping su... Transcription by RNA polymerase (RNAP) II is regulated at multiple steps by phosphorylation, catalyzed mainly by members of the cyclin-dependent kinase (CDK) family. The CDKs involved in transcription have overlapping substrate specificities, but play largely non-redundant roles in coordinating gene expression. Novel functions and targets of CDKs have recently emerged at the end of the transcription cycle, when the primary transcript is cleaved, and in most cases polyadenylated, and transcription is terminated by the action of the "torpedo" exonuclease Xrn2, which is a CDK substrate. Collectively, various functions have been ascribed to CDKs or CDK-mediated phosphorylation: recruiting cleavage and polyadenylation factors, preventing premature termination within gene bodies while promoting efficient termination of full-length transcripts, and preventing extensive readthrough transcription into intergenic regions or neighboring genes. The assignment of precise functions to specific CDKs is still in progress, but recent advances suggest ways in which the CDK network and RNAP II machinery might cooperate to ensure timely exit from the transcription cycle.

The role of alternative splicing in cancer.

Singh B, Eyras E

Transcription · 2017 Mar · PMID 28005460 · Full text

The functional capacity of cells is defined by the transcriptome. Many recent studies have identified variations in the transcriptome of tumors due to alternative splicing changes, as well as mutations in splicing factor... The functional capacity of cells is defined by the transcriptome. Many recent studies have identified variations in the transcriptome of tumors due to alternative splicing changes, as well as mutations in splicing factors and regulatory signals in most tumor types. Some of these alterations have been linked to tumor progression, metastasis, therapy resistance, and other oncogenic processes. Here, we describe the different mechanisms that drive splicing changes in tumors and their impact in cancer. Motivated by the current evidence, we propose a model whereby a subset of the splicing patterns contributes to the definition of specific tumor phenotypes, and may hold potential for the development of novel clinical biomarkers and therapeutic approaches.

Structural dynamics and DNA interaction of human TFIID.

Nogales E, Fang J, Louder RK

Transcription · 2017 Jan · PMID 27935424 · Full text

TFIID is a large protein complex required for the recognition and binding of eukaryotic gene core promoter sequences and for the recruitment of the rest of the general transcription factors involved in initiation of euka... TFIID is a large protein complex required for the recognition and binding of eukaryotic gene core promoter sequences and for the recruitment of the rest of the general transcription factors involved in initiation of eukaryotic protein gene transcription. Cryo-electron microscopy studies have demonstrated the conformational complexity of human TFIID, where one-third of the mass of the complex can shift its position by well over 100 Å. This conformational plasticity appears to be linked to the capacity of TFIID to bind DNA, and suggests how it would allow both the recognition of different core promoter elements and the tuning of its binding affinity by regulatory factors.

TFEB and TFE3: The art of multi-tasking under stress conditions.

Martina JA, Puertollano R

Transcription · 2017 Jan · PMID 27892768 · Full text

Cellular adaptation response to a myriad of stressors is key for survival. The lysosomal/autophagy pathway is inextricably connected to the stress response regulation. Two transcription factors, TFEB and TFE3, have recen... Cellular adaptation response to a myriad of stressors is key for survival. The lysosomal/autophagy pathway is inextricably connected to the stress response regulation. Two transcription factors, TFEB and TFE3, have recently emerged as master regulators of this degradative pathway. Their function modulating different cellular pathways will be discussed.

Measures of RNA metabolism rates: Toward a definition at the level of single bonds.

Wachutka L, Gagneur J

Transcription · 2017 Mar · PMID 27841720 · Full text

We give an overview of experimental and computational methods to estimate RNA metabolism rates genome-wide. We then advocate a local definition of RNA metabolism rate at the level of individual phosphodiester bonds. Rate... We give an overview of experimental and computational methods to estimate RNA metabolism rates genome-wide. We then advocate a local definition of RNA metabolism rate at the level of individual phosphodiester bonds. Rates of formation and disappearance of individual bonds are unambiguously defined, in contrast to rates of complete transcripts. We show that over previous approaches, the recently developed transient transcriptome sequencing (TT-seq) protocol allows for estimation of metabolism rates of individual bonds with least positional bias.

Causal role of histone acetylations in enhancer function.

Pradeepa MM

Transcription · 2017 Jan · PMID 27792455 · Full text

Enhancers control development and cellular function by spatiotemporal regulation of gene expression. Co-occurrence of acetylation of histone H3 at lysine 27 (H3K27ac) and mono methylation of histone H3 at lysine 4 (H3K4m... Enhancers control development and cellular function by spatiotemporal regulation of gene expression. Co-occurrence of acetylation of histone H3 at lysine 27 (H3K27ac) and mono methylation of histone H3 at lysine 4 (H3K4me1) has been widely used for identification of active enhancers. However, increasing evidence suggests that using this combination of marks alone for enhancer identification gives an incomplete picture of the active enhancer repertoire. We have shown that the H3 globular domain acetylations, H3K64ac and H3K122ac, and an H4 tail acetylation, H4K16ac, are enriched at active enhancers together with H3K27ac, and also at a large number of enhancers without detectable H3K27ac. We propose that acetylations at these lysine residues of histones H3 and H4 might function by directly affecting chromatin structure, nucleosome-nucleosome interactions, nucleosome stability, and transcription factor accessibility.

H3K36 methylation state and associated silencing mechanisms.

Suzuki S, Murakami Y, Takahata S

Transcription · 2017 Jan · PMID 27723431 · Full text

Epigenetic marks determine cell fate via numerous reader proteins. H3K36 methylation is a common epigenetic mark that is thought to be associated with the activities of the RNA polymerase 2 C-terminal domain. We discuss... Epigenetic marks determine cell fate via numerous reader proteins. H3K36 methylation is a common epigenetic mark that is thought to be associated with the activities of the RNA polymerase 2 C-terminal domain. We discuss a novel silencing mechanism regulated by Set2-dependent H3K36 methylation that involves exosome-dependent RNA processing.

More than meets the dimer: What is the quaternary structure of the glucocorticoid receptor?

Presman DM, Hager GL

Transcription · 2017 Jan · PMID 27764575 · Full text

It is widely accepted that the glucocorticoid receptor (GR), a ligand-regulated transcription factor that triggers anti-inflammatory responses, binds specific response elements as a homodimer. Here, we will discuss the o... It is widely accepted that the glucocorticoid receptor (GR), a ligand-regulated transcription factor that triggers anti-inflammatory responses, binds specific response elements as a homodimer. Here, we will discuss the original primary data that established this model and contrast it with a recent report characterizing the GR-DNA complex as a tetramer.

YEATS domain: Linking histone crotonylation to gene regulation.

Li Y, Zhao D, Chen Z … +1 more , Li H

Transcription · 2017 Jan · PMID 27661789 · Full text

Recent research reveals that the YEATS domains preferentially recognize crotonylated lysines on histones. Here, we discuss the molecular mechanisms that enable this recognition and the biological significances of this in... Recent research reveals that the YEATS domains preferentially recognize crotonylated lysines on histones. Here, we discuss the molecular mechanisms that enable this recognition and the biological significances of this interaction. The dynamics of histone crotonylation and its potential roles in the regulation of gene expression will also be discussed.

A structure-based kinetic model of transcription.

Zuo Y, Steitz TA

Transcription · 2017 Jan · PMID 27656764 · Full text

During transcription, RNA polymerase moves downstream along the DNA template and maintains a transcription bubble. Several recent structural studies of transcription complexes with a complete transcription bubble provide... During transcription, RNA polymerase moves downstream along the DNA template and maintains a transcription bubble. Several recent structural studies of transcription complexes with a complete transcription bubble provide new insights into how RNAP couples the nucleotide addition reaction to its directional movement.

Putative RNA-directed adaptive mutations in cancer evolution.

Auboeuf D

Transcription · 2016 Oct · PMID 27715501 · Full text

Understanding the molecular mechanisms behind the capacity of cancer cells to adapt to the tumor microenvironment and to anticancer therapies is a major challenge. In this context, cancer is believed to be an evolutionar... Understanding the molecular mechanisms behind the capacity of cancer cells to adapt to the tumor microenvironment and to anticancer therapies is a major challenge. In this context, cancer is believed to be an evolutionary process where random mutations and the selection process shape the mutational pattern and phenotype of cancer cells. This article challenges the notion of randomness of some cancer-associated mutations by describing molecular mechanisms involving stress-mediated biogenesis of mRNA-derived small RNAs able to target and increase the local mutation rate of the genomic loci they originate from. It is proposed that the probability of some mutations at specific loci could be increased in a stress-specific and RNA-depending manner. This would increase the probability of generating mutations that could alleviate stress situations, such as those triggered by anticancer drugs. Such a mechanism is made possible because tumor- and anticancer drug-associated stress situations trigger both cellular reprogramming and inflammation, which leads cancer cells to express molecular tools allowing them to "attack" and mutate their own genome in an RNA-directed manner.

Steroid hormone receptors silence genes by a chromatin-targeted mechanism similar to those used for gene activation.

Nacht AS, Beato M, Vicent GP

Transcription · 2017 Jan · PMID 27700223 · Full text

How genes are repressed by steroid hormones remains a matter of debate, and several indirect mechanisms have been proposed. We found that the ligand-activated progesterone receptor recruits to the promoter of downregulat... How genes are repressed by steroid hormones remains a matter of debate, and several indirect mechanisms have been proposed. We found that the ligand-activated progesterone receptor recruits to the promoter of downregulated genes a repressor complex composed of HP1γ, the lysine demethylase LSD1, histone deacetylases, coREST, the RNA SRA, and the ATPase BRG1. BRG1 is needed for chromatin remodeling and facilitates the deposition of linker histone variant H1.2, which compacts chromatin and hinders RNA polymerase loading and transcription. Thus, steroid hormone receptors can repress genes in ways reminiscent of those used for gene induction, namely by directly targeting factors that remodel chromatin. But while PR-dependent gene induction in T47D cells is mainly achieved by potentiating enhancer activity, repression acts at the level of gene promoters.

Transcriptional control by G-quadruplexes: In vivo roles and perspectives for specific intervention.

Armas P, David A, Calcaterra NB

Transcription · 2017 Jan · PMID 27696937 · Full text

G-quadruplexes are non-canonical DNA secondary structures involved in several genomic and molecular processes. Here, we summarize the main G-quadruplex features and evidences proving the in vivo role on the transcription... G-quadruplexes are non-canonical DNA secondary structures involved in several genomic and molecular processes. Here, we summarize the main G-quadruplex features and evidences proving the in vivo role on the transcriptional regulation of genes required for zebrafish embryonic development. We also discuss alternative strategies for specifically interfering G-quadruplex in vivo.

Eukaryotic transcription initiation machinery visualized at molecular level.

Han Y, He Y

Transcription · 2016 Oct · PMID 27658022 · Full text

The structures of RNA Polymerase (Pol) II pre-initiation complexes (PIC) have recently been determined at near-atomic resolution, elucidating unprecedented mechanistic details of promoter opening during transcription ini... The structures of RNA Polymerase (Pol) II pre-initiation complexes (PIC) have recently been determined at near-atomic resolution, elucidating unprecedented mechanistic details of promoter opening during transcription initiation. The key structural features of promoter opening are summarized here. Structural knowledge of Pol I and III PIC is also briefly discussed.

tRNA evolution from the proto-tRNA minihelix world.

Root-Bernstein R, Kim Y, Sanjay A … +1 more , Burton ZF

Transcription · 2016 Oct · PMID 27636862 · Full text

Multiple models have been advanced for the evolution of cloverleaf tRNA. Here, the conserved archaeal tRNA core (75-nt) is posited to have evolved from ligation of three proto-tRNA minihelices (31-nt) and two-symmetrical... Multiple models have been advanced for the evolution of cloverleaf tRNA. Here, the conserved archaeal tRNA core (75-nt) is posited to have evolved from ligation of three proto-tRNA minihelices (31-nt) and two-symmetrical 9-nt deletions within joined acceptor stems (93 - 18 = 75-nt). The primary evidence for this conclusion is that the 5-nt stem 7-nt anticodon loop and the 5-nt stem 7-nt T loop are structurally homologous and related by coding sequence. We posit that the D loop was generated from a third minihelix (31-nt) in which the stem and loop became rearranged after 9-nt acceptor stem deletions and cloverleaf folding. The most 3´-5-nt segment of the D loop and the 5-nt V loop are apparent remnants of the joined acceptor stems (14 - 9 = 5-nt). Before refolding in the tRNA cloverleaf, we posit that the 3'-5-nt segment of the D loop and the 5-nt V loop were paired, and, in the tRNA cloverleaf, frequent pairing of positions 29 (D loop) and 47 (V loop) remains (numbered on a 75-nt tRNA cloverleaf core). Amazingly, after >3.5 billion years of evolutionary pressure on the tRNA cloverleaf structure, a model can be constructed that convincingly describes the genesis of 75/75-nt conserved archaeal tRNA core positions. Judging from the tRNA structure, cloverleaf tRNA appears to represent at least a second-generation scheme (and possibly a third-generation scheme) that replaced a robust 31-nt minihelix protein-coding system, evidence for which is preserved in the cloverleaf structure. Understanding tRNA evolution provides insights into ribosome and rRNA evolution.

Ouija board: A transcription factor evolved for only one target in steroid hormone biosynthesis in the fruit fly Drosophila melanogaster.

Niwa YS, Niwa R

Transcription · 2016 Oct · PMID 27434771 · Full text

Transcription factors generally regulate gene expression of multiple targets. In contrast, our recent finding suggests that the zinc finger protein Ouija board controls steroid hormone biosynthesis through specific regul... Transcription factors generally regulate gene expression of multiple targets. In contrast, our recent finding suggests that the zinc finger protein Ouija board controls steroid hormone biosynthesis through specific regulation of only one gene spookier in Drosophila. It sheds light on a specialized but essential factor that evolved for one target.

Computational challenges in modeling gene regulatory events.

Pataskar A, Tiwari VK

Transcription · 2016 Oct · PMID 27390891 · Full text

Cellular transcriptional programs driven by genetic and epigenetic mechanisms could be better understood by integrating "omics" data and subsequently modeling the gene-regulatory events. Toward this end, computational bi... Cellular transcriptional programs driven by genetic and epigenetic mechanisms could be better understood by integrating "omics" data and subsequently modeling the gene-regulatory events. Toward this end, computational biology should keep pace with evolving experimental procedures and data availability. This article gives an exemplified account of the current computational challenges in molecular biology.
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