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1.
Molecular Mechanisms of pre-mRNA Splicing through Structural Biology of the Spliceosome.
Yan, C, Wan, R, Shi, Y
Cold Spring Harbor perspectives in biology. 2019;(1)
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Abstract
Precursor messenger RNA (pre-mRNA) splicing is executed by the spliceosome. In the past 3 years, cryoelectron microscopy (cryo-EM) structures have been elucidated for a majority of the yeast spliceosomal complexes and for a few human spliceosomes. During the splicing reaction, the dynamic spliceosome has an immobile core of about 20 protein and RNA components, which are organized around a conserved splicing active site. The divalent metal ions, coordinated by U6 small nuclear RNA (snRNA), catalyze the branching reaction and exon ligation. The spliceosome also contains a mobile but compositionally stable group of about 13 proteins and a portion of U2 snRNA, which facilitate substrate delivery into the splicing active site. The spliceosomal transitions are driven by the RNA-dependent ATPase/helicases, resulting in the recruitment and dissociation of specific splicing factors that enable the reaction. In summary, the spliceosome is a protein-directed metalloribozyme.
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Messenger RNA therapy for rare genetic metabolic diseases.
Berraondo, P, Martini, PGV, Avila, MA, Fontanellas, A
Gut. 2019;(7):1323-1330
Abstract
Decades of intense research in molecular biology and biochemistry are fructifying in the emergence of therapeutic messenger RNAs (mRNA) as a new class of drugs. Synthetic mRNAs can be sequence optimised to improve translatability into proteins, as well as chemically modified to reduce immunogenicity and increase chemical stability using naturally occurring uridine modifications. These structural improvements, together with the development of safe and efficient vehicles that preserve mRNA integrity in circulation and allow targeted intracellular delivery, have paved the way for mRNA-based therapeutics. Indeed, mRNAs formulated into biodegradable lipid nanoparticles are currently being tested in preclinical and clinical studies for multiple diseases including cancer immunotherapy and vaccination for infectious diseases. An emerging application of mRNAs is the supplementation of proteins that are not expressed or are not functional in a regulated and tissue-specific manner. This so-called 'protein replacement therapy' could represent a solution for genetic metabolic diseases currently lacking effective treatments. Here we summarise this new class of drugs and discuss the preclinical evidence supporting the potential of liver-mediated mRNA therapy for three rare genetic conditions: methylmalonic acidaemia, acute intermittent porphyria and ornithine transcarbamylase deficiency.
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Nuclear mRNA Surveillance Mechanisms: Function and Links to Human Disease.
Singh, P, Saha, U, Paira, S, Das, B
Journal of molecular biology. 2018;(14):1993-2013
Abstract
Production of export-competent mRNAs involves transcription and a series of dynamic processing and modification events of pre-messenger RNAs in the nucleus. Mutations in the genes encoding the transcription and mRNP processing machinery and the complexities involved in the biogenesis events lead to the formation of aberrant messages. These faulty transcripts are promptly eliminated by the nuclear RNA exosome and its cofactors to safeguard the cells and organisms from genetic catastrophe. Mutations in the components of the core nuclear exosome and its cofactors lead to the tissue-specific dysfunction of exosomal activities, which are linked to diverse human diseases and disorders. In this article, we examine the structure and function of both the yeast and human RNA exosome complex and its cofactors, discuss the nature of the various altered amino acid residues implicated in these diseases with the speculative mechanisms of the mutation-induced disorders and project the frontier and prospective avenues of the future research in this field.
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[Intersubunit Mobility of the Ribosome].
Finkelstein, AV, Razin, SV, Spirin, AS
Molekuliarnaia biologiia. 2018;(6):921-934
Abstract
Ribosomes are ribonucleoprotein nanoparticles synthesizing all proteins in living cells. The function of the ribosome is to translate the genetic information encoded in a nucleotide sequence of mRNA into the amino acid sequence of a protein. Each translation step (occurring after the codon-dependent binding of the aminoacyl-tRNA with the ribosome and mRNA) includes (i) the transpeptidation reaction and (ii) the translocation that unidirectionally drives the mRNA chain and mRNA-bound tRNA molecules through the ribosomal intersubunit space; the latter process is driven by the free energy of the chemical reaction of transpeptidation. Thus, the translating ribosome can be considered a conveying protein-synthesizing molecular machine. In this review we analyze the role of ribosomal intersubunit mobility in the process of translocation.
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The special existences: nanoRNA and nanoRNase.
Liao, H, Liu, M, Guo, X
Microbiological research. 2018;:134-139
Abstract
To adapt to a wide range of nutritional and environmental changes, cells must adjust their gene expression profiles. This process is completed by the frequent transcription and rapid degradation of mRNA. mRNA decay is initiated by a series of endo- and exoribonucleases. These enzymes leave behind 2- to 5-nt-long oligoribonucleotides termed "nanoRNAs" that are degraded by specific nanoRNases; the degradation of nanoRNA is essential because nanoRNA can mediate the priming of transcription initiation that is harmful for the cell via an unknown mechanism. Identified nanoRNases include Orn in E. coli, NrnA and NrnB in B. subtilis, and NrnC in Bartonella. Even though these nanoRNases can degrade nanoRNA specifically into mononucleotides, the biochemical features, structural features and functional mechanisms of these enzymes are different. Sequence analysis has identified homologs of these nanoRNases in different bacteria, including Gammaproteobacteria, Betaproteobacteria, Alphaproteobacteria, Firmicutes and Cyanobacteria. However, there are several bacteria, such as those belonging to the class Thermolithobacteria, that do not have homologs of these nanoRNases. In this paper, the source of nanoRNA, the features of different kinds of nanoRNases and the distribution of these enzymes in prokaryotes are described in detail.
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[Functional implications of single nucleotide polymorphisms (SNPs) in protein-coding and non-coding RNA genes in multifactorial diseases].
Ramírez-Bello, J, Jiménez-Morales, M
Gaceta medica de Mexico. 2017;(2):238-250
Abstract
Single nucleotide polymorphisms (SNPs) represent the most common type of variation in the human genome. The SNPs located in protein-coding and non-coding RNA genes are classified as neutral and functional. The neutral have no effect, while the functional affect different biological processes and continually confer risk for multifactorial diseases. Functional SNPs found in the promoters of protein-coding and non-coding RNA genes (microRNAs: miRNAs) termed regulatory SNP (rSNPs) and miRNAs rSNPs (miR-rSNPs), respectively, affect the gene expression. Functional SNPs located on the structure of the precursor mRNAs (exons and introns), mature mRNA (5´ untranslated region [UTR], coding sequence, and 3´ UTR), and primary, precursor, and mature miRNAs are termed structural RNA SNPs (srSNPs) and miR-srSNPs, respectively. The srSNPs affect the splicing (and alternative splicing), srSNPs affect the splicing (and alternative splicing), the translation, stability, amino acid sequence, structure, and function of proteins and interaction between mRNA/miRNAs. Finally, the miR-srSNPs affect the structure, processing and interaction between miRNAs/mRNAs. Functional characterization of potentially harmful risk alleles of the SNPs located in protein-coding and non-coding RNA genes have contributed to an understanding of their functions in the complex diseases. The objective of this review is update the reader on the functional role of the SNPs located in protein-coding and non-coding RNA genes and their relationship with multifactorial diseases.
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7.
Decoding sORF translation - from small proteins to gene regulation.
Cabrera-Quio, LE, Herberg, S, Pauli, A
RNA biology. 2016;(11):1051-1059
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Abstract
Translation is best known as the fundamental mechanism by which the ribosome converts a sequence of nucleotides into a string of amino acids. Extensive research over many years has elucidated the key principles of translation, and the majority of translated regions were thought to be known. The recent discovery of wide-spread translation outside of annotated protein-coding open reading frames (ORFs) came therefore as a surprise, raising the intriguing possibility that these newly discovered translated regions might have unrecognized protein-coding or gene-regulatory functions. Here, we highlight recent findings that provide evidence that some of these newly discovered translated short ORFs (sORFs) encode functional, previously missed small proteins, while others have regulatory roles. Based on known examples we will also speculate about putative additional roles and the potentially much wider impact that these translated regions might have on cellular homeostasis and gene regulation.
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The end of the message: multiple protein-RNA interactions define the mRNA polyadenylation site.
Shi, Y, Manley, JL
Genes & development. 2015;(9):889-97
Abstract
The key RNA sequence elements and protein factors necessary for 3' processing of polyadenylated mRNA precursors are well known. Recent studies, however, have significantly reshaped current models for the protein-RNA interactions involved in poly(A) site recognition, painting a picture more complex than previously envisioned and also providing new insights into regulation of this important step in gene expression. Here we review the recent advances in this area and provide a perspective for future studies.
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Identification of phloem-mobile mRNA.
Notaguchi, M
Journal of plant research. 2015;(1):27-35
Abstract
Signaling between cells, tissues and organs is essential for multicellular organisms to coordinate and adapt their development and growth to internal and environmental changes. Plants have evolved a plant-specific symplasmic pathway, called plasmodesmata, for efficient intercellular communication, in addition to the receptor-ligand-based apoplasmic pathway. Long-distance signaling between distant organs is enabled via the phloem tube system, where plasmodesmata contribute to phloem loading and unloading for photosynthate allocation. In addition to signaling by small molecules such as metabolites and phytohormones, the transport of proteins, small RNAs and mRNAs is also considered an important mechanism to achieve long-distance signaling in plants. Recent studies on phloem-mobile proteins and small RNAs have revealed their role in crucial physiological processes including flowering, systemic silencing and nutrient allocation. However, the biological role of mRNAs found in the phloem tube is not yet clear, though their mobility over long-distances has been well evidenced. To gain this knowledge, it is important to collect further information on mRNA profiles in the phloem translocation stream. In this review, I summarize the current approaches to identifying the mRNA population in the phloem translocation system, and discuss the possible role of short- and long-distance mRNA transport.
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10.
Synchronizing transcriptional control of T cell metabolism and function.
Man, K, Kallies, A
Nature reviews. Immunology. 2015;(9):574-84
Abstract
During an immune response, cytokines and transcription factors regulate the differentiation and function of effector and memory T cells. At the same time, T cell metabolism undergoes dynamic and differentiation-stage-specific changes that are required for initial T cell activation, rapid proliferation and the acquisition of effector functions. Similarly, during the resolution of an immune response, metabolic regulation is crucial for restraining inflammatory responses and promoting peripheral tolerance, and it is required for the long-term maintenance of memory T cells. T cell receptor (TCR)-induced transcription factors, in particular MYC and interferon-regulatory factor 4 (IRF4), cooperate with canonical nutrient-sensing pathways to integrate antigen-specific and metabolic signals to appropriately modulate adaptive immune responses. In this Review, we focus on the emerging evidence that T cell differentiation and metabolism are closely linked and synchronized by immune cell-specific cytokines and transcription factors that are induced by TCR signalling.