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Mature mRNA (mature + mrna)

Distribution by Scientific Domains
Life Sciences60%

Selected Abstracts

Antisense therapeutics for neurofibromatosis type 1 caused by deep intronic mutations,

HUMAN MUTATION, Issue 3 2009
Eva Pros
Abstract Neurofibromatosis type 1 (NF1) is an autosomal dominant disorder affecting 1:3,500 individuals. Disease expression is highly variable and complications are diverse. However, currently there is no specific treatment for the disease. NF1 is caused by mutations in the NF1 gene, approximately 2.1% of constitutional mutations identified in our population are deep intronic mutations producing the insertion of a cryptic exon into the mature mRNA. We used antisense morpholino oligomers (AMOs) to restore normal splicing in primary fibroblast and lymphocyte cell lines derived from six NF1 patients bearing three deep intronic mutations in the NF1 gene (c.288+2025T>G, c.5749+332A>G, and c.7908-321C>G). AMOs were designed to target the newly created 5, splice sites to prevent the incorporation of cryptic exons. Our results demonstrate that AMO treatment effectively restored normal NF1 splicing at the mRNA level for the three mutations studied in the different cell lines analyzed. We also found that AMOs had a rapid effect that lasted for several days, acting in a sequence-specific manner and interfering with the splicing mechanism. Finally, to test whether the correction of aberrant NF1 splicing also restored neurofibromin function to wild-type levels, we measured the amount of Ras-GTP after AMO treatment in primary fibroblasts. The results clearly show an AMO-dependent decrease in Ras-GTP levels, which is consistent with the restoration of neurofibromin function. To our knowledge this is the first time that an antisense technique has been usedsuccessfully to correct NF1 mutations opening the possibility of a therapeutic strategy for this type of mutation not only for NF1 but for other genetic disorders. Hum Mutat 30, 454,462, 2009. © 2009 Wiley-Liss, Inc. [source]

Molecular anatomy of a speckle

THE ANATOMICAL RECORD : ADVANCES IN INTEGRATIVE ANATOMY AND EVOLUTIONARY BIOLOGY, Issue 7 2006
Lisa L. Hall
Abstract Direct localization of specific genes, RNAs, and proteins has allowed the dissection of individual nuclear speckles in relation to the molecular biology of gene expression. Nuclear speckles (aka SC35 domains) are essentially ubiquitous structures enriched for most pre-mRNA metabolic factors, yet their relationship to gene expression has been poorly understood. Analyses of specific genes and their spliced or mature mRNA strongly support that SC35 domains are hubs of activity, not stores of inert factors detached from gene expression. We propose that SC35 domains are hubs that spatially link expression of specific pre-mRNAs to rapid recycling of copious RNA metabolic complexes, thereby facilitating expression of many highly active genes. In addition to increasing the efficiency of each step, sequential steps in gene expression are structurally integrated at each SC35 domain, consistent with other evidence that the biochemical machineries for transcription, splicing, and mRNA export are coupled. Transcription and splicing are subcompartmentalized at the periphery, with largely spliced mRNA entering the domain prior to export. In addition, new findings presented here begin to illuminate the structural underpinnings of a speckle by defining specific perturbations of phosphorylation that promote disassembly or assembly of an SC35 domain in relation to other components. Results thus far are consistent with the SC35 spliceosome assembly factor as an integral structural component. Conditions that disperse SC35 also disperse poly(A) RNA, whereas the splicing factor ASF/SF2 can be dispersed under conditions in which SC35 or SRm300 remain as intact components of a core domain. Anat Rec Part A, 288A:664,675, 2006. © 2006 Wiley-Liss, Inc. [source]

Nonsense-mediated decay: paving the road for genome diversification

BIOESSAYS, Issue 10 2008
Francisco Sánchez-Sánchez
The expression of protein-encoding genes is a complex process culminating in the production of mature mRNA and its translation by the ribosomes. The production of a mature mRNA involves an intricate series of processing steps. The majority of eukaryotic protein-encoding genes contain intron sequences that disrupt the protein-encoding frame, and hence have to be removed from immature mRNA prior to translation into protein. The mechanism involved in the selection of correct splice sites is incompletely understood. A considerable body of evidence suggests that the splicing machinery has suboptimal efficiency and fidelity leading to substantial processing inaccuracy. Here we discuss a recently published article1 that extends observations that cells rely on nonsense- mediated mRNA decay (NMD) to compensate for such suboptimal processing accuracy. Intriguingly these authors provide evidence for a strong selective pressure in favour of premature termination of mRNA translation in the event of intron retention. The analysis presented implies a positive role of NMD in transcript diversification through alternative splicing and suggest that this ancient surveillance mechanism may have co-evolved with intron acquisition born from the need for quality control of splicing patterns. BioEssays 30:926,928, 2008. © 2008 Wiley Periodicals, Inc. [source]

Crystallization and preliminary X-ray diffraction analysis of the C-terminal domain of the human spliceosomal DExD/H-box protein hPrp22

ACTA CRYSTALLOGRAPHICA SECTION F (ELECTRONIC), Issue 9 2009
Denis Kudlinzki
The Homo sapiens DExD/H-box protein hPrp22 is a crucial component of the eukaryotic pre-mRNA splicing machinery. Within the splicing cycle, it is involved in the ligation of exons and generation of the lariat and it additionally catalyzes the release of mature mRNA from the spliceosomal U5 snRNP. The yeast homologue of this protein, yPrp22, shows ATP-dependent RNA-helicase activity and is capable of unwinding RNA/RNA duplex molecules. A truncated construct coding for residues 950,1183 of human Prp22, comprising the structurally and functionally uncharacterized C-terminal domain, was cloned into an Escherichia coli expression vector. The protein was subsequently overproduced, purified and crystallized. The crystals obtained diffracted to 2.1,Ĺ resolution, belonged to the tetragonal space group P41212 or P43212, with unit-cell parameters a = b = 78.2, c = 88.4,Ĺ, and contained one molecule in the asymmetric unit. [source]

Hibernation as a far-reaching program for the modulation of RNA transcription

MICROSCOPY RESEARCH AND TECHNIQUE, Issue 8 2008
Manuela Malatesta
Abstract In eukaryotic cells, pre-mRNAs undergo several transformation steps to generate mature mRNAs ready to be exported to the cytoplasm. The molecular and structural apparatus for mRNA production is generally able to promptly respond to variations of metabolic demands. Hibernating mammals, which periodically enter a hypometabolic state, represent an interesting physiological model to investigate the adaptive morpho-functional modifications of the pre-mRNA transcriptional and processing machinery under extreme metabolic conditions. In this study, the subnuclear distribution of some transcriptional, splicing, and cleavage factors was investigated by ultrastructural immunocytochemistry in cell nuclei of the liver (a highly metabolizing organ involved in multiple regulatory functions) and the brown adipose tissue (responsible for nonshivering thermogenesis) from euthermic, hibernating, and arousing hazel dormice (Muscardinus avellanarius). Our observations demonstrate that, during hibernation, transcriptional activity significantly decreases and pre-mRNA processing factors undergo an intranuclear redistribution moving to domains usually devoid of such molecules; moreover, in hepatocytes, there is a preferential accumulation of pre-mRNAs at the splicing stage, whereas, in brown adipocytes, pre-mRNAs are mainly stored at the cleavage stage. Upon arousal, the pre-mRNAs at the cleavage stage are immediately utilized, while the maturation of pre-mRNAs at the splicing stage seems to be restored before transcription had taken place. Our data suggest a programmed intranuclear reorganization of the RNA maturation machinery aimed at efficiently and rapidly restoring the pre-mRNA processing, and, consequently, the specific cellular activities upon arousal. Once again natural hibernation appears as a highly programmed hypometabolic state rather than a simple fall of metabolic and physiological functions. Microsc. Res. Tech., 2008. © 2008 Wiley-Liss, Inc. [source]