57 research outputs found
Defective splicing, disease and therapy: searching for master checkpoints in exon definition
The number of aberrant splicing processes causing human disease is growing exponentially and many recent studies have uncovered some aspects of the unexpectedly complex network of interactions involved in these dysfunctions. As a consequence, our knowledge of the various cis- and trans-acting factors playing a role on both normal and aberrant splicing pathways has been enhanced greatly. However, the resulting information explosion has also uncovered the fact that many splicing systems are not easy to model. In fact we are still unable, with certainty, to predict the outcome of a given genomic variation. Nonetheless, in the midst of all this complexity some hard won lessons have been learned and in this survey we will focus on the importance of the wide sequence context when trying to understand why apparently similar mutations can give rise to different effects. The examples discussed in this summary will highlight the fine ‘balance of power’ that is often present between all the various regulatory elements that define exon boundaries. In the final part, we shall then discuss possible therapeutic targets and strategies to rescue genetic defects of complex splicing systems
Age-Related Alternative Splicing: Driver or Passenger in the Aging Process?
Alternative splicing changes are closely linked to aging, though it remains unclear if they are drivers or effects. As organisms age, splicing patterns change, varying gene isoform levels and functions. These changes may contribute to aging alterations rather than just reflect declining RNA quality control. Three main splicing types-intron retention, cassette exons, and cryptic exons-play key roles in age-related complexity. These events modify protein domains and increase nonsense-mediated decay, shifting protein isoform levels and functions. This may potentially drive aging or serve as a biomarker. Fluctuations in splicing factor expression also occur with aging. Somatic mutations in splicing genes can also promote aging and age-related disease. The interplay between splicing and aging has major implications for aging biology, though differentiating correlation and causation remains challenging. Declaring a splicing factor or event as a driver requires comprehensive evaluation of the associated molecular and physiological changes. A greater understanding of how RNA splicing machinery and downstream targets are impacted by aging is essential to conclusively establish the role of splicing in driving aging, representing a promising area with key implications for understanding aging, developing novel therapeutical options, and ultimately leading to an increase in the healthy human lifespan
An Amyloid-Like Pathological Conformation of TDP-43 Is Stabilized by Hypercooperative Hydrogen Bonds
TDP-43 is an essential RNA-binding protein forming aggregates in almost all cases of sporadic amyotrophic lateral sclerosis (ALS) and many cases of frontotemporal lobar dementia (FTLD) and other neurodegenerative diseases. TDP-43 consists of a folded N-terminal domain with a singular structure, two RRM RNA-binding domains, and a long disordered C-terminal region which plays roles in functional RNA regulatory assemblies as well as pernicious aggregation. Evidence from pathological mutations and seeding experiments strongly suggest that TDP-43 aggregates are pathologically relevant through toxic gain-of-harmful-function and/or harmful loss-of-native-function mechanisms. Recent, but not early, microscopy studies and the ability of TDP-43 aggregates to resist harsh treatment and to seed new pathological aggregates in vitro and in cells strongly suggest that TDP-43 aggregates have a self-templating, amyloid-like structure. Based on the importance of the Gln/Asn-rich 341–367 residue segment for efficient aggregation of endogenous TDP-43 when presented as a 12X-repeat and extensive spectroscopic and computational experiments, we recently proposed that this segment adopts a beta-hairpin structure that assembles in a parallel with a beta-turn configuration to form an amyloid-like structure. Here, we propose that this conformer is stabilized by an especially strong class of hypercooperative hydrogen bonding unique to Gln and Asn sidechains. The clinical existence of this conformer is supported by very recent LC-MS/MS characterization of TDP-43 from ex vivo aggregates, which show that residues 341–367 were protected in vivo from Ser phosphorylation, Gln/Asn deamidation and Met oxidation. Its distinct pattern of SDS-PAGE bands allows us to link this conformer to the exceptionally stable seed of the Type A TDP-43 proteinopathy.This work was supported by Grants SAF2013-49179-C2-2-R (DVL) and EU JPND AC14/00037 (DVL) and EU JPND RiModFTD, Italy, Ministero della Sanita’ (EB), and the Thierry Latran Foundation REHNPALS (EB).Peer reviewedPeer Reviewe
Tailored antisense oligonucleotides designed to correct aberrant splicing reveal actionable groups of mutations for rare genetic disorders
Effective translation of rare disease diagnosis knowledge into therapeutic applications is achievable within a reasonable timeframe; where mutations are amenable to current antisense oligonucleotide technology. In our study, we identified five distinct types of abnormal splice-causing mutations in patients with rare genetic disorders and developed a tailored antisense oligonucleotide for each mutation type using phosphorodiamidate morpholino oligomers with or without octa-guanidine dendrimers and 2′-O-methoxyethyl phosphorothioate. We observed variations in treatment effects and efficiencies, influenced by both the chosen chemistry and the specific nature of the aberrant splicing patterns targeted for correction. Our study demonstrated the successful correction of all five different types of aberrant splicing. Our findings reveal that effective correction of aberrant splicing can depend on altering the chemical composition of oligonucleotides and suggest a fast, efficient, and feasible approach for developing personalized therapeutic interventions for genetic disorders within short time frames
Complexities of 5'splice site definition: Implications in clinical analyses
In higher eukaryotes, the 5' splice site (5'ss) is initially recognized through an RNA-RNA interaction by U1 small nuclear ribonucleoprotein (U1 snRNP). This event represents one of the key steps in initial spliceosomal assembly and many disease-associated mutations in humans often disrupt this process. Beside base pair complementarity, 5'ss recognition can also be modified by additional factors such as RNA secondary structures or the specific binding of other nuclear proteins. In this work, we have focused on investigating a few examples of changes detected within the 5'ss in patients, that would not be immediately considered "disease causing mutations". We show that the splicing outcome of very similar mutations can be very different due to variations in trans-acting factor(s) interactions and specific context influences. Using several NF1 donor sites and SELEX approaches as experimental models, we have examined the binding properties of particular sequence motifs such as GGGU found in donor sites, and how the sequence context can change their interaction with hnRNPs such as H/F and A1/A2. Our results clearly show that even minor differences in local nucleotide context can differentially affect the binding ability of these factors to the GGGU core. Finally, using a previously identified mutation in KCNH2 that resulted in intron retention we show how very similar 5'ss mutations found in patients can have a very different splicing outcome due to the neighbouring sequence context, thus highlighting the general need to approach splicing problems with suitable experimental approaches
Physiological tissue-specific and age-related reduction of mouse TDP-43 levels is regulated by epigenetic modifications
The cellular level of TDP-43 (also known as TARDBP) is tightly regulated; increases or decreases in TDP-43 have deleterious effects in cells. The predominant mechanism responsible for the regulation of the level of TDP-43 is an autoregulatory negative feedback loop. In this study, we identified an in vivo cause-effect relationship between Tardbp gene promoter methylation and specific histone modification and the TDP-43 level in tissues of mice at two different ages. Furthermore, epigenetic control was observed in mouse and human cultured cell lines. In amyotrophic lateral sclerosis, the formation of TDP-43-containing brain inclusions removes functional protein from the system. This phenomenon is continuous but compensated by newly synthesized protein. The balance between sequestration and new synthesis might become critical with ageing, if accompanied by an epigenetic modification-regulated decrease in newly synthesized TDP-43. Sequestration by aggregates would then decrease the amount of functional TDP-43 to a level lower than those needed by the cell and thereby trigger the onset of symptoms
C–H insertion as a key step to spiro-oxetanes, scaffolds for drug discovery
A new route to spiro-oxetanes, potential scaffolds for drug discovery, is described. The route is based on the selective 1,4-C–H insertion reactions of metallocarbenes, generated from simple carbonyl precursors in flow or batch mode, to give spiro-β-lactones that are rapidly converted into spiro-oxetanes. The three-dimensional and lead like-properties of spiro-oxetanes is illustrated by the conversion of the 1-oxa-7-azaspiro[3,5]nonane scaffold into a range of functionalized derivatives
TDP-43 affects splicing profiles and isoform production of genes involved in the apoptotic and mitotic cellular pathways
In recent times, high-throughput screening analyses have broadly defined the RNA cellular targets of TDP-43, a nuclear factor involved in neurodegeneration. A common outcome of all these studies is that changing the expression levels of this protein can alter the expression of several hundred RNAs within cells. What still remains to be clarified is which changes represent direct cellular targets of TDP-43 or just secondary variations due to the general role played by this protein in RNA metabolism. Using an HTS-based splicing junction analysis we identified at least six bona fide splicing events that are consistent with being controlled by TDP-43. Validation of the data, both in neuronal and non-neuronal cell lines demonstrated that TDP-43 substantially alters the levels of isoform expression in four genes potentially important for neuropathology: MADD/IG20, STAG2, FNIP1 and BRD8. For MADD/IG20 and STAG2, these changes could also be confirmed at the protein level. These alterations were also observed in a cellular model that successfully mimics TDP-43 loss of function effects following its aggregation. Most importantly, our study demonstrates that cell cycle alterations induced by TDP-43 knockdown can be recovered by restoring the STAG2, an important component of the cohesin complex, normal splicing profile
New lysosomal acid lipase gene mutants explain the phenotype of Wolman disease and cholesteryl ester storage disease.
Deficiency of lysosomal acid lipase (LAL) leads to either Wolman disease(WD) or the more benign cholesteryl ester storage disease (CESD). To identifythe molecular basis of the different phenotypes we have characterised the LALgene mutations in three new patients with LAL deficiency. A patient with WD washomozygote for a null allele Y303X. The other two patients, with CESD, presentedeither homozygosity for T267I or compound heterozygosity consisting of Q64R andan exon 8 donor splice site substitution (G→A in position–1). The mutants T267I and Q64R and the previously reported L273S, G66V,and H274Y CESD substitutions, overexpressed in stable clones, were found to befully glycosylated and show an enzymatic activity of 3–8% of that ofnormal LAL. On the other hand, the Δ254–277 mutant proteinderived from exon 8 skipping and the Y303X protein were totally inactive. Bytransient transfection of hybrid minigene constructs, the CESD G→A(–1) substitution resulted in partial exon inclusion, thus allowing theproduction of a small amount of normal LAL mRNA and hence of a functionalenzyme. In contrast, a G→Asubstitution observed in WD at position +1 of the same exon 8 donor siteresulted in complete exon skipping and the sole production of an inactiveΔ254–277 protein.In conclusion,LAL genotypes determine the level of residual enzymatic activity, thusexplaining the severity of the phenotype.—Pagani, F., R. Pariyarath, R.Garcia, C. Stuani, A. B. Burlina, G. Ruotolo, M. Rabusin, and F. E. Baralle. Newlysosomal acid lipase gene mutants explain the phenotype of Wolman disease andcholesteryl ester storage disease. J. Lipid Res. 1998. 39:1382–1388
Congenital Insensitivity to Pain: Novel SCN9A Missense and In-Frame Deletion Mutations
SCN9A encodes the voltage-gated sodium channel Nav1.7, a protein highly expressed in pain-sensing neurons. Mutations in SCN9A cause three human pain disorders: bi-allelic loss of function mutations result in Channelopathy-associated Insensitivity to Pain (CIP), whereas activating mutations cause severe episodic pain in Paroxysmal Extreme Pain Disorder (PEPD) and Primary Erythermalgia (PE). To date, all mutations in SCN9A that cause a complete inability to experience pain are protein truncating and presumably lead to no protein being produced. Here, we describe the identification and functional characterization of two novel non-truncating mutations in families with CIP: a homozygously-inherited missense mutation found in a consanguineous Israeli Bedouin family (Nav1.7-R896Q) and a five amino acid in-frame deletion found in a sporadic compound heterozygote (Nav1.7-ΔR1370-L1374). Both of these mutations map to the pore region of the Nav1.7 sodium channel. Using transient transfection of PC12 cells we found a significant reduction in membrane localization of the mutant protein compared to the wild type. Furthermore, voltage clamp experiments of mutant-transfected HEK293 cells show a complete loss of function of the sodium channel, consistent with the absence of pain phenotype. In summary, this study has identified critical amino acids needed for the normal subcellular localization and function of Nav1.7. © 2010 Wiley-Liss, Inc
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