RNA structure of trinucleotide repeats associated with human neurological diseases

Sobczak, Krzysztof; Mezer, Mateusz de; Michlewski, Gracjan; Król, Jacek; Krzyżosiak, Włodzimierz J.

doi:10.1093/nar/gkg766

Cited by 200 publications

(242 citation statements)

References 52 publications

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“…CAG repeat RNAs fold into secondary hairpin structures [9][10][11][12] . To give an idea of how these hairpins could look like, we performed in silico RNA-structure predictions of CAG repeat stretches with different repeat sizes.…”

Section: Mid1mentioning

confidence: 99%

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Translation of HTT mRNA with expanded CAG repeats is regulated by the MID1–PP2A protein complex

et al. 2013

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Expansion of CAG repeats is a common feature of various neurodegenerative disorders, including Huntington's disease. Here we show that expanded CAG repeats bind to a translation regulatory protein complex containing MID1, protein phosphatase 2A and 40S ribosomal S6 kinase. Binding of the MID1-protein phosphatase 2A protein complex increases with CAG repeat size and stimulates translation of the CAG repeat expansion containing messenger RNA in a MID1-, protein phosphatase 2A-and mammalian target of rapamycindependent manner. Our data indicate that pathological CAG repeat expansions upregulate protein translation leading to an overproduction of aberrant protein and suggest that the MID1-complex may serve as a therapeutic target for the treatment of CAG repeat expansion disorders.

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Section: Mid1mentioning

confidence: 99%

“…CAG sequences form double-stranded RNA structures, the stability of which increases with repeat-numbers [9][10][11] . For example the CAG repeat region of the HTT messenger RNA (mRNA) forms double-stranded hairpin structures 12 .…”

mentioning

confidence: 99%

Translation of HTT mRNA with expanded CAG repeats is regulated by the MID1–PP2A protein complex

et al. 2013

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“…On the other hand, recent studies revealed the importance of the ataxin-1-specific sequence context for the protein function and showed that even the high level expression of an expanded poly-Q tract protein in the nucleus may be insufficient to cause disease (14). In this light the RNA-mediated mechanisms of pathogenesis, similar to those proposed for DM (15) and FXTAS (16 -18) were also considered for polyglutamine diseases (17)(18)(19)(20)(21). According to this mechanism the expanded repeats in transcripts form long stable hairpins, which recruit double-stranded RNA-binding proteins in a repeat length-dependent manner, sequestering them from other transcripts and interfering with their normal functions (22).…”

mentioning

confidence: 98%

Imperfect CAG Repeats Form Diverse Structures in SCA1 Transcripts

Sobczak

Krzyżosiak

2004

Journal of Biological Chemistry

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The expanded CAG repeat in the coding sequence of the spinocerebellar ataxia type 1 (SCA1) gene is responsible for SCA1, one of the hereditary human neurodegenerative diseases. In the normal SCA1 alleles usually 1-3 CAT triplets break the continuity of the CAG repeat tracts. Here we show what is the structural role of the CAU interruptions in the SCA1 transcripts. Depending on their number and localization within the repeat tract the interruptions either enlarge the terminal loop of the hairpin formed by the repeats, nucleate the internal loops in its stem structure, or force the repeats to fold into two smaller hairpins. Thus, the interruptions destabilize the CAG repeat hairpin, which is likely to decrease its ability to participate in the putative RNA pathogenesis mechanism driven by the long CAG repeat hairpins.

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“…Among them were all the CNG repeats shown by our bioinformatic analysis to be the most abundant in transcripts [31]. The quasistable hairpin stem structure is composed of the periodically occurring C-G, G-C pairs and N-N mismatches, and the repeats show a tendency to assume several variantive alignments if this process is not suppressed by the presence of a suitable GC clamp [32]. The characteristic feature of hairpins formed by the CNG repeats is that their structure rigidity increases with repeat length.…”

Section: Cng Repeats Form Hairpin Structures In Transcriptsmentioning

confidence: 93%

“…Not only the diseases caused by the repeat expansions in non-coding sequences [42,51] but also the so-called polyglutamine diseases were considered in this context [31,32,52]. We have shown that at least the RNA hairpin structures, which are behind the RNA pathogenesis in myotonic dystrophy have the same architecture also in other TREDs-related transcripts [32,33]. Thus, they have the potential to interact with the specific dsRNA binding proteins.…”

Section: Unified Model Of Rna-mediated Pathogenesis In Tredsmentioning

confidence: 99%

Repetitive sequences that shape the human transcriptome

Jasinska¹,

Krzyżosiak²

2004

FEBS Letters

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Only a small portion of the total RNA transcribed in human cells becomes mature mRNA and constitutes the human transcriptome, which is context-dependent and varies with development, physiology and pathology. A small fraction of different repetitive sequences, which make up more than half of the human genome, is retained in mature transcripts and shapes their function. Among them are short interspersed elements (SINEs), of which Alu sequences are most frequent, and simple sequence repeats, which come in many varieties. In this review, we have focused on the structural and functional role of Alu elements and trinucleotide repeats in transcripts.

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RNA structure of trinucleotide repeats associated with human neurological diseases

Cited by 200 publications

References 52 publications

Translation of HTT mRNA with expanded CAG repeats is regulated by the MID1–PP2A protein complex

Translation of HTT mRNA with expanded CAG repeats is regulated by the MID1–PP2A protein complex

Imperfect CAG Repeats Form Diverse Structures in SCA1 Transcripts

Repetitive sequences that shape the human transcriptome

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