Defective minor spliceosome
            <scp>mRNA</scp>
            processing results in isolated familial growth hormone deficiency

Argente, Jesús; Flores, Raquel; Gutiérrez-Arumí, Armand; Verma, Bhupendra; Martos‐Moreno, Gabriel Ángel; Cuscò, Ivon; Oghabian, Ali; Chowen, Julie A.; Frilander, Mikko J.; Pérez-Jurado, Luís A.

doi:10.1002/emmm.201303573

Cited by 95 publications

(105 citation statements)

References 22 publications

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“…Isolated GHD can also be caused by biallelic mutations in RNPC3, which encodes a minor spliceosome protein required for U11/U12 small nuclear ribonucleoprotein (snRNP) formation and splicing of U12-type introns (33). Compound heterozygosity for a gene encoding a protein important for ciliary function (IFT172) can cause functional GHD, pituitary hypoplasia, and ectopic posterior pituitary (34), and also Alström syndrome, caused by a mutation of ALMS1 encoding a protein localized to the centrosomes and basal bodies of ciliated cells (35) is associated with GHD.…”

Section: Gh Deficiencymentioning

confidence: 99%

MECHANISMS IN ENDOCRINOLOGY: Novel genetic causes of short stature

Wit

Oostdijk

Losekoot

et al. 2016

European Journal of Endocrinology

141

132

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The fast technological development, particularly single nucleotide polymorphism array, array-comparative genomic hybridization, and whole exome sequencing, has led to the discovery of many novel genetic causes of growth failure. In this review we discuss a selection of these, according to a diagnostic classification centred on the epiphyseal growth plate. We successively discuss disorders in hormone signalling, paracrine factors, matrix molecules, intracellular pathways, and fundamental cellular processes, followed by chromosomal aberrations including copy number variants (CNVs) and imprinting disorders associated with short stature. Many novel causes of GH deficiency (GHD) as part of combined pituitary hormone deficiency have been uncovered. The most frequent genetic causes of isolated GHD are GH1 and GHRHR defects, but several novel causes have recently been found, such as GHSR, RNPC3, and IFT172 mutations. Besides well-defined causes of GH insensitivity (GHR, STAT5B, IGFALS, IGF1 defects), disorders of NFkB signalling, STAT3 and IGF2 have recently been discovered. Heterozygous IGF1R defects are a relatively frequent cause of prenatal and postnatal growth retardation. TRHA mutations cause a syndromic form of short stature with elevated T 3 /T 4 ratio. Disorders of signalling of various paracrine factors (FGFs, BMPs, WNTs, PTHrP/IHH, and CNP/NPR2) or genetic defects affecting cartilage extracellular matrix usually cause disproportionate short stature. Heterozygous NPR2 or SHOX defects may be found in w3% of short children, and also rasopathies (e.g., Noonan syndrome) can be found in children without clear syndromic appearance. Numerous other syndromes associated with short stature are caused by genetic defects in fundamental cellular processes, chromosomal abnormalities, CNVs, and imprinting disorders.

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Section: Gh Deficiencymentioning

confidence: 99%

MECHANISMS IN ENDOCRINOLOGY: Novel genetic causes of short stature

Wit

Oostdijk

Losekoot

et al. 2016

European Journal of Endocrinology

141

132

View full text Add to dashboard Cite

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“…Plusieurs autres pathologies affectant l'épissage en trans ont égale-ment été rapportées, dont une délétion du gène SF3B4 (splicing factor 3b subunit 4) associée au syndrome de Nager, une affection caractéri-sée par des dysostoses acrofaciales 2 [14], ou encore la Clericuzio-type poikiloderma, une maladie associée à un défaut de maturation du snARN U6 [15]. En outre, plusieurs mutations affectant le fonctionnement du splicéosome mineur ont été caractérisées dont celles à l'origine d'une déficience en hormone de croissance [16] ou d'une forme de nanisme affectant le gène MOPD I (microcephalic osteodysplastic primordial dwarfism) [17], ou encore de la sclérose latérale amyotrophique (SLA) [18]. Au-delà des mutations germinales, un large ensemble de mutations acquises ont été identifiées, en particulier dans les cancers.…”

Section: Organisation D'une Unité D'épissageunclassified

L’épissage des ARN pré-messagers : quand le splicéosome perd pied

et al. 2016

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“…In contrast, mutations in the 65K gene lead to rather dramatic activation of cryptic U2-type splice sites, but a very mild disease (IGHD1) phenotype with pituitary hypoplasia resulting in postnatal dwarfism, but apparently no other major symptoms. 28 While detailed transcriptome analysis of the MOPD1/TALS patients has not yet been described, the results seem somewhat counterintuitive, with more severe splicing defects leading to a milder disease. One possible explanation is that that perhaps the activation of cryptic U2-type splice sites seen with IGHD1 are better tolerated than the intron retention events reported with MOPD1/TALS.…”

Section: Implications For Human Diseasesmentioning

confidence: 99%

“…Importantly, this has been observed not only in human or mammalian cells, but also in Arabidopsis. 29 In contrast, under normal conditions the unspliced U12-type introns accumulate but there is no indication of concomitant activation of nearby cryptic splice sites, 19,20,28 arguing that U12-type introns are in fact recognized with similar efficiency as U2-type introns, but one or more subsequent steps in the spliceosome assembly or catalytic activation of the spliceosome are either slow or fail altogether, thus resulting in the elevated intron retention signal seen with the RT-PCR and RNAseq analyses (Fig. 1).…”

Section: Inefficient Versus Slow Splicing Of Minor Intronsmentioning

confidence: 99%

“…27 Regardless of whether the U12-type introns are spliced slowly or inefficiently, the molecular events responsible for the elevated retention levels of U12-type introns appear to take place after the intron recognition step. Inhibition of intron recognition step either by human disease-causing mutations 28 or by knocking down specific protein components in the U11/U12 di-snRNP responsible for the initial intron recognition 29,30 all lead to, in addition to a defect in the splicing of U12-type introns, activation of cryptic U2-type splice sites in the vicinity of a subset of U12-type introns. Importantly, this has been observed not only in human or mammalian cells, but also in Arabidopsis.…”

Section: Inefficient Versus Slow Splicing Of Minor Intronsmentioning

confidence: 99%

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Regulation of gene expression through inefficient splicing of U12-type introns

Niemelä

Frilander

2014

RNA Biology

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U 12-type introns are a rare class of nuclear introns that are removed by a dedicated U12-dependent spliceosome and are thought to regulate the expression of their target genes owing through their slower splicing reaction. Recent genome-wide studies on the splicing of U12-type introns are now providing new insights on the biological significance of this parallel splicing machinery. The new studies cover multiple different organisms and experimental systems, including human patient cells with mutations in the components of the minor spliceosome, zebrafish with similar mutations and various experimentally manipulated human cells and Arabidopsis plants.Here, we will discuss the potential implications of these studies on the understanding of the mechanism and regulation of the minor spliceosome, as well as their medical implications.

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Defective minor spliceosome mRNA processing results in isolated familial growth hormone deficiency

Cited by 95 publications

References 22 publications

MECHANISMS IN ENDOCRINOLOGY: Novel genetic causes of short stature

MECHANISMS IN ENDOCRINOLOGY: Novel genetic causes of short stature

L’épissage des ARN pré-messagers : quand le splicéosome perd pied

Regulation of gene expression through inefficient splicing of U12-type introns

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