<i>IFT52</i>mutations destabilize anterograde complex assembly, disrupt ciliogenesis and result in short rib polydactyly syndrome

Zhang, Wenjuan; Taylor, S. Paige; Nevarez, Lisette; Lachman, Ralph S.; Nickerson, Deborah A.; Bamshad, Michael J.; Krakow, Deborah; Cohn, Daniel H.

doi:10.1093/hmg/ddw241

Cited by 45 publications

(64 citation statements)

References 38 publications

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“…The data also establish the molecular basis of SRPS type IV and demonstrate that it is allelic with SRPS type II. Previous publications of SRPS and ATD cases from the ISDR have included 22 additional families with mutations in nine ciliary genes ( DYNC2H1, WDR34, IFT52, ICK, INTU, IFT81, DYNC2LI1, IFT43 , and WDR35 ), including six genes not represented among the current set of families (Duran, et al., ; Huber et al., ; Taylor et al., ; Taylor et al., ; Toriyama et al., ; Zhang et al., ). Mutations have also been reported in families in this spectrum of disease in six additional genes, C21ORF2 (McInerney‐Leo et al., ; Wheway et al., ), TCTEX1D2 (Gholkar et al., ), IFT172 (Halbritter et al., ), KIAA0586 (Alby et al., ), CEP120 (Shaheen et al., ), or IFT122 (Walczak‐Sztulpa et al., ), bringing the number of known skeletal ciliopathy genes to twenty six.…”

Section: Discussionmentioning

confidence: 99%

“…We identified causal variants in only six out of 152 families and only two of the 14 genes ( TRAF3IP1 and IFT80 ) that encode IFT‐B components. In the total ISDR skeletal ciliopathy cohort, there was also one family with unclassified SRPS due to IFT52 mutations (Zhang et al., ) and one family each with ATD and SRPS type III due to IFT81 mutations (Duran, et al., ), so overall nine out of 175 (5%) families studied had IFT‐B defects. It is unclear why the genes encoding anterograde IFT components are less frequently mutated than retrograde molecules in the SRPS‐ATD spectrum of disease.…”

Section: Discussionmentioning

confidence: 99%

“…Mutations in all six of the genes encoding retrograde transport (IFT‐A) components ( IFT43 (Arts et al., ), WDR19 (Bredrup, et al., ), IFT122 (Walczak‐Sztulpa et al., ), TTC21B (Davis et al., ), WDR35 (Mill et al., ), and IFT140 (Perrault et al., ; Schmidts et al., )) have also been characterized in these disorders. By contrast, mutations in only a subset of the genes encoding IFT‐B complex members, IFT80 (Cavalcanti et al., ), IFT172 (Halbritter et al., ), IFT52 (Zhang et al., ), and IFT81 (Duran, et al., ), have been identified among the skeletal ciliopathies. In addition, mutations in two genes ( EVC (Ruiz‐Perez et al., ), EVC2 (Galdzicka et al., )) that encode basal body proteins, the NEK1 kinase gene (Thiel et al., ) and the gene encoding its interacting protein C21ORF2 (McInerney‐Leo et al., ; Wheway et al., ), the ICK MAP‐like kinase gene (Taylor et al., ), the INTU planar cell polarity (PCP) gene (Toriyama et al., ), the KIAA0586 (Alby et al., ) centrosomal protein gene, and the CEP120 core centriolar protein gene (Shaheen et al., ) have also been reported.…”

Section: Introductionmentioning

confidence: 99%

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Expanding the genetic architecture and phenotypic spectrum in the skeletal ciliopathies

et al. 2017

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Defects in the biosynthesis and/or function of primary cilia cause a spectrum of disorders collectively referred to as ciliopathies. A subset of these disorders is distinguished by profound abnormalities of the skeleton that include a long narrow chest with markedly short ribs, extremely short limbs, and polydactyly. These include the perinatal lethal short-rib polydactyly syndromes (SRPS) and the less severe asphyxiating thoracic dystrophy (ATD), Ellis-van Creveld (EVC) syndrome, and cranioectodermal dysplasia (CED) phenotypes. To identify new genes and define the spectrum of mutations in the skeletal ciliopathies, we analyzed 152 unrelated families with SRPS, ATD, and EVC. Causal variants were discovered in 14 genes in 120 families, including one newly associated gene and two genes previously associated with other ciliopathies. These three genes encode components of three different ciliary complexes; FUZ, which encodes a planar cell polarity complex molecule; TRAF3IP1, which encodes an anterograde ciliary transport protein; and LBR, which encodes a nuclear membrane protein with sterol reductase activity. The results established the molecular basis of SRPS type IV, in which mutations were identified in four different ciliary genes.The data provide systematic insight regarding the genotypes associated with a large cohort of these genetically heterogeneous phenotypes and identified new ciliary components required for normal skeletal development.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Expanding the genetic architecture and phenotypic spectrum in the skeletal ciliopathies

et al. 2017

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“…It is involved in anterograde transport from the base to the tip of cilia (Perrault et al., ). All six components of the IFT‐A complex have been associated with skeletal ciliopathies (Huber & Cormier‐Daire, ) and so far 4 out of 16 members of the IFT‐B complex have been associated with skeletal ciliopathies ( IFT52 , IFT80, IFT172, IFT81 ) (Beales et al., ; Duran et al., ; Halbritter et al., ; Zhang et al., ). Compound heterozygous mutation in IFT81 (p.Leu29Phe;p.Arg512* and p.Leu262*;c.1303_1305delCTT, respectively) have been shown to cause phenotypes within ATD and short‐rib polydactyly syndrome type II (Duran et al., ).…”

Section: Discussionmentioning

confidence: 99%

Alu-Alu mediated intragenic duplications in IFT81 and MATN3 are associated with skeletal dysplasias

et al. 2018

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Skeletal dysplasias are a diverse group of rare Mendelian disorders with clinical and genetic heterogeneity. Here, we used targeted copy number variant (CNV) screening and identified intragenic exonic duplications, formed through Alu-Alu fusion events, in two individuals with skeletal dysplasia and negative exome sequencing results. First, we detected a homozygous tandem duplication of exon 9 and 10 in IFT81 in a boy with Jeune syndrome, or short-rib thoracic dysplasia (SRTD) (MIM# 208500). Western blot analysis did not detect any wild-type IFT81 protein in fibroblasts from the patient with the IFT81 duplication, but only a shorter isoform of IFT81 that was also present in the normal control samples. Complementary zebrafish studies suggested that loss of full-length IFT81 protein but expression of a shorter form of IFT81 protein affects the phenotype while being compatible with life. Second, a de novo tandem duplication of exons 2 to 5 in MATN3 was identified in a girl with multiple epiphyseal dysplasia (MED) type 5 (MIM# 607078). Our data highlights the importance of detection and careful characterization of intragenic duplication CNVs, presenting them as a novel and very rare genetic mechanism in IFT81-related Jeune syndrome and MATN3-related MED.

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“…For example, hypomorphic mutations in IFT172 result in the skeletal ciliopathies JATD and Mainzer–Saldino syndrome 128 , or VACTERL (vertebral anomalies, anal atresia, cardiac defects, tracheoesophageal fistula and/or esophageal atresia, renal and radial anomalies and limb defects) associated with hydrocephalus 129 . Mutations in IFT52 and IFT80 also cause skeletal ciliopathies 130,131 . The disruption of IFT57 is associated with OFD, as well as short stature and brachymesophalangia 132 .…”

Section: Transition Zone Is a Hotspot For Ciliopathiesmentioning

confidence: 99%

Genes and molecular pathways underpinning ciliopathies

Reiter

Leroux

2017

Nat Rev Mol Cell Biol

1,239

1,298

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Motile and non-motile (primary) cilia are nearly ubiquitous cellular organelles. The dysfunction of cilia causes diseases known as ciliopathies. The number of reported ciliopathies (currently 35) is increasing, as is the number of established (187) and candidate (241) ciliopathy-associated genes. The characterization of ciliopathy-associated proteins and phenotypes has improved our knowledge of ciliary functions. In particular, investigating ciliopathies has helped us to understand the molecular mechanisms by which the cilium-associated basal body functions in early ciliogenesis, as well as how the transition zone functions in ciliary gating, and how intraflagellar transport enables cargo trafficking and signalling. Both basic biological and clinical studies are uncovering novel ciliopathies and the ciliary proteins involved. The assignment of these proteins to different ciliary structures, processes and ciliopathy subclasses (first order and second order) provides insights into how this versatile organelle is built, compartmentalized and functions in diverse ways that are essential for human health.

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IFT52mutations destabilize anterograde complex assembly, disrupt ciliogenesis and result in short rib polydactyly syndrome

Cited by 45 publications

References 38 publications

Expanding the genetic architecture and phenotypic spectrum in the skeletal ciliopathies

Expanding the genetic architecture and phenotypic spectrum in the skeletal ciliopathies

Alu-Alu mediated intragenic duplications in IFT81 and MATN3 are associated with skeletal dysplasias

Genes and molecular pathways underpinning ciliopathies

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