Molecular basis of ciliary defects caused by compound heterozygous IFT144/WDR19 mutations found in cranioectodermal dysplasia

Abstract Primary cilia contain specific proteins to achieve their functions as cellular antennae. Ciliary protein trafficking is mediated by the intraflagellar transport (IFT) machinery containing the IFT-A and IFT-B complexes. Mutations in genes encoding the IFT-A subunits (IFT43, IFT121/WDR35, IFT122, IFT139/TTC21B, IFT140, and IFT144/WDR19) often result in skeletal ciliopathies, including cranioectodermal dysplasia (CED). We here characterized the molecular and cellular defects of CED caused by compound heterozygous mutations in IFT144 [the missense variant IFT144(L710S) and the nonsense variant IFT144(R1103*)]. These two variants were distinct with regard to their interactions with other IFT-A subunits and with the IFT-B complex. When exogenously expressed in IFT144-knockout (KO) cells, IFT144(L710S) as well as IFT144(WT) rescued both moderately compromised ciliogenesis and the abnormal localization of ciliary proteins. As the homozygous IFT144(L710S) mutation was found to cause autosomal recessive retinitis pigmentosa, IFT144(L710S) is likely to be hypomorphic at the cellular level. In striking contrast, the exogenous expression of IFT144(R1103*) in IFT144-KO cells exacerbated the ciliogenesis defects. The expression of IFT144(R1103*) together with IFT144(WT) restored the abnormal phenotypes of IFT144-KO cells. However, the coexpression of IFT144(R1103*) with the hypomorphic IFT144(L710S) variant in IFT144-KO cells, which mimics the genotype of compound heterozygous CED patients, resulted in severe ciliogenesis defects. Taken together, these observations demonstrate that compound heterozygous mutations in IFT144 cause severe ciliary defects via a complicated mechanism, where one allele can cause severe ciliary defects when combined with a hypomorphic allele.

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Combinations of deletion and missense variations of the dynein-2 DYNC2LI1 subunit found in skeletal ciliopathies cause ciliary defects

Scientific Reports ◽

10.1038/s41598-021-03950-0 ◽

2022 ◽

Vol 12 (1) ◽

Author(s):

Hantian Qiu ◽

Yuta Tsurumi ◽

Yohei Katoh ◽

Kazuhisa Nakayama

Keyword(s):

Protein Trafficking ◽

Intraflagellar Transport ◽

Missense Variant ◽

Compound Heterozygous ◽

Wild Type ◽

Normal Phenotype ◽

Deletion Variant ◽

Extracellular Signals ◽

Pathogenic Variants ◽

Genes Encoding

AbstractCilia play crucial roles in sensing and transducing extracellular signals. Bidirectional protein trafficking within cilia is mediated by the intraflagellar transport (IFT) machinery containing IFT-A and IFT-B complexes, with the aid of kinesin-2 and dynein-2 motors. The dynein-2 complex drives retrograde trafficking of the IFT machinery after its transportation to the ciliary tip as an IFT cargo. Mutations in genes encoding the dynein-2-specific subunits (DYNC2H1, WDR60, WDR34, DYNC2LI1, and TCTEX1D2) are known to cause skeletal ciliopathies. We here demonstrate that several pathogenic variants of DYNC2LI1 are compromised regarding their ability to interact with DYNC2H1 and WDR60. When expressed in DYNC2LI1-knockout cells, deletion variants of DYNC2LI1 were unable to rescue the ciliary defects of these cells, whereas missense variants, as well as wild-type DYNC2LI1, restored the normal phenotype. DYNC2LI1-knockout cells coexpressing one pathogenic deletion variant together with wild-type DYNC2LI1 demonstrated a normal phenotype. In striking contrast, DYNC2LI1-knockout cells coexpressing the deletion variant in combination with a missense variant, which mimics the situation of cells of compound heterozygous ciliopathy individuals, demonstrated ciliary defects. Thus, DYNC2LI1 deletion variants found in individuals with skeletal ciliopathies cause ciliary defects when combined with a missense variant, which expressed on its own does not cause substantial defects.

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Lateral transport of Smoothened from the plasma membrane to the membrane of the cilium

The Journal of Cell Biology ◽

10.1083/jcb.200907126 ◽

2009 ◽

Vol 187 (3) ◽

pp. 365-374 ◽

Cited By ~ 186

Author(s):

Ljiljana Milenkovic ◽

Matthew P. Scott ◽

Rajat Rohatgi

Keyword(s):

Plasma Membrane ◽

Protein Trafficking ◽

Primary Cilia ◽

Protein Transport ◽

Transmembrane Protein ◽

Signaling Proteins ◽

Lateral Transport ◽

Transport Pathway ◽

Ciliary Membrane ◽

Specific Proteins

The function of primary cilia depends critically on the localization of specific proteins in the ciliary membrane. A major challenge in the field is to understand protein trafficking to cilia. The Hedgehog (Hh) pathway protein Smoothened (Smo), a 7-pass transmembrane protein, moves to cilia when a ligand is received. Using microscopy-based pulse-chase analysis, we find that Smo moves through a lateral transport pathway from the plasma membrane to the ciliary membrane. Lateral movement, either via diffusion or active transport, is quite distinct from currently studied pathways of ciliary protein transport in mammals, which emphasize directed trafficking of Golgi-derived vesicles to the base of the cilium. We anticipate that this alternative route will be used by other signaling proteins that function at cilia. The path taken by Smo may allow novel strategies for modulation of Hh signaling in cancer and regeneration.

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BLOC-1 is required for selective membrane protein trafficking from endosomes to primary cilia

The Journal of Cell Biology ◽

10.1083/jcb.201611138 ◽

2017 ◽

Vol 216 (7) ◽

pp. 2131-2150 ◽

Cited By ~ 30

Author(s):

William J. Monis ◽

Victor Faundez ◽

Gregory J. Pazour

Keyword(s):

Protein Trafficking ◽

Primary Cilia ◽

Recycling Endosome ◽

Ciliary Membrane ◽

Membrane Protein Trafficking ◽

Selective Membrane ◽

Specific Proteins ◽

Lysosome Related Organelles ◽

Extracellular Environment

Primary cilia perceive the extracellular environment through receptors localized in the ciliary membrane, but mechanisms directing specific proteins to this domain are poorly understood. To address this question, we knocked down proteins potentially important for ciliary membrane targeting and determined how this affects the ciliary trafficking of fibrocystin, polycystin-2, and smoothened. Our analysis showed that fibrocystin and polycystin-2 are dependent on IFT20, GMAP210, and the exocyst complex, while smoothened delivery is largely independent of these components. In addition, we found that polycystin-2, but not smoothened or fibrocystin, requires the biogenesis of lysosome-related organelles complex-1 (BLOC-1) for ciliary delivery. Consistent with the role of BLOC-1 in sorting from the endosome, we find that disrupting the recycling endosome reduces ciliary polycystin-2 and causes its accumulation in the recycling endosome. This is the first demonstration of a role for BLOC-1 in ciliary assembly and highlights the complexity of pathways taken to the cilium.

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Genetic interaction of mammalian IFT-A paralogs regulates cilia disassembly, ciliary protein trafficking, Hedgehog signaling and embryogenesis

10.1101/803544 ◽

2019 ◽

Cited By ~ 2

Author(s):

Wei Wang ◽

Bailey A. Allard ◽

Tana S. Pottorf ◽

Jay L. Vivian ◽

Pamela V. Tran

Keyword(s):

Protein Trafficking ◽

Hedgehog Signaling ◽

Double Mutant ◽

Primary Cilia ◽

Genetic Interaction ◽

Protein Complexes ◽

Intraflagellar Transport ◽

Retrograde Transport ◽

Ciliary Protein ◽

Transport Defect

AbstractPrimary cilia are sensory organelles that are essential for eukaryotic development and health. These antenna-like structures are synthesized by intraflagellar transport protein complexes, IFT-B and IFT-A, which mediate bi-directional protein trafficking along the ciliary axoneme. Here using mouse embryonic fibroblasts (MEF), we investigate the ciliary roles of two mammalian orthologues of Chlamydomonas IFT-A gene, IFT139, namely Thm1 (also known as Ttc21b) and Thm2 (Ttc21a). Thm1 loss causes perinatal lethality, and Thm2 loss allows survival into adulthood. At E14.5, the number of Thm1;Thm2 double mutant embryos is lower than that for a Mendelian ratio, indicating deletion of Thm1 and Thm2 causes mid-gestational lethality. We examined the ciliary phenotypes of mutant MEF. Thm1-mutant MEF show decreased cilia assembly, shortened primary cilia, a retrograde IFT defect for IFT and BBS proteins, and reduced ciliary entry of membrane-associated proteins. Thm1-mutant cilia also show a retrograde transport defect for the Hedgehog transducer, Smoothened, and an impaired response to Smoothened agonist, SAG. Thm2-null MEF show normal ciliary dynamics and Hedgehog signaling, but additional loss of a Thm1 allele impairs response to SAG. Further, Thm1;Thm2 double mutant MEF show enhanced cilia disassembly, and relative to Thm1-null MEF, increased impairment of IFT81 retrograde transport and of INPP5E ciliary import. Thus, Thm1 and Thm2 have unique and redundant roles in MEF. Thm1 regulates cilia assembly, and together with Thm2, cilia disassembly. Moreover, Thm1 alone and together with Thm2, regulates ciliary protein trafficking, Hedgehog signaling, and embryogenesis. These findings shed light on mechanisms underlying Thm1-, Thm2- or IFT-A-mediated ciliopathies.

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Deletion of INPP5E in the murine retina impairs axoneme formation and prevents photoreceptor disc morphogenesis

10.1101/2020.11.29.403030 ◽

2020 ◽

Author(s):

Ali S. Sharif ◽

Cecilia D. Gerstner ◽

Martha A. Cady ◽

Vadim Y. Arshavsky ◽

Christina Mitchell ◽

...

Keyword(s):

Outer Segment ◽

Secretory Pathway ◽

Primary Cilia ◽

Catalytic Domain ◽

Intraflagellar Transport ◽

Joubert Syndrome ◽

Structural Proteins ◽

Missense Mutations ◽

Outer Segments ◽

Specific Proteins

ABSTRACTINPP5E (pharbin) is a ubiquitously-expressed, farnesylated phosphatidylinositol polyphosphate 5’-phosphatase which modulates the phosphoinositide composition of membranes. INPP5E resides in primary cilia, and mutations or loss of INPP5E are associated with ciliary dysfunction. INPP5E missense mutations of the phosphatase catalytic domain cause Joubert syndrome in humans, a syndromic ciliopathy affecting multiple tissues including brain, liver, kidney and retina. We show that, differing from other primary cilia, INPP5E is present in the wildtype photoreceptor inner segment and absent in the outer segment--a modified primary cilium dedicated to phototransduction. We generated Inpp5eF/F;Six3Cre (in short, retInpp5e-/-) mice which exhibit a rapidly progressing rod-cone degeneration nearly completed by postnatal day 21 (P21) in the central retina. Mutant cone outer segments contain vesicles instead of discs as early as P8. While P10 mutant outer segments contain phototransduction and structural proteins, they do not form axonemes and fail to elaborate disc membranes. Connecting cilia of retInpp5e-/- rods appear normal, although IFT-B/A particles accumulate at their distal ends suggesting disrupted intraflagellar transport. These results show that ablation of INPP5E does not impair the secretory pathway responsible for delivery of outer segment-specific proteins, but blocks axonemal extension and prevents disc morphogenesis.

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The IFT-A complex regulates Shh signaling through cilia structure and membrane protein trafficking

The Journal of Cell Biology ◽

10.1083/jcb.201110049 ◽

2012 ◽

Vol 197 (6) ◽

pp. 789-800 ◽

Cited By ~ 137

Author(s):

Karel F. Liem ◽

Alyson Ashe ◽

Mu He ◽

Peter Satir ◽

Jennifer Moran ◽

...

Keyword(s):

Membrane Protein ◽

Sonic Hedgehog ◽

Protein Trafficking ◽

Primary Cilia ◽

Intraflagellar Transport ◽

Loss Of Function ◽

Shh Signaling ◽

Shh Pathway ◽

Membrane Protein Trafficking ◽

Ectopic Activation

Two intraflagellar transport (IFT) complexes, IFT-A and IFT-B, build and maintain primary cilia and are required for activity of the Sonic hedgehog (Shh) pathway. A weak allele of the IFT-A gene, Ift144, caused subtle defects in cilia structure and ectopic activation of the Shh pathway. In contrast, strong loss of IFT-A, caused by either absence of Ift144 or mutations in two IFT-A genes, blocked normal ciliogenesis and decreased Shh signaling. In strong IFT-A mutants, the Shh pathway proteins Gli2, Sufu, and Kif7 localized correctly to cilia tips, suggesting that these pathway components were trafficked by IFT-B. In contrast, the membrane proteins Arl13b, ACIII, and Smo failed to localize to primary cilia in the absence of IFT-A. We propose that the increased Shh activity seen in partial loss-of-function IFT-A mutants may be a result of decreased ciliary ACIII and that the loss of Shh activity in the absence of IFT-A is a result of severe disruptions of cilia structure and membrane protein trafficking.

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Ift172 conditional knockout mice exhibit rapid retinal degeneration and protein trafficking defects

10.1101/210617 ◽

2017 ◽

Author(s):

Priya R Gupta ◽

Nachiket Pendse ◽

Scott H Greenwald ◽

Mihoko Leon ◽

Qin Liu ◽

...

Keyword(s):

Retinal Degeneration ◽

Protein Trafficking ◽

Primary Cilia ◽

Molecular Mechanisms ◽

Outer Nuclear Layer ◽

Intraflagellar Transport ◽

Conditional Knockout ◽

Photoreceptor Outer Segments ◽

Outer Segments ◽

Trafficking Defects

AbstractIntraflagellar transport (IFT) is a bidirectional transport process that occurs along primary cilia and specialized sensory cilia, such as photoreceptor outer-segments. Genes coding for various IFT components are associated with ciliopathies. Mutations in IFT172 lead to diseases ranging from isolated retinal degeneration to severe syndromic ciliopathies. In this study, we created a mouse model of IFT172-associated retinal degeneration to investigate the ocular disease mechanism. We found that depletion of IFT172 in rod photoreceptors leads to a rapid degeneration of the retina, with severely reduced electroretinography responses by one month and complete outer-nuclear layer degeneration by two months. We investigated molecular mechanisms of degeneration and show that IFT172 protein reduction leads to mislocalization of specific photoreceptor outer-segments proteins (RHO, RP1, IFT139), aberrant light-driven translocation of alpha transducin and altered localization of glioma-associated oncogene family member 1 (GLI1). This murine model recapitulates the retinal phenotype seen in patients with IFT172-associated blindness and can be used for in vivo testing of ciliopathy therapies.

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