SNX10 gene mutation leading to osteopetrosis with dysfunctional osteoclasts

Stattin, Eva‐Lena; Henning, Petra; Klar, Joakim; McDermott, Emma; Stecksén‐Blicks, Christina; Sandström, Per-Erik; Kellgren, Therese G.; Rydén, Patrik; Hallmans, Göran; Lönnerholm, Torsten; Ameur, Adam; Helfrich, Miep; Coxon, Fraser P.; Dahl, Niklas; Wikström, Johan; Lerner, Ulf H.

doi:10.1038/s41598-017-02533-2

Cited by 45 publications

(62 citation statements)

References 48 publications

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Section: Discussionmentioning

confidence: 73%

“…Our cofractionation and localization experiments indicate interactions between PIKfyve and Snx10, the sorting nexin that causes osteopetrorickets when mutated in mice or humans. 10,26,27 PIKfyve and Snx10 cofractionated with early endosomes and they coprecipitated from cell lysates, suggesting their direct interaction or participation in a multiprotien complex. Consistent with this, colocalization of Snx10 and PIKfyve was observed by immunofluorescence of osteoclasts and gastric zymogenic cells, another cell type whose function was shown by us to be severely compromised by Snx10 mutations.…”

Section: Ctsb Modulates Lysosome Biogenesismentioning

confidence: 99%

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Snx10 and PIKfyve are required for lysosome formation in osteoclasts

Sultana

Morse

Picotto

et al. 2019

J of Cellular Biochemistry

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Bone resorption and organelle homeostasis in osteoclasts require specialized intracellular trafficking. Sorting nexin 10 (Snx10) is a member of the sorting nexin family of proteins that plays crucial roles in cargo sorting in the endosomal pathway by its binding to phosphoinositide(3)phosphate (PI3P) localized in early endosomes. We and others have shown previously that the gene encoding sorting Snx10 is required for osteoclast morphogenesis and function, as osteoclasts from humans and mice lacking functional Snx10 are dysfunctional. To better understand the role and mechanisms by which Snx10 regulates vesicular transport, the aim of the present work was to study PIKfyve, another PI3P‐binding protein, which phosphorylates PI3P to PI(3,5)P2. PI(3,5)P2 is known to be required for endosome/lysosome maturation, and the inhibition of PIKfyve causes endosome enlargement. Overexpression of Snx10 also induces accumulation of early endosomes suggesting that both Snx10 and PIKfyve are required for normal endosome/lysosome transition. Apilimod is a small molecule with specific, nanomolar inhibitory activity on PIKfyve but only in the presence of key osteoclast factors CLCN7, OSTM1, and Snx10. This observation suggests that apilimod's inhibitory effects are mediated by endosome/lysosome disruption. Here we show that both Snx10 and PIKfyve colocalize to early endosomes in osteoclasts and coimmunoprecipitate in vesicle fractions. Treatment with 10 nM apilimod or genetic deletion of PIKfyve in cells resulted in the accumulation of early endosomes, and in the inhibition of osteoclast differentiation, lysosome formation, and secretion of TRAP from differentiated osteoclasts. Snx10 and PIKfyve also colocalized in gastric zymogenic cells, another cell type impacted by Snx10 mutations. Apilimod‐specific inhibition of PIKfyve required Snx10 expression, as it did not inhibit lysosome biogenesis in Snx10‐deficient osteoclasts. These findings suggest that Snx10 and PIKfyve are involved in the regulation of endosome/lysosome homeostasis via the synthesis of PI(3,5)P2 and may point to a new strategy to prevent bone loss.

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Section: Discussionmentioning

confidence: 73%

Section: Ctsb Modulates Lysosome Biogenesismentioning

confidence: 99%

Snx10 and PIKfyve are required for lysosome formation in osteoclasts

Sultana

Morse

Picotto

et al. 2019

J of Cellular Biochemistry

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“…(osteopetrosis-associated transmembrane protein 1), and SNX10 (sorting nexin 10) account for 1-5% of ARO cases each. [3][4][5][6][7][8] ARO occurs in an estimated 1 in 250 000 people. In addition, a form termed exceptional intermediate autosomal recessive osteopetrosis (IARO) has been described, with mutations in CLCN7, PLEKHM1 (pleckstrin homology domain-containing family M with RUN domain-member 1), and TCIRG1.…”

Section: Intermediate Autosomal Recessive Osteopetrosis With a Large mentioning

confidence: 99%

“…Many genes are implied in ARO such as TCIRG1 (T‐cell immune regulator 1) and CLCN7 (chloride voltage‐gated channel 7), which are responsible for 70% of genetically confirmed ARO. Four additional genes RANKL (receptor activator of NF‐κB ligand), RANK (receptor activator of NF‐κB), OSTM1 (osteopetrosis‐associated transmembrane protein 1), and SNX10 (sorting nexin 10) account for 1‐5% of ARO cases each . ARO occurs in an estimated 1 in 250 000 people.…”

mentioning

confidence: 99%

Intermediate autosomal recessive osteopetrosis with a large noncoding deletion in SNX10: A case report

Baer

Schaefer

Michot

et al. 2019

Pediatric Blood & Cancer

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“…Subsequent studies have revealed additional mutations in SNX10, including nonsense, mis-sense, and splicing defect mutations, that cause ARO in patients of diverse ethnic origins in Europe, North America and Asia. It is currently estimated that mutations in SNX10 account for 5% of ARO cases globally (Palagano et al, 2018;Pangrazio et al, 2013;Stattin et al, 2017). The specific symptoms of patients carrying distinct SNX10 mutations vary, but several symptoms are characteristic; these include early age of onset, significantly increased bone mass, anemia, hepatosplenomegaly, and impaired vision and hearing that are caused by gradual closure of skull foramina arising from reduced bone resorption.…”

mentioning

confidence: 99%

R51Q SNX10 induces osteopetrosis by promoting uncontrolled fusion of monocytes to form giant, non-functional osteoclasts

Barnea

Stein

Winograd‐Katz

et al. 2018

Preprint

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In this study we report on the establishment and characterization of a novel knock-in mouse model that is homozygous for the R51Q mutation in the sorting nexin 10 (SNX10) protein. This mutation leads to massive, early-onset, and widespread osteopetrosis in the mutant mice, similar to that observed in humans who are homozygous for this mutation. The diseased mice exhibit multiple additional characteristics of the corresponding human osteopetrosis, including missing and impacted teeth, occasional osteomyelitis, stunted growth, failure to thrive, and a significantly-reduced lifespan. The phenotype of homozygous R51Q SNX10 osteoclasts is unique and defines a novel form of ARO that combines both lack of bone-resorbing activity and reduced cell numbers in vivo. Furthermore, mutant osteoclasts grown on bone develop a giant cell morphology, reaching sizes that are up to three orders of magnitude larger than osteoclasts from wild-type or heterozygous mice. These large osteoclasts display poor survival in vitro, which may account for their fewer numbers in vivo. Electron microscopy studies indicate that homozygous mutant osteoclasts exhibit severely impaired ruffled borders and are incapable of resorbing bone, providing a clear cellular basis for the osteopetrotic phenotype. We propose that the R51Q SNX10 mutation directly causes osteoporosis by affecting both osteoclast formation and function.We further conclude that the maximal size of osteoclasts is determined by an active and geneticallyregulated mechanism in which SNX10 participates, and that it is disrupted by the R51Q SNX10 mutation.

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SNX10 gene mutation leading to osteopetrosis with dysfunctional osteoclasts

Cited by 45 publications

References 48 publications

Snx10 and PIKfyve are required for lysosome formation in osteoclasts

Snx10 and PIKfyve are required for lysosome formation in osteoclasts

Intermediate autosomal recessive osteopetrosis with a large noncoding deletion in SNX10: A case report

R51Q SNX10 induces osteopetrosis by promoting uncontrolled fusion of monocytes to form giant, non-functional osteoclasts

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