Characterization of ANKRD11 mutations in humans and mice related to KBG syndrome

Katherina Walz; Devon Cohen; Paul M. Neilsen; Joseph Foster; Francesco Brancati; Korcan Demir; Richard Fisher; Michelle Moffat; Nienke E. Verbeek; Kathrine Bjørgo; Adriana Lo Castro; Paolo Curatolo; Giuseppe Novelli; Clemer Abad; Cao Lei; Lily Zhang; Oscar Diaz-Horta; Juan I. Young; David F. Callen; Mustafa Tekin

doi:10.1007/s00439-014-1509-2

Characterization of ANKRD11 mutations in humans and mice related to KBG syndrome

Katherina Walz^*, Devon Cohen, Paul M. Neilsen, Joseph Foster, Francesco Brancati, Korcan Demir, Richard Fisher, Michelle Moffat, Nienke E. Verbeek, Kathrine Bjørgo, Adriana Lo Castro, Paolo Curatolo, Giuseppe Novelli, Clemer Abad, Cao Lei, Lily Zhang, Oscar Diaz-Horta, Juan I. Young, David F. Callen, Mustafa Tekin

^*Corresponding author for this work

Section Clinical Genetics

Research output: Contribution to journal › Article › Academic › peer-review

1 Citation (Scopus)

Abstract

Mutations in ANKRD11 have recently been reported to cause KBG syndrome, an autosomal dominant condition characterized by intellectual disability (ID), behavioral problems, and macrodontia. To understand the pathogenic mechanism that relates ANKRD11 mutations with the phenotype of KBG syndrome, we studied the cellular characteristics of wild-type ANKRD11 and the effects of mutations in humans and mice. We show that the abundance of wild-type ANKRD11 is tightly regulated during the cell cycle, and that the ANKRD11 C-terminus is required for the degradation of the protein. Analysis of 11 pathogenic ANKRD11 variants in humans, including six reported in this study, and one reported in the Ankrd11<sup>Yod/+</sup> mouse, shows that all mutations affect the C-terminal regions and that the mutant proteins accumulate aberrantly. In silico analysis shows the presence of D-box sequences that are signals for proteasome degradation. We suggest that ANKRD11 C-terminus plays an important role in regulating the abundance of the protein, and a disturbance of the protein abundance due to the mutations leads to KBG syndrome.

Original language	English
Pages (from-to)	181-190
Number of pages	10
Journal	Human Genetics
Volume	134
Issue number	2
DOIs	https://doi.org/10.1007/s00439-014-1509-2
Publication status	Published - 2015

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Walz, K., Cohen, D., Neilsen, P. M., Foster, J., Brancati, F., Demir, K., Fisher, R., Moffat, M., Verbeek, N. E., Bjørgo, K., Lo Castro, A., Curatolo, P., Novelli, G., Abad, C., Lei, C., Zhang, L., Diaz-Horta, O., Young, J. I., Callen, D. F., & Tekin, M. (2015). Characterization of ANKRD11 mutations in humans and mice related to KBG syndrome. Human Genetics, 134(2), 181-190. https://doi.org/10.1007/s00439-014-1509-2

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title = "Characterization of ANKRD11 mutations in humans and mice related to KBG syndrome",

abstract = "Mutations in ANKRD11 have recently been reported to cause KBG syndrome, an autosomal dominant condition characterized by intellectual disability (ID), behavioral problems, and macrodontia. To understand the pathogenic mechanism that relates ANKRD11 mutations with the phenotype of KBG syndrome, we studied the cellular characteristics of wild-type ANKRD11 and the effects of mutations in humans and mice. We show that the abundance of wild-type ANKRD11 is tightly regulated during the cell cycle, and that the ANKRD11 C-terminus is required for the degradation of the protein. Analysis of 11 pathogenic ANKRD11 variants in humans, including six reported in this study, and one reported in the Ankrd11Yod/+ mouse, shows that all mutations affect the C-terminal regions and that the mutant proteins accumulate aberrantly. In silico analysis shows the presence of D-box sequences that are signals for proteasome degradation. We suggest that ANKRD11 C-terminus plays an important role in regulating the abundance of the protein, and a disturbance of the protein abundance due to the mutations leads to KBG syndrome.",

author = "Katherina Walz and Devon Cohen and Neilsen, {Paul M.} and Joseph Foster and Francesco Brancati and Korcan Demir and Richard Fisher and Michelle Moffat and Verbeek, {Nienke E.} and Kathrine Bj{\o}rgo and {Lo Castro}, Adriana and Paolo Curatolo and Giuseppe Novelli and Clemer Abad and Cao Lei and Lily Zhang and Oscar Diaz-Horta and Young, {Juan I.} and Callen, {David F.} and Mustafa Tekin",

year = "2015",

doi = "10.1007/s00439-014-1509-2",

language = "English",

volume = "134",

pages = "181--190",

journal = "Human Genetics",

issn = "0340-6717",

publisher = "Springer-Verlag",

number = "2",

}

Walz, K, Cohen, D, Neilsen, PM, Foster, J, Brancati, F, Demir, K, Fisher, R, Moffat, M, Verbeek, NE, Bjørgo, K, Lo Castro, A, Curatolo, P, Novelli, G, Abad, C, Lei, C, Zhang, L, Diaz-Horta, O, Young, JI, Callen, DF & Tekin, M 2015, 'Characterization of ANKRD11 mutations in humans and mice related to KBG syndrome', Human Genetics, vol. 134, no. 2, pp. 181-190. https://doi.org/10.1007/s00439-014-1509-2

TY - JOUR

T1 - Characterization of ANKRD11 mutations in humans and mice related to KBG syndrome

AU - Walz, Katherina

AU - Cohen, Devon

AU - Neilsen, Paul M.

AU - Foster, Joseph

AU - Brancati, Francesco

AU - Demir, Korcan

AU - Fisher, Richard

AU - Moffat, Michelle

AU - Verbeek, Nienke E.

AU - Bjørgo, Kathrine

AU - Lo Castro, Adriana

AU - Curatolo, Paolo

AU - Novelli, Giuseppe

AU - Abad, Clemer

AU - Lei, Cao

AU - Zhang, Lily

AU - Diaz-Horta, Oscar

AU - Young, Juan I.

AU - Callen, David F.

AU - Tekin, Mustafa

PY - 2015

Y1 - 2015

N2 - Mutations in ANKRD11 have recently been reported to cause KBG syndrome, an autosomal dominant condition characterized by intellectual disability (ID), behavioral problems, and macrodontia. To understand the pathogenic mechanism that relates ANKRD11 mutations with the phenotype of KBG syndrome, we studied the cellular characteristics of wild-type ANKRD11 and the effects of mutations in humans and mice. We show that the abundance of wild-type ANKRD11 is tightly regulated during the cell cycle, and that the ANKRD11 C-terminus is required for the degradation of the protein. Analysis of 11 pathogenic ANKRD11 variants in humans, including six reported in this study, and one reported in the Ankrd11Yod/+ mouse, shows that all mutations affect the C-terminal regions and that the mutant proteins accumulate aberrantly. In silico analysis shows the presence of D-box sequences that are signals for proteasome degradation. We suggest that ANKRD11 C-terminus plays an important role in regulating the abundance of the protein, and a disturbance of the protein abundance due to the mutations leads to KBG syndrome.

AB - Mutations in ANKRD11 have recently been reported to cause KBG syndrome, an autosomal dominant condition characterized by intellectual disability (ID), behavioral problems, and macrodontia. To understand the pathogenic mechanism that relates ANKRD11 mutations with the phenotype of KBG syndrome, we studied the cellular characteristics of wild-type ANKRD11 and the effects of mutations in humans and mice. We show that the abundance of wild-type ANKRD11 is tightly regulated during the cell cycle, and that the ANKRD11 C-terminus is required for the degradation of the protein. Analysis of 11 pathogenic ANKRD11 variants in humans, including six reported in this study, and one reported in the Ankrd11Yod/+ mouse, shows that all mutations affect the C-terminal regions and that the mutant proteins accumulate aberrantly. In silico analysis shows the presence of D-box sequences that are signals for proteasome degradation. We suggest that ANKRD11 C-terminus plays an important role in regulating the abundance of the protein, and a disturbance of the protein abundance due to the mutations leads to KBG syndrome.

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DO - 10.1007/s00439-014-1509-2

M3 - Article

C2 - 25413698

AN - SCOPUS:84925534257

SN - 0340-6717

VL - 134

SP - 181

EP - 190

JO - Human Genetics

JF - Human Genetics

IS - 2

ER -

Characterization of ANKRD11 mutations in humans and mice related to KBG syndrome

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