英:Shank (SH3 and multiple ankyrin repeat domains protein)
SH3 and multiple ankyrin repeat domains 2 | |||||||||||||
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Identifiers | |||||||||||||
Symbols | SHANK2; AUTS17; CORTBP1; CTTNBP1; ProSAP1; SHANK; SPANK-3 | ||||||||||||
External IDs | OMIM: 603290 MGI: 2671987 HomoloGene: 105965 GeneCards: SHANK2 Gene | ||||||||||||
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RNA expression pattern | |||||||||||||
More reference expression data | |||||||||||||
Orthologs | |||||||||||||
Species | Human | Mouse | |||||||||||
Entrez | 22941 | 210274 | |||||||||||
Ensembl | ENSG00000162105 | ENSMUSG00000037541 | |||||||||||
UniProt | Q9UPX8 | Q80Z38 | |||||||||||
RefSeq (mRNA) | NM_012309.3 | XM_001002370 | |||||||||||
RefSeq (protein) | NP_036441.2 | XP_001002370 | |||||||||||
Location (UCSC) |
Chr 11: 70.31 – 70.96 Mb |
Chr 7: 143.99 – 144.23 Mb | |||||||||||
PubMed search | [3] | [4] |
SH3 and multiple ankyrin repeat domains 3 | |||||||||||||
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Identifiers | |||||||||||||
Symbols | SHANK3; DEL22q13.3; PROSAP2; PSAP2; SCZD15; SPANK-2 | ||||||||||||
External IDs | OMIM: 606230 MGI: 1930016 HomoloGene: 75163 GeneCards: SHANK3 Gene | ||||||||||||
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RNA expression pattern | |||||||||||||
More reference expression data | |||||||||||||
Orthologs | |||||||||||||
Species | Human | Mouse | |||||||||||
Entrez | 85358 | 58234 | |||||||||||
Ensembl | ENSG00000251322 | ENSMUSG00000022623 | |||||||||||
UniProt | F2Z3L0 | Q4ACU6 | |||||||||||
RefSeq (mRNA) | NM_001080420.1 | NM_021423.3 | |||||||||||
RefSeq (protein) | NP_001073889.1 | NP_067398.2 | |||||||||||
Location (UCSC) |
Chr 22: 51.11 – 51.17 Mb |
Chr 15: 89.33 – 89.39 Mb | |||||||||||
PubMed search | [5] | [6] |
同義語:ProSAP (Proline-rich synapse-associated protein), CortBP (Cortactin-binding protein), Somatostatin receptor-interacting protein (SSTRIP), GKAP/SAPAP-interacting protein, SPANK, Synamon
Shankは、2000個以上のアミノ酸からなる巨大な足場タンパク質である。選択的スプライシングによりさまざまな遺伝子産物が得られるが、最も長いものはアンキリンリピート、SH3 (Src homology 3)ドメイン、PDZ (PSD-95, Dlg, Zo-1)ドメイン、プロリンリッチ配列、SAM (Sterile alpha motif)ドメインからなる。それぞれのドメインが相互作用するタンパク質を持つので、結合タンパク質は多岐にわたる。自閉症との関連が指摘されている。
構造
Shankには異なった遺伝子にコードされるShank1、2、3がある。Shankのドメイン構造はアミノ端から、アンキリンリピート、SH3ドメイン、PDZドメイン、1000残基以上に及ぶプロリン、セリン、グリシンに富む配列、SAMからなる(図1)。選択的スプライシングにより、アンキリンリピートやSH3ドメイン、SAMドメインを欠くものもある。
サブタイプ毎の別名は、
- Shank1 = GKAP/SAPAP-interacting protein = SPANK-1 = Somatostatin receptor-interacting protein (SSTRIP) = Synamon
- Shank2 = CortBP1 (Cortactin-binding protein 1) = ProSAP1 (Proline-rich synapse-associated protein 1) = SPANK-3
- Shank3 = ProSAP2 = SPANK-2
発現
Shank1, Shank2, Shank3いずれのサブタイプも脳に広範に発現している。細胞レベルでは、シナプス後部、特にシナプス後肥厚部に多く分布している。
機能
Shankを神経細胞に過剰発現するとスパインの肥大化が起こり、特にShank結合タンパク質であるHomerとの共発現はスパインのを更なる肥大化を引き起こす[2]。 さらに、本来、スパインを持たない小脳顆粒細胞にShankを導入すると、 NMDA型グルタミン酸受容体やAMPA型グルタミン酸受容体をもつスパインを形成するようになる[3]。
Shank分子間のドメイン間相互作用によりオリゴマーを形成するShankと、両端に2つずつのリガンド結合部位をもつ逆平行4量体を形成するHomerは互いに架橋して、高次のネットワーク構造を形成する。このShankとHomerの高次複合体がシナプス後肥厚部の骨格となると考えられる[4] 。
分子内・分子間相互作用
Shank分子内、あるいはShank分子間の相互作用としては、アンキリンリピートとSH3ドメインが相互作用する[5]ほか、PDZドメインはホモ二量体を[6]、SAMドメインは多量体を[7] 形成する。このPDZドメインによるホモ二量体形成には、PDZドメイン本来のタンパク質結合部位は関与しないので、二量体を形成しても、他のPDZリガンドは結合できる(図2)。一方、結晶化されたSAMドメインは一周6分子の螺旋状ポリマーを形成しており(図3)、更にこの螺旋が側面で会合して、Zn2+イオンに依存性の二次元の広がりをもつシートを形成する。
但し、SAMドメインの大きさはShank全長の3%にしか相当しないので、上流の長い配列も含めて大きなポリマーを形成できるかどうかは不明である。
Shankと相互作用するタンパク質
受容体・膜タンパク質
いずれも、C末端(C-terminus)がShankのPDZドメインに結合する。
- ソマトスタチン受容体サブタイプ2[10]
- 嚢胞性線維症膜コンダクタンス制御因子 (Cystic fibrosis transmembrane conductance regulator, CFTR)[12]
- 代謝活性型グルタミン酸受容体サブユニットmGluR1、mGluR5[14] これらは、Shankに結合するHomerとも相互作用する。
シナプス足場タンパク質
- Homer[17]
低分子量GTP結合タンパク質を制御するタンパク質
- IRSp53
アクチン結合タンパク質
- IRSp53
その他のタンパク質
Shank遺伝子の異常
自閉症との関連については、ヒトにおけるShank3の変異が最初に報告されたが[29]、その後、Shank2[30], Shank1[31]についても報告されている。Phelan–McDermid 症候群は染色体22q13部位の欠失によるもので、Shank3 の異常が原因の一つと考えられている。また、Shank2、Shank3のノックアウトマウスは社会的相互作用の欠如や過剰な毛繕いなど自閉症様の表現型を呈する[32] [33] [34]。さらに、自閉症患者にみられるShank3のC末の欠失変異体は、優性にShank3のプロテアーゼ分解を促進して、シナプスの形成を阻害する[35]。
関連項目
参考文献
- ↑
Lim, S., Naisbitt, S., Yoon, J., Hwang, J.I., Suh, P.G., Sheng, M., & Kim, E. (1999).
Characterization of the Shank family of synaptic proteins. Multiple genes, alternative splicing, and differential expression in brain and development. The Journal of biological chemistry, 274(41), 29510-8. [PubMed:10506216] [WorldCat] [DOI] - ↑
Sala, C., Piëch, V., Wilson, N.R., Passafaro, M., Liu, G., & Sheng, M. (2001).
Regulation of dendritic spine morphology and synaptic function by Shank and Homer. Neuron, 31(1), 115-30. [PubMed:11498055] [WorldCat] [DOI] - ↑
Roussignol, G., Ango, F., Romorini, S., Tu, J.C., Sala, C., Worley, P.F., ..., & Fagni, L. (2005).
Shank expression is sufficient to induce functional dendritic spine synapses in aspiny neurons. The Journal of neuroscience : the official journal of the Society for Neuroscience, 25(14), 3560-70. [PubMed:15814786] [PMC] [WorldCat] [DOI] - ↑
Hayashi, M.K., Tang, C., Verpelli, C., Narayanan, R., Stearns, M.H., Xu, R.M., ..., & Hayashi, Y. (2009).
The postsynaptic density proteins Homer and Shank form a polymeric network structure. Cell, 137(1), 159-71. [PubMed:19345194] [PMC] [WorldCat] [DOI] - ↑
Romorini, S., Piccoli, G., Jiang, M., Grossano, P., Tonna, N., Passafaro, M., ..., & Sala, C. (2004).
A functional role of postsynaptic density-95-guanylate kinase-associated protein complex in regulating Shank assembly and stability to synapses. The Journal of neuroscience : the official journal of the Society for Neuroscience, 24(42), 9391-404. [PubMed:15496675] [PMC] [WorldCat] [DOI] - ↑ 6.0 6.1
Im, Y.J., Lee, J.H., Park, S.H., Park, S.J., Rho, S.H., Kang, G.B., ..., & Eom, S.H. (2003).
Crystal structure of the Shank PDZ-ligand complex reveals a class I PDZ interaction and a novel PDZ-PDZ dimerization. The Journal of biological chemistry, 278(48), 48099-104. [PubMed:12954649] [WorldCat] [DOI] - ↑ 7.0 7.1
Baron, M.K., Boeckers, T.M., Vaida, B., Faham, S., Gingery, M., Sawaya, M.R., ..., & Bowie, J.U. (2006).
An architectural framework that may lie at the core of the postsynaptic density. Science (New York, N.Y.), 311(5760), 531-5. [PubMed:16439662] [WorldCat] [DOI] - ↑
Im, Y.J., Kang, G.B., Lee, J.H., Park, K.R., Song, H.E., Kim, E., ..., & Eom, S.H. (2010).
Structural basis for asymmetric association of the betaPIX coiled coil and shank PDZ. Journal of molecular biology, 397(2), 457-66. [PubMed:20117114] [WorldCat] [DOI] - ↑
Tobaben, S., Südhof, T.C., & Stahl, B. (2000).
The G protein-coupled receptor CL1 interacts directly with proteins of the Shank family. The Journal of biological chemistry, 275(46), 36204-10. [PubMed:10958799] [WorldCat] [DOI] - ↑
Zitzer, H., Hönck, H.H., Bächner, D., Richter, D., & Kreienkamp, H.J. (1999).
Somatostatin receptor interacting protein defines a novel family of multidomain proteins present in human and rodent brain. The Journal of biological chemistry, 274(46), 32997-3001. [PubMed:10551867] [WorldCat] [DOI] - ↑
Han, W., Kim, K.H., Jo, M.J., Lee, J.H., Yang, J., Doctor, R.B., ..., & Lee, M.G. (2006).
Shank2 associates with and regulates Na+/H+ exchanger 3. The Journal of biological chemistry, 281(3), 1461-9. [PubMed:16293618] [WorldCat] [DOI] - ↑
Kim, J.Y., Han, W., Namkung, W., Lee, J.H., Kim, K.H., Shin, H., ..., & Lee, M.G. (2004).
Inhibitory regulation of cystic fibrosis transmembrane conductance regulator anion-transporting activities by Shank2. The Journal of biological chemistry, 279(11), 10389-96. [PubMed:14679199] [WorldCat] [DOI] - ↑
Uchino, S., Wada, H., Honda, S., Nakamura, Y., Ondo, Y., Uchiyama, T., ..., & Kohsaka, S. (2006).
Direct interaction of post-synaptic density-95/Dlg/ZO-1 domain-containing synaptic molecule Shank3 with GluR1 alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid receptor. Journal of neurochemistry, 97(4), 1203-14. [PubMed:16606358] [WorldCat] [DOI] - ↑
Tu, J.C., Xiao, B., Naisbitt, S., Yuan, J.P., Petralia, R.S., Brakeman, P., ..., & Worley, P.F. (1999).
Coupling of mGluR/Homer and PSD-95 complexes by the Shank family of postsynaptic density proteins. Neuron, 23(3), 583-92. [PubMed:10433269] [WorldCat] [DOI] - ↑
Uemura, T., Mori, H., & Mishina, M. (2004).
Direct interaction of GluRdelta2 with Shank scaffold proteins in cerebellar Purkinje cells. Molecular and cellular neurosciences, 26(2), 330-41. [PubMed:15207857] [WorldCat] [DOI] - ↑
Yao, I., Hata, Y., Hirao, K., Deguchi, M., Ide, N., Takeuchi, M., & Takai, Y. (1999).
Synamon, a novel neuronal protein interacting with synapse-associated protein 90/postsynaptic density-95-associated protein. The Journal of biological chemistry, 274(39), 27463-6. [PubMed:10488079] [WorldCat] [DOI] - ↑
Tu, J.C., Xiao, B., Naisbitt, S., Yuan, J.P., Petralia, R.S., Brakeman, P., ..., & Worley, P.F. (1999).
Coupling of mGluR/Homer and PSD-95 complexes by the Shank family of postsynaptic density proteins. Neuron, 23(3), 583-92. [PubMed:10433269] [WorldCat] [DOI] - ↑
Soltau, M., Richter, D., & Kreienkamp, H.J. (2002).
The insulin receptor substrate IRSp53 links postsynaptic shank1 to the small G-protein cdc42. Molecular and cellular neurosciences, 21(4), 575-83. [PubMed:12504591] [WorldCat] - ↑
Lim, S., Sala, C., Yoon, J., Park, S., Kuroda, S., Sheng, M., & Kim, E. (2001).
Sharpin, a novel postsynaptic density protein that directly interacts with the shank family of proteins. Molecular and cellular neurosciences, 17(2), 385-97. [PubMed:11178875] [WorldCat] [DOI] - ↑
Park, E., Na, M., Choi, J., Kim, S., Lee, J.R., Yoon, J., ..., & Kim, E. (2003).
The Shank family of postsynaptic density proteins interacts with and promotes synaptic accumulation of the beta PIX guanine nucleotide exchange factor for Rac1 and Cdc42. The Journal of biological chemistry, 278(21), 19220-9. [PubMed:12626503] [WorldCat] [DOI] - ↑
Wendholt, D., Spilker, C., Schmitt, A., Dolnik, A., Smalla, K.H., Proepper, C., ..., & Boeckers, T.M. (2006).
ProSAP-interacting protein 1 (ProSAPiP1), a novel protein of the postsynaptic density that links the spine-associated Rap-Gap (SPAR) to the scaffolding protein ProSAP2/Shank3. The Journal of biological chemistry, 281(19), 13805-16. [PubMed:16522626] [WorldCat] [DOI] - ↑
Naisbitt, S., Kim, E., Tu, J.C., Xiao, B., Sala, C., Valtschanoff, J., ..., & Sheng, M. (1999).
Shank, a novel family of postsynaptic density proteins that binds to the NMDA receptor/PSD-95/GKAP complex and cortactin. Neuron, 23(3), 569-82. [PubMed:10433268] [WorldCat] [DOI] - ↑
Du, Y., Weed, S.A., Xiong, W.C., Marshall, T.D., & Parsons, J.T. (1998).
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(執筆者:林真理子 担当編集委員:柚崎通介)