肌营养不良蛋白聚糖、Tks5和Src介导成肌细胞中侵袭性足突的组装。

Dystroglycan, Tks5 and Src mediated assembly of podosomes in myoblasts.

作者信息

Thompson Oliver, Kleino Iivari, Crimaldi Luca, Gimona Mario, Saksela Kalle, Winder Steve J

机构信息

Department of Biomedical Science, University of Sheffield, Western Bank, Sheffield, UK.

出版信息

PLoS One. 2008;3(11):e3638. doi: 10.1371/journal.pone.0003638. Epub 2008 Nov 4.

DOI:10.1371/journal.pone.0003638

PMID:18982058

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2572840/

Abstract

BACKGROUND

Dystroglycan is a ubiquitously expressed cell adhesion receptor best understood in its role as part of the dystrophin glycoprotein complex of mature skeletal muscle. Less is known of the role of dystroglycan in more fundamental aspects of cell adhesion in other cell types, nor of its role in myoblast cell adhesion.

PRINCIPAL FINDINGS

We have examined the role of dystroglycan in the early stages of myoblast adhesion and spreading and found that dystroglycan initially associates with other adhesion proteins in large puncta morphologically similar to podosomes. Using a human SH3 domain phage display library we identified Tks5, a key regulator of podosomes, as interacting with beta-dystroglycan. We verified the interaction by immunoprecipitation, GST-pulldown and immunfluorescence localisation. Both proteins localise to puncta during early phases of spreading, but importantly following stimulation with phorbol ester, also localise to structures indistinguishable from podosomes. Dystroglycan overexpression inhibited podosome formation by sequestering Tks5 and Src. Mutation of dystroglycan tyrosine 890, previously identified as a Src substrate, restored podosome formation.

CONCLUSIONS

We propose therefore, that Src-dependent phosphorylation of beta-dystroglycan results in the formation of a Src/dystroglycan complex that drives the SH3-mediated association between dystroglycan and Tks5 which together regulate podosome formation in myoblasts.

摘要

背景

肌营养不良聚糖是一种广泛表达的细胞黏附受体，作为成熟骨骼肌中肌营养不良蛋白糖蛋白复合物的一部分，其作用已得到充分了解。对于肌营养不良聚糖在其他细胞类型细胞黏附的更基本方面的作用，以及其在成肌细胞黏附中的作用，人们了解较少。

主要发现

我们研究了肌营养不良聚糖在成肌细胞黏附和铺展早期阶段的作用，发现肌营养不良聚糖最初与其他黏附蛋白在形态上类似于足体的大斑点中结合。使用人SH3结构域噬菌体展示文库，我们鉴定出足体的关键调节因子Tks5与β-肌营养不良聚糖相互作用。我们通过免疫沉淀、GST下拉和免疫荧光定位验证了这种相互作用。在铺展早期阶段，两种蛋白都定位于斑点，但重要的是，在用佛波酯刺激后，它们也定位于与足体无法区分的结构。肌营养不良聚糖的过表达通过隔离Tks5和Src抑制足体形成。先前被鉴定为Src底物的肌营养不良聚糖酪氨酸890突变恢复了足体形成。

结论

因此，我们提出，β-肌营养不良聚糖的Src依赖性磷酸化导致形成Src/肌营养不良聚糖复合物，该复合物驱动肌营养不良聚糖与Tks5之间的SH3介导的结合，它们共同调节成肌细胞中的足体形成。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6468/2572840/f508736a7fda/pone.0003638.g001.jpg

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肌营养不良蛋白聚糖、Tks5和Src介导成肌细胞中侵袭性足突的组装。

Dystroglycan, Tks5 and Src mediated assembly of podosomes in myoblasts.

作者信息

机构信息

出版信息

BACKGROUND

PRINCIPAL FINDINGS

CONCLUSIONS

背景

主要发现

结论

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