膜插入和表位标记的 gp9 在 M13 噬菌体尖端的组装。

Membrane insertion and assembly of epitope-tagged gp9 at the tip of the M13 phage.

机构信息

Institute of Microbiology and Molecular Biology, University of Hohenheim, Stuttgart, Germany.

出版信息

BMC Microbiol. 2011 Sep 26;11:211. doi: 10.1186/1471-2180-11-211.

DOI:10.1186/1471-2180-11-211

PMID:21943062

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3193035/

Abstract

BACKGROUND

Filamentous M13 phage extrude from infected Escherichia coli with a tip structure composed of gp7 and gp9. This tip structure is extended by the assembly of the filament composed of the major coat protein gp8. Finally, gp3 and gp6 terminate the phage structure at the proximal end. Up to now, gp3 has been the primary tool for phage display technology. However, gp7, gp8 and gp9 could also be used for phage display and these phage particles should bind to two different or more surfaces when the modified coat proteins are combined. Therefore, we tested here if the amino-terminal end of gp9 can be modified and whether the modified portion is exposed and detectable on the M13 phage particles.

RESULTS

The amino-terminal region of gp9 was modified by inserting short sequences that encode antigenic epitopes. We show here that the modified gp9 proteins correctly integrate into the membrane using the membrane insertase YidC exposing the modified epitope into the periplasm. The proteins are then efficiently assembled onto the phage particles. Also extensions up to 36 amino acid residues at the amino-terminal end of gp9 did not interfere with membrane integration and phage assembly. The exposure of the antigenic tags on the phage was visualised with immunogold labelling by electron microscopy and verified by dot blotting with antibodies to the tags.

CONCLUSIONS

Our results suggest that gp9 at the phage tip is suitable for the phage display technology. The modified gp9 can be supplied in trans from a plasmid and fully complements M13 phage with an amber mutation in gene 9. The modified phage tip is very well accessible to antibodies.

摘要

背景

丝状 M13 噬菌体从感染的大肠杆菌中挤出，其尖端结构由 gp7 和 gp9 组成。该尖端结构通过组装由主要外壳蛋白 gp8 组成的丝状结构来延伸。最后，gp3 和 gp6 在近端终止噬菌体结构。到目前为止，gp3 一直是噬菌体展示技术的主要工具。然而，gp7、gp8 和 gp9 也可用于噬菌体展示，并且当修饰的外壳蛋白结合时，这些噬菌体颗粒应该与两个不同或更多的表面结合。因此，我们在这里测试 gp9 的氨基末端是否可以被修饰，以及修饰部分是否暴露在 M13 噬菌体颗粒上并可检测到。

结果

gp9 的氨基末端区域通过插入编码抗原表位的短序列进行修饰。我们在这里表明，修饰后的 gp9 蛋白使用膜插入酶 YidC 正确整合到膜中，将修饰的表位暴露在周质中。然后，这些蛋白有效地组装到噬菌体颗粒上。此外，gp9 氨基末端的延伸长达 36 个氨基酸残基也不干扰膜整合和噬菌体组装。通过电子显微镜的免疫金标记可以观察到噬菌体上抗原标记的暴露，并通过与标记物的抗体进行斑点印迹验证。

结论

我们的结果表明，噬菌体尖端的 gp9 适合噬菌体展示技术。修饰后的 gp9 可以从质粒中转录，并完全补充基因 9 中有琥珀突变的 M13 噬菌体。修饰的噬菌体尖端非常容易与抗体结合。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/582a/3193035/9aeae87fcdb5/1471-2180-11-211-1.jpg

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膜插入和表位标记的 gp9 在 M13 噬菌体尖端的组装。

Membrane insertion and assembly of epitope-tagged gp9 at the tip of the M13 phage.

机构信息

Institute of Microbiology and Molecular Biology, University of Hohenheim, Stuttgart, Germany.