Coexpression of proteins in bacteria using T7-based expression plasmids: expression of heteromeric cell-cycle and transcriptional regulatory complexes.

Abstract

This report describes the development and application of a dual vector coexpression system for the overproduction of heteromeric cell cycle and transcriptional regulatory protein complexes in bacteria. To facilitate these studies we constructed a T7-based expression plasmid, pRM1 that contains an origin of replication derived from p15A, and a gene encoding kanamycin resistance. This expression vector is compatible with ColE1-derived plasmids found in the pET family of T7 expression vectors, which encode ampicillin resistance. It also has the same multiple cloning sites as the pET- derived pRSET vector, allowing easy shuttling between the two expression vectors. Cotransformation of the pRM1 and pET-derived expression vectors into an Escherichia coli strain such as BL21(DE3) results in a significant level of coexpression of heteromeric protein complexes. We demonstrate the applicability of combining the pRM1 and pET-derived vectors for the coexpression of cell cycle regulatory components, pRB/E7 and pRB/E1a, and the transcriptional regulatory complexes, SRF/SAP-1 and SRF/Elk-1. We further use the pRB/E1a complex to demonstrate that these coexpressed complexes can be purified to homogeneity for further studies. Use of the pRM1 vector in combination with the pET-derived vectors should be generally applicable for the large-scale coexpression and purification of a wide variety of heteromeric protein complexes for biochemical, biophysical, and structural studies.