Uncovering Ubiquitin and Ubiquitin-like Signaling Networks

Microscopic imaging and technolog

Heterologous Expression of Membrane Proteins: Choosing the Appropriate Host

International audienceBACKGROUND: Membrane proteins are the targets of 50% of drugs, although they only represent 1% of total cellular proteins. The first major bottleneck on the route to their functional and structural characterisation is their overexpression; and simply choosing the right system can involve many months of trial and error. This work is intended as a guide to where to start when faced with heterologous expression of a membrane protein. METHODOLOGY/PRINCIPAL FINDINGS: The expression of 20 membrane proteins, both peripheral and integral, in three prokaryotic (E. coli, L. lactis, R. sphaeroides) and three eukaryotic (A. thaliana, N. benthamiana, Sf9 insect cells) hosts was tested. The proteins tested were of various origins (bacteria, plants and mammals), functions (transporters, receptors, enzymes) and topologies (between 0 and 13 transmembrane segments). The Gateway system was used to clone all 20 genes into appropriate vectors for the hosts to be tested. Culture conditions were optimised for each host, and specific strategies were tested, such as the use of Mistic fusions in E. coli. 17 of the 20 proteins were produced at adequate yields for functional and, in some cases, structural studies. We have formulated general recommendations to assist with choosing an appropriate system based on our observations of protein behaviour in the different hosts. CONCLUSIONS/SIGNIFICANCE: Most of the methods presented here can be quite easily implemented in other laboratories. The results highlight certain factors that should be considered when selecting an expression host. The decision aide provided should help both newcomers and old-hands to select the best system for their favourite membrane protein

Dissecting β-ring assembly pathway of the mammalian 20S proteasome

The 20S proteasome is the catalytic core of the 26S proteasome. It comprises four stacked rings of seven subunits each, α1–7β1–7β1–7α1–7. Recent studies indicated that proteasome-specific chaperones and β-subunit appendages assist in the formation of α-rings and dimerization of half-proteasomes, but the process involved in the assembly of β-rings is poorly understood. Here, we clarify the mechanism of β-ring formation on α-rings by characterizing assembly intermediates accumulated in cells depleted of each β-subunit. Starting from β2, incorporation of β-subunits occurs in an orderly manner dependent on the propeptides of β2 and β5, and the C-terminal tail of β2. Unexpectedly, hUmp1, a chaperone functioning at the final assembly step, is incorporated as early as β2 and is required for the structural integrity of early assembly intermediates. We propose a model in which β-ring formation is assisted by both intramolecular and extrinsic chaperones, whose roles are partially different between yeast and mammals

A novel proteasome interacting protein recruits the deubiquitinating enzyme UCH37 to 26S proteasomes

The 26S proteasome is a multisubunit protease responsible for regulated proteolysis in eukaryotic cells. It is composed of one catalytic 20S proteasome and two 19S regulatory particles attached on both ends of 20S proteasomes. Here, we describe the identification of Adrm1 as a novel proteasome interacting protein in mammalian cells. Although the overall sequence of Adrm1 has weak homology with the yeast Rpn13, the amino- and carboxyl-terminal regions exhibit significant homology. Therefore, we designated it as hRpn13. hRpn13 interacts with a base subunit Rpn2 via its amino-terminus. The majority of 26S proteasomes contain hRpn13, but a portion of them does not, indicating that hRpn13 is not an integral subunit. Intriguingly, we found that hRpn13 recruits UCH37, a deubiquitinating enzyme known to associate with 26 proteasomes. The carboxyl-terminal regions containing KEKE motifs of both hRpn13 and UCH37 are involved in their physical interaction. Knockdown of hRpn13 caused no obvious proteolytic defect but loss of UCH37 proteins and decrease in deubiquitinating activity of 26S proteasomes. Our results indicate that hRpn13 is essential for the activity of UCH37