Efficient processes for protein expression using recombinant baculovirus particles.

The use of baculoviruses has become a standard approach in many labs for recombinant protein production. In addition to giving a broad and practical overview of the technology, this chapter focuses in particular on two recent developments in the field and how these can be efficiently exploited for protein production: the use of baculovirus-infected insect cells and in vivo recombination-mediated production of recombinant viruses.

Cloning and pharmacological characterization of CCR7, CCL21 and CCL19 from Macaca fascicularis.

The chemokine receptor CCR7 and its ligands CCL19 and CCL21 play an important role in lymphocyte homing and have also been associated with inflammatory, allergic and lung disorders. Cloning of the cynomolgus monkey genes encoding CCR7, CCL19 and CCL21 revealed 93-97% sequence identity of the deduced proteins with their respective human homologs. In chemotaxis assays, B300-19 cells transfected with the cynomolgus (c) CCR7 receptor migrated in response to cCCL19 and cCCL21 in a dose-dependent manner with EC(50) values of 324+/-188nM and 247+/-29nM, respectively. cCCL19 and cCCL21 also elicited calcium responses in stable cell CHO-K1 lines expressing the cCCR7 receptor with EC(50) values of 227+/-4nM and 484+/-163nM, respectively. Although both human (h) CCL19 and hCCL21 elicited increases in intracellular calcium at the cCCR7 receptor, hCCL19 almost completely inhibited subsequent stimulation by hCCL21 whilst hCCL21 failed to inhibit subsequent stimulation by hCCL19. These results identify novel cynomolgus monkey genes and provide a model system for pre-clinical studies of potential drug candidates.

High-throughput insect cell protein expression applications.

The Baculovirus Expression Vector System (BEVS) is one of the most efficient systems for production of recombinant proteins and consequently its application is wide-spread in industry as well as in academia. Since the early 1970s, when the first stable insect cell lines were established and the infectivity of bacu-lovirus in an in vitro culture system was demonstrated (1, 2), virtually thousands of reports have been published on the successful expression of proteins using this system as well as on method improvement. However, despite its popularity the system is labor intensive and time consuming. Moreover, adaptation of the system to multi-parallel (high-throughput) expression is much more difficult to achieve than with E. coli due to its far more complex nature. However, recent years have seen the development of strategies that have greatly enhanced the stream-lining and speed of baculovirus protein expression for increased throughput via use of automation and miniaturization. This chapter therefore tries to collate these developments in a series of protocols (which are modifications to standard procedure plus several new approaches) that will allow the user to expedite the speed and throughput of baculovirus-mediated protein expression and facilitate true multi-parallel, high-throughput protein expression profiling in insect cells. In addition we also provide a series of optimized protocols for small and large-scale transient insect cell expression that allow for both the rapid analysis of multiple constructs and the concomitant scale-up of those selected for on-going analysis. Since this approach is independent of viral propagation, the timelines for this approach are markedly shorter and offer a significant advantage over standard bacu-lovirus expression approach strategies in the context of HT applications.

Biochemical characterization of USP7 reveals post-translational modification sites and structural requirements for substrate processing and subcellular localization.

Ubiquitin specific protease 7 (USP7) belongs to the family of deubiquitinating enzymes. Among other functions, USP7 is involved in the regulation of stress response pathways, epigenetic silencing and the progress of infections by DNA viruses. USP7 is a 130-kDa protein with a cysteine peptidase core, N- and C-terminal domains required for protein-protein interactions. In the present study, recombinant USP7 full length, along with several variants corresponding to domain deletions, were expressed in different hosts in order to analyze post-translational modifications, oligomerization state, enzymatic properties and subcellular localization patterns of the enzyme. USP7 is phosphorylated at S18 and S963, and ubiquitinated at K869 in mammalian cells. In in vitro activity assays, N- and C-terminal truncations affected the catalytic efficiency of the enzyme different. Both the protease core alone and in combination with the N-terminal domain are over 100-fold less active than the full length enzyme, whereas a construct including the C-terminal region displays a rather small decrease in catalytic efficiency. Limited proteolysis experiments revealed that USP7 variants containing the C-terminal domain interact more tightly with ubiquitin. Besides playing an important role in substrate recognition and processing, this region might be involved in enzyme dimerization. USP7 constructs lacking the N-terminal domain failed to localize in the cell nucleus, but no nuclear localization signal could be mapped within the enzyme's first 70 amino acids. Instead, the tumor necrosis factor receptor associated factor-like region (amino acids 70-205) was sufficient to achieve the nuclear localization of the enzyme, suggesting that interaction partners might be required for USP7 nuclear import.

A semi-automated large-scale process for the production of recombinant tagged proteins in the Baculovirus expression system.

The efficient preparation of recombinant proteins at the lab-scale level is essential for drug discovery, in particular for structural biology, protein interaction studies and drug screening. The Baculovirus insect-cell expression system is one of the most widely applied and highly successful systems for production of recombinant functional proteins. However, the use of eukaryotic cells as host organisms and the multi-step protocol required for the generation of sufficient virus and protein has limited its adaptation to industrialized high-throughput operation. We have developed an integrated large-scale process for continuous and partially automated protein production in the Baculovirus system. The instrumental platform includes parallel insect-cell fermentation in 10L BioWave reactors, cell harvesting and lysis by tangential flow filtration (TFF) using two custom-made filtration units and automated purification by multi-dimensional chromatography. The use of disposable materials (bags, filters and tubing), automated cleaning cycles and column regeneration, prevent any cross-contamination between runs. The preparation of the clear cell lysate by sequential TFF takes less than 2 h and represents considerable time saving compared to standard cell harvesting and lysis by sonication and ultra-centrifugation. The process has been validated with 41 His-tagged proteins with molecular weights ranging from 20 to 160 kDa. These proteins represented several families, and included 23 members of the deubiquitinating enzyme (DUB) family. Each down-stream unit can process four proteins in less than 24 h with final yields between 1 and 100 mg, and purities between 50 and 95%.