Direct modulation of phospholipase D activity by Gbetagamma.

Phospholipase D-mediated hydrolysis of phosphatidylcholine is stimulated by protein kinase C and the monomeric G proteins Arf, RhoA, Cdc42, and Rac1, resulting in complex regulation of this enzyme. Using purified proteins, we have identified a novel inhibitor of phospholipase D activity, Gbetagamma subunits of heterotrimeric G proteins. G protein-coupled receptor activation alters affinity between Galpha and Gbetagamma subunits, allowing subsequent interaction with distinct effectors. Gbeta1gamma1 inhibited phospholipase D1 and phospholipase D2 activity, and both Gbeta1gamma1 and Gbeta1gamma2 inhibited stimulated phospholipase D1 activity in a dosedependent manner in reconstitution assays. Reconstitution assays suggest this interaction occurs through the amino terminus of phospholipase D, because Gbeta1gamma1 is unable to inhibit an amino-terminally truncated phospholipase D construct, PLD1.d311, which like full-length phospholipase D isoforms, requires phosphatidylinositol-4,5-bisphosphate for activity. Furthermore, a truncated protein consisting of the amino-terminal region of phospholipase D containing the phox/pleckstrin homology domains was found to interact with Gbeta1gamma1, unlike the PLD1.d311 recombinant protein, which lacks this domain. In vivo, expressed recombinant Gbeta1gamma2 was also found to inhibit phospholipase D activity under basal and stimulated conditions in MDA-MB-231 cells, which natively express both phospholipase D1 and phospholipase D2. These data demonstrate that Gbetagamma directly regulates phospholipase D activity in vitro and suggest a novel mechanism to negatively regulate phospholipase D signaling in vivo.

Strategies for recombinant Furin employment in a biotechnological process: complete target protein precursor cleavage.

Coagulation factors, amongst many other proteins, often require posttranslational endoproteolytic processing for maturation. Upon high yield expression of recombinant forms of these proteins, processing frequently becomes severely limiting, resulting in a hampered function of the protein. In this report, the human endoprotease Furin was used to achieve complete propeptide removal from recombinant von Willebrand Factor (rvWF) precursors in CHO cells. At expression beyond 200 ng rvWF/106 cells x day, processing became insufficient. Stable co- and overexpression of full length Furin resulted in complete precursor cleavage in cell clones expressing 2 mug rvWF/106 cells x day. Rather than occuring intracellularly, processing was found to be mediated by a naturally secreted form of rFurin, present in 100 fold higher concentrations than endogenous Furin and accumulating in the cell culture supernatant. Attempts to increase rFurin yield by amplification, in order to ensure complete rvWF precursor processing at expression rates beyond 2 mug rvWF/106 cells x day, failed. Truncation of the trans-membrane domain resulted in immediate secretion of rFurin and approximately 10 fold higher concentrations in the conditioned medium. In cases where these high rFurin concentrations are not sufficient to ensure complete processing, an in vitro downstream processing procedure has to be established. Secreted affinity epitope-tagged rFurin derivatives were constructed, the fate of which, at expression, was dependent on the size of the C-terminal truncation and the type of the heterologous epitope added. A suitable candidate was purified by a one step affinity procedure, and successfully used for in vitro processing. This allows complete proteolytic processing of large amounts of precursor molecules by comparably small quantities of rFurin. Complete precursor cleavage of a target protein at expression rates of up to approximately 200 ng, 2 mug, and 20 mug, as well as beyond 20 mug/106 cells x day can thus be anticipated to be accomplished by endogenous Furin, additional expression of full length rFurin, co-expression of truncated and hence secreted rFurin, and a protein-chemical in vitro procedure, respectively.

Production of highly homogeneous and structurally intact recombinant von Willebrand factor multimers by furin-mediated propeptide removal in vitro.

Recombinant human von Willebrand Factor (rvWF), a multimeric glycoprotein essential to haemostasis, has been developed as a potential therapeutic agent for treatment of von Willebrand disease (vWD). Permanent Chinese-hamster ovary (CHO)-rvWF cell clones co-expressing recombinant furin (rfurin) were established in order to ensure complete rvWF propeptide removal [Fischer, Schlokat, Mitterer, Reiter, Mundt, Turecek, Schwarz and Dorner (1995) FEBS Lett. 375, 259-262]. Large quantities of material are required for in vivo tests and clinical studies. This demand is commonly met by achieving high-yield expression of the desired protein via amplification. Co-amplification of rfurin, necessary to completely process increasing amounts of rvWF precursor, could not be accomplished, presumably due to lethal effects of overexpressed rfurin for the host cells [Creemers (1994) Ph.D. Thesis, University of Leuven]. Recent reports have inferred that rfurin can only mediate rvWF processing intracellularly [Rehemtulla and Kaufman (1992) Blood 79, 2349-2355; Rehemtulla, Dorner and Kaufman (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 8235-8239]. We report here that rvWF-precursor processing, however, occurs predominantly extracellularly upon rfurin co-expression. Mixing experiments employing rfurin- as well as rvWF-precursor-containing conditioned media demonstrate that rvWF precursors are accessible and cleavable by rfurin in vitro. Exposure to rfurin in vitro converts the heterogeneous multimer pattern typical of incompletely processed rvWF multimers into highly homogeneous and structurally intact multimers superior to the ones exhibited by plasma-derived vWF. These findings thus demonstrate the feasibility of large-scale production of a completely processed, intact and homogeneous rvWF preparation, based on individual rvWF-precursor high-yield expression and subsequent propeptide removal by rfurin in vitro.