Signaling via G proteins mediates tumorigenic effects of GPR87.

G protein-coupled receptors (GPCRs) constitute a large protein family of seven transmembrane (7TM) spanning proteins that regulate multiple physiological functions. GPR87 is overexpressed in several cancers and plays a role in tumor cell survival. Here, the basal activity of GPR87 was investigated in transiently transfected HEK293 cells, revealing ligand-independent coupling to Gαi, Gαq and Gα12/13. Furthermore, GPR87 showed a ligand-independent G protein-dependent activation of the downstream transcription factors CREB, NFκB, NFAT and SRE. In tetracycline-induced Flp-In T-Rex-293 cells, GPR87 induced cell clustering presumably through Gα12/13 coupling. In a foci formation assay using retrovirally transduced NIH3T3 cells, GPR87 showed a strong in vitro transforming potential, which correlated to the in vivo tumor induction in nude mice. Importantly, we demonstrate that the transforming potential of GPR87 was correlated to the receptor signaling, as the signaling-impaired mutant R139A (Arg in the conserved "DRY"-motif at the bottom of transmembrane helix 3 of GPR87 substituted to Ala) showed a lower in vitro cell transformation potential. Furthermore, R139A lost the ability to induce cell clustering. In summary, we show that GPR87 is active through several signaling pathways and that the signaling activity is linked to the receptor-induced cell transformation and clustering. The robust surface expression of GPR87 and general high druggability of GPCRs make GPR87 an attractive future anticancer target for drugs that - through inhibition of the receptor signaling - will inhibit its transforming properties.

Virus-encoded 7 transmembrane receptors.

Herpesviruses are an ancient group which have exploited gene capture of multiple cellular modulators of the immune response. Viral homologues of 7 transmembrane receptors (v7TMRs) are a consistent feature of beta- and gammaherpesviruses; the majority of the v7TMRs are homologous to cellular chemokine receptors (CKRs). Conserved families of v7TMRs distinguish between beta- versus gammaherpesviruses; furthermore, significant divisions within these subfamilies, such as between genera of the gammaherpesviruses or between the primate and rodent cytomegaloviruses, coincide with specific v7TMR gene families. Divergence of functional properties between the viral 7TMR and their cellular counterparts is likely, therefore, to reflect adaptation supporting various aspects of the viral lifecycle with concomitant effects upon viral pathogenesis. Consistent with their long evolutionary history, the v7TMRs have acquired a range of distinctive characteristics. This chapter reviews key features of the v7TMRs which are likely to impact upon their functional roles: trafficking properties, ligand specificity, and signaling capacity. Rapid, constitutive endocytosis, reminiscent of cellular "scavenger" receptors, may provide a mechanism for immune evasion, or alternatively relate to virion assembly, including incorporation of v7TMRs within the virion envelope. Some v7TMRs display relatively broad chemokine-binding specificity, whereas others remain "orphan" and may be completely independent of ligand activation. Indeed, many of the v7TMRs have been shown to signal constitutively, associated in some cases with notable divergence of highly conserved regulatory elements such as the "DRY" motif of TMIII. The availability of rodent models for v7TMR functional studies has provided evidence for important biological roles, including cellular transformation, tissue tropism, and viral persistence. Recent studies addressing signaling pathways critical to these phenotypes will be discussed, with reference to both beta- and gammaherpesviruses.

Identification of common mechanisms by which human and mouse cytomegalovirus seven-transmembrane receptor homologues contribute to in vivo phenotypes in a mouse model.

The mouse cytomegalovirus chemokine receptor homologue (CKR) M33 is required for salivary gland tropism and efficient reactivation from latency, phenotypes partially rescued by the human cytomegalovirus CKR US28. Herein, we demonstrate that complementation of salivary gland tropism is mediated predominantly by G protein-dependent signaling conserved with that of M33; in contrast, both G protein-dependent and -independent pathways contribute to the latency phenotypes. A novel M33-dependent replication phenotype in cultured bone marrow macrophages is also described.