Hetero-oligomerization of chemokine receptors: diversity and relevance for function.

The G protein-coupled receptor (GPCR) family of membrane receptors encompasses over 1000 members, representing the largest known receptor family, with a variety of structurally different ligands. GPCRs are favorite targets for drug development in numerous diseases. Chemokine receptors are an important GPCR sub-class and are known to play a crucial role in the regulation of multiple physiological and various pathophysiological processes, including inflammation, atherosclerosis, cancer, and viral infections. Chemokine receptor activation is controlled by some 50 chemokine ligands which often act in a redundant and overlapping manner, enabling for a complex regulatory system together controlling and fine-tuning the specificity and spatio-temporal properties of the response. Recent findings have indicated that additionally the organization of chemokine receptors on the cell surface could be critical for driving their biological effects. In fact, chemokine receptors have increasingly been found to organize into homo- or hetero-oligomeric complexes, in part in a ligand-inducible manner, resulting in complex networks and crosstalk with other orthogonal signaling complexes. There has even been evidence for heterologous complex formation between chemokine receptors and non-chemokine receptor G protein-coupled receptors (GPCRs), and even non-GPCRs. However, the functional consequences of this kind of oligomerization have remained poorly understood, even for the chemokine receptor homo-oligomers. Yet, there is growing evidence that targeting homo- and/or hetero-oligomerization of chemokine receptors might be beneficial for the development of novel and specific therapeutics. In the present article, we highlight the multi-faceted complexity of chemokine receptor structures with a focus on their hetero-oligomerization properties.

FMIP controls the adipocyte lineage commitment of C2C12 cells by downmodulation of C/EBP alpha.

Fms interacting protein (FMIP) is a substrate for Fms tyrosine kinase, and a nuclear/cytoplasm shuttling protein with a leucine zipper. As the phosphorylation of FMIP is observed in insulin-stimulated preadipocytes, we examined the role of FMIP in adipocyte differentiation, using the mesenchymal multipotent stem cells, C2C12 cells, that can differentiate into adipocytes, muscle cells and osteoblasts. Ectopic expression of FMIP in C2C12 impairs the adipocyte differentiation induced by treatment with insulin, dexamethasone and 3-isobutyl-1-methylxanthine. These cells exhibit muscle phenotype with multinuclear morphology. Furthermore, knockdown of endogenous FMIP expression by small interfering RNA improves adipocytic lineage commitment of C2C12 cells, while impairing muscle differentiation. Upon stimulation with insulin, CCAAT/enhancer binding protein (C/EBP)beta, but not C/EBPalpha, is upregulated in cells expressing ectopic FMIP, whereas in FMIP knockdown cells, C/EBPalpha is constitutively expressed. Ectopic expression of C/EBPalpha counteracts the effects of FMIP, whereas C/EBPalpha knockdown partially mimics the effects of FMIP in this system. Northern blot analysis and reverse transcriptase-polymerase chain reaction study reveal that ectopic FMIP-expressing cells do not contain the polyadenylated C/EBPalpha mRNA, but contain the C/EBPalpha pre-mRNA, suggesting that FMIP plays a role in RNA processing and/or export. Indeed, a member of the THO complex that plays a role in mRNA export, THOC1, is co-precipitated with FMIP. The data we have acquired on FMIP suggest that it is a target for tyrosine kinase receptors that potentiate mRNA export.