A core domain of the BMP2 proregion is sufficient for the biogenesis of mature homodimeric growth factor.

The large proregions of cystine knot growth factors exert several important biological functions. Previous results have shown that the proregion of BMP2 retards the activity of the mature growth factor. Hitherto, no information exists about the function of the BMP2 proregion during the biogenesis of the mature growth factor. Here, evidence is presented that the proregion is required for the secretion of BMP2 when present in covalent linkage to the mature domain. In trans complementation, i.e., with the proregion encoded by a separate plasmid, does not result in secretion of homodimeric mature growth factor. An extended variant of a previously in vitro characterized subdomain of the proregion, when being present in covalent linkage to the mature growth factor, restores secretion of mature BMP2, albeit at a reduced level.

Molecular analysis of two novel missense mutations in the GDF5 proregion that reduce protein activity and are associated with brachydactyly type C.

Growth and differentiation factor 5 (GDF5) plays a central role in bone and cartilage development by regulating the proliferation and differentiation of chondrogenic tissue. GDF5 is synthesized as a preproprotein. The biological function of the proregion comprising 354 residues is undefined. We identified two families with a heterozygosity for the novel missense mutations p.T201P or p.L263P located in the proregion of GDF5. The patients presented with dominant brachydactyly type C characterized by the shortening of skeletal elements in the distal extremities. Both mutations gave rise to decreased biological activity in in vitro analyses. The variants reduced the GDF5-induced activation of SMAD signaling by the GDF5 receptors BMPR1A and BMPR1B. Ectopic expression in micromass cultures yielded relatively low protein levels of the variants and showed diminished chondrogenic activity as compared to wild-type GDF5. Interestingly, stimulation of micromass cells with recombinant human proGDF5(T201P) and proGDF5(L263P) revealed their reduced chondrogenic potential compared to the wild-type protein. Limited proteolysis of the mutant recombinant proproteins resulted in a fragment pattern profoundly different from wild-type proGDF5. Modeling of a part of the GDF5 proregion into the known three-dimensional structure of TGFß1 latency-associated peptide revealed that the homologous positions of both mutations are conserved regions that may be important for the folding of the mature protein or the assembly of dimeric protein complexes. We hypothesize that the missense mutations p.T201P and p.L263P interfere with the protein structure and thereby reduce the amount of fully processed, biologically active GDF5, finally causing the clinical loss of function phenotype.

Identification of a core domain within the proregion of bone morphogenetic proteins that interacts with the dimeric, mature domain.

Proregions of bone morphogenetic proteins (BMPs) fulfill important biological functions as intramolecular chaperones and for extracellular targeting of the mature signal ligand. Knowledge of the structures of the proregions would contribute to a more comprehensive picture of the biological activities of the pro-forms of BMP growth factors. In this study, a protease resistant core domain of the proregions of three BMPs was identified. For a more detailed analysis, the core domain of the BMP-2 proregion was recombinantly produced. Unfolding/refolding experiments and spectroscopic analyses proved that the core domain can be obtained as a folded entity. Binding of the core domain to the mature growth factor was demonstrated by SPR. Via peptide microarray analysis, residues within the core fragment could be identified that engage in binding to the dimeric, mature domain. Our study reveals that diverse members of the BMP family share a common, independently folding core domain within the large proregions peculiar to TGF-ß superfamily members that may serve as a scaffold for folding and assembly of the dimeric proprotein complexes.