Bone morphogenetic protein

BMPs for clinical use are produced using recombinant DNA technology (recombinant human BMPs; rhBMPs). Recombinant BMP-2 and BMP-7 are currently approved for human use. BMP-7 has also recently found use in the treatment of chronic kidney disease (CKD). BMP-7 has been shown in murine animal models to reverse the loss of glomeruli due to sclerosis. A 2022 study by researchers from the Mayo Clinic, Maastricht University, and Ethris GmBH, a biotech company that focuses on RNA therapeutics, found that chemically modified mRNA encoding BMP-2 promoted dosage-dependent healing of femoral osteotomies in male rats. The mRNA molecules were complexed within nonviral lipid particles, loaded onto sponges, and surgically implanted into the bone defects. They remained localized around the site of application. Compared to receiving rhBMP-2 directly, bony tissues regenerated after mRNA treatment displayed superior strength and less formation of massive callus. Off-label use Although rhBMP-2 and rhBMP-7 are used in the treatment of a variety of bone-related conditions including spinal fusions and nonunions, the risks of this off-label treatment are not understood. While rhBMPs are approved for specific applications (spinal lumbar fusions with an anterior approach and tibia nonunions), up to 85% of all BMP usage is off-label. ==Contraindications==

Bone morphogenetic protein (rhBMP) should not be routinely used in any type of anterior cervical spine fusion, such as with anterior cervical discectomy and fusion. There are reports of this therapy causing swelling of soft tissue which in turn can cause life-threatening complications due to difficulty swallowing and pressure on the respiratory tract. == Function ==

BMPs interact with specific receptors on the cell surface, referred to as bone morphogenetic protein receptors (BMPRs). Signal transduction through BMPRs results in mobilization of members of the SMAD family of proteins. The signaling pathways involving BMPs, BMPRs and SMADs are important in the development of the heart, central nervous system, and cartilage, as well as post-natal bone development. They have an important role during embryonic development on the embryonic patterning and early skeletal formation. As such, disruption of BMP signaling can affect the body plan of the developing embryo. For example, BMP4 and its inhibitors noggin and chordin help regulate polarity of the embryo (i.e. back to front patterning). Specifically BMP-4 and its inhibitors play a major role in neurulation and the development of the neural plate. BMP-4 signals ectoderm cells to develop into skin cells, but the secretion of inhibitors by the underlying mesoderm blocks the action of BMP-4 to allow the ectoderm to continue on its normal course of neural cell development. Additionally, secretion of BMPs by the roof plate in the developing spinal cord helps to specify dorsal sensory interneurons. As a member of the transforming growth factor-beta superfamily, BMP signaling regulates a variety of embryonic patterning during fetal and embryonic development. For example, BMP signaling controls the early formation of the Müllerian duct (MD) which is a tubular structure in early embryonic developmental stage and eventually becomes female reproductive tracts. Chemical inhibiting BMP signals in chicken embryo caused a disruption of MD invagination and blocked the epithelial thickening of the MD-forming region, indicating that the BMP signals play a role in early MD development. Moreover, BMP signaling is involved in the formation of foregut and hindgut, intestinal villus patterning, and endocardial differentiation. Villi contribute to increase the effective absorption of nutrients by extending the surface area in small intestine. Gain or lose function of BMP signaling altered the patterning of clusters and emergence of villi in mouse intestinal model. BMP signal derived from myocardium is also involved in endocardial differentiation during heart development. Inhibited BMP signal in zebrafish embryonic model caused strong reduction of endocardial differentiation, but only had little effect in myocardial development. In addition, Notch-Wnt-Bmp crosstalk is required for radial patterning during mouse cochlea development via antagonizing manner. Mutations in BMPs and their inhibitors are associated with a number of human disorders which affect the skeleton. Several BMPs are also named 'cartilage-derived morphogenetic proteins' (CDMPs), while others are referred to as 'growth differentiation factors' (GDFs). BMPs are also involved in adipogenesis and functional regulation of adipose tissue. BMP4 favors white adipogenesis, whereas BMP7 activates brown fat functionality; BMP inhibitors are also involved in this regulation ==Types==

Originally, seven such proteins were discovered. Of these, six (BMP2 through BMP7) belong to the Transforming growth factor beta superfamily of proteins. BMP1 is a metalloprotease. Since then, thirteen more BMPs, all of which are in the TGF-beta family, have been discovered, bringing the total to twenty. The current nomenclature only recognizes 13, as many others are put under the growth differentiation factor naming instead. ==History==

From the time of Hippocrates it has been known that bone has considerable potential for regeneration and repair. Nicholas Senn, a surgeon at Rush Medical College in Chicago, described the utility of antiseptic decalcified bone implants in the treatment of osteomyelitis and certain bone deformities. Pierre Lacroix proposed that there might be a hypothetical substance, osteogenin, that might initiate bone growth. The biological basis of bone morphogenesis was shown by Marshall R. Urist. Urist made the key discovery that demineralized, lyophilized segments of bone induced new bone formation when implanted in muscle pouches in rabbits. This discovery was published in 1965 by Urist in Science. Urist proposed the name "Bone Morphogenetic Protein" in the scientific literature in the Journal of Dental Research in 1971. Bone induction is a sequential multistep cascade. The key steps in this cascade are chemotaxis, mitosis, and differentiation. Early studies by Hari Reddi unraveled the sequence of events involved in bone-matrix-induced bone morphogenesis. On the basis of the above work, it seemed likely that morphogens were present in the bone matrix. Using a battery of bioassays for bone formation, a systematic study was undertaken to isolate and purify putative bone morphogenetic proteins. A major stumbling block to purification was the insolubility of demineralized bone matrix. To overcome this hurdle, Hari Reddi and Kuber Sampath used dissociative extractants, such as 4M guanidine HCL, 8M urea, or 1% SDS. The soluble extract alone or the insoluble residues alone were incapable of new bone induction. This work suggested that the optimal osteogenic activity requires a synergy between soluble extract and the insoluble collagenous substratum. It not only represented a significant advance toward the final purification of bone morphogenetic proteins by the Reddi laboratory, but ultimately also enabled the cloning of BMPs by John Wozney and colleagues at Genetics Institute. ==Society==

Costs At between US$6,000 and $10,000 for a typical treatment, BMPs can be costly compared with other techniques such as bone grafting. However, this cost is often far less than the costs required with orthopaedic revision in multiple surgeries. While there is little debate that rhBMPs are successful clinically, but some of the surgeons responsible for the original Medtronic-supported studies on the efficacy of rhBMP-2 have been accused of bias and conflict of interest. For example, one surgeon, a lead author on four of these research papers, did not disclose any financial ties while with the company on three of the papers; he was paid over $4 million by Medtronic. It has since been revealed that potential complications can arise from the use including implant displacement, subsidence, infection, urogenital events, and retrograde ejaculation. == References ==