Abstract
Using a random non-standard peptide integrated discovery system, we obtained cyclic peptides that bind to hepatocyte growth factor (HGF) or mesenchymal-epithelial transition factor. (MET) HGF-inhibitory peptide-8 (HiP-8) selectively bound to two-chain active HGF, but not to single-chain precursor HGF. HGF showed a dynamic change in its molecular shape in atomic force microscopy, but HiP-8 inhibited dynamic change in the molecular shape into a static status. The inhibition of the molecular dynamics of HGF by HiP-8 was associated with the loss of the ability to bind MET. HiP-8 could selectively detect active HGF in cancer tissues, and active HGF probed by HiP-8 showed co-localization with activated MET. Using HiP-8, cancer tissues with active HGF could be detected by positron emission tomography. HiP-8 seems to be applicable for the diagnosis and treatment of cancers. In contrast, based on the receptor dimerization as an essential process for activation, the cross-linking of the cyclic peptides that bind to the extracellular region of MET successfully generated an artificial ligand to MET. The synthetic MET agonists activated MET and exhibited biological activities which were indistinguishable from the effects of HGF. MET agonists composed of cyclic peptides can be manufactured by chemical synthesis but not recombinant protein expression, and thus are expected to be new biologics that are applicable to therapeutics and regenerative medicine.
Highlights
Many aspects of the biological and physiological roles of hepatocyte growth factor (HGF) and the mesenchymal-epithelial transition factor. (MET) receptor have been introduced in previous articles [1,2,3]
The notable biological activities driven by the HGF-MET pathway include the induction of dynamic tubular morphogenesis and cell motility into the epithelial cells [4,5]
A variety of tissue-specific MET knockout mice have revealed that the HGF-MET pathway promotes tissue regeneration, protects against cell death, and suppresses the progression of chronic inflammation and fibrosis in different tissues and cell types [3]
Summary
Many aspects of the biological and physiological roles of HGF and the MET receptor have been introduced in previous articles [1,2,3]. The notable biological activities driven by the HGF-MET pathway include the induction of dynamic tubular morphogenesis and cell motility into the epithelial cells [4,5]. This dynamic morphogenic activity could not be performed by other growth factors [4], and was attributed to the preferential association of MET with the adapter protein Gab1 [5]. TFhcelesaurrlfyascheopwlassmthoenserelescotnivaencbeinadnianlgysoisf HfoirPt-h8etobitncdHinGgFo, fbuHtiPn-o8t ttoo ssccHHGGFF a(FnidgutcrHe G3)F. clearly shows the selective binding of HiP-8 to tcHGF, but not to scHGF (Figure 3). The sensorgram shows that HiP-8 selectively binds to tcHGF, but not to scHGF (B) [20]
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