Michio Hagiya

Deletion of kringle domains or the N-terminal hairpin structure in hepatocyte growth factor results in marked decreases in related biological activities

To determine the essential domain for biological activity in the hepatocyte growth factor (HGF) molecule, we prepared various mutated recombinant HGFs using site-directed mutagenesis, and examined the effects on DNA synthesis in hepatocytes, scattering of MDCK cells and the antiproliferative activity on HepG2 hepatoma cells. Native HGF and mutant HGFs, in which Gln534 and/or Tyr673 were respectively substituted for His and Ser to coincide with the catalytic triad amino acids in plasmin, markedly stimulated DNA synthesis of hepatocytes and scattering of MDCK cells but inhibited DNA synthesis of HepG2 cells. The mutant HGF deleted with the third or fourth kringle domain resulted in marked decrease of all three biological activities, while deletion of the N-terminal hairpin structure or the first or second kringle domain almost completely inactivated biological activities. We propose that the N-terminal hairpin structure and the first and second kringle domains are essential for biological activities of HGF and possibly for binding to its receptor.

Analysis of the structure and expression of the Augmenter of Liver Regeneration (ALR) gene

BackgroundThe gene encoding the hepatotrophic factor Augmenter of Liver Regeneration (ALR) has recently been cloned in the rat. The availability of the mouse form of ALR would allow the analysis of the role of this factor in the physiology of liver and other organs, while the identification of the human homolog would allow the transfer of the great wealth of information that has been generated in animal models to clinically oriented pilot trials, and eventually the therapeutic application of this information.Materials and MethodsStandard molecular biology approaches have been used to determine the genomic structure of the ALR gene in the mouse, and to characterize the ALR transcript and its protein product. The human ALR cDNA was also isolated and the amino acid sequence of the human gene product deduced. The mapping of mouse and human ALR genes on mouse and human chromosomes was then completed.ResultsThe protein coding portion of the mouse ALR gene is comprised of three exons, the first containing the 5′ untranslated sequence and the initial 18 bases after the ATG translation initiation codon, the second exon encompasses 198 bases, and the third exon contains the remaining portion of the protein coding sequence. Rat, mouse, and human ALR genes (and protein products) were found to be highly conserved and preferentially expressed in the testis and in the liver. The ALR gene maps to the mouse chromosome 17, in a region syntenic with human chromosome 16, where the T/t region has also been mapped.ConclusionsALR appears to be a protein with important physiologic properties, not exclusively limited to liver regeneration, with roles that are involved in the synthesis or stability of the nuclear and mitochondrial transcripts that are present in actively regenerating cells, particularly the germ cells of the testes.

Macrophage stimulating protein (MSP) binds to its receptor via the MSP beta chain.

Macrophage stimulating protein (MSP) is a 78-kDa disulfide-linked heterodimer belonging to the plasminogen-related kringle protein family. MSP activates the RON receptor protein-tyrosine kinase, which results in cell migration, shape change, or proliferation. A structure-activity study of MSP was performed using pro-MSP, MSP, MSP α and β chains, and a complex including the first two kringles and IgG Fc (MSP-NK2). Radioiodinated MSP and MSP β chain both bound specifically to RON. The K d of 1.4 nm for MSP β chain is higher than the reportedK d range of 0.6–0.8 nm for MSP. Pro-MSP, MSP α chain, and MSP-NK2 did not bind. Only MSP stimulated RON autophosphorylation. Although the β chain bound to RON and partially inhibited MSP-induced RON phosphorylation in kidney 293 cells, it did not induce RON phosphorylation. Pro-MSP, MSP α chain, or MSP-NK2 failed to activate RON, consistent with their inability to bind to the RON receptor. Functional studies showed that only MSP induced cell migration, and shape change in resident macrophages, and growth of murine keratinocytes. Our data indicate that the primary receptor binding domain is located in a region of the MSP β chain, in contrast to structurally similar hepatocyte growth factor, in which the receptor binding site is in the α chain. However, full activation of RON requires binding of the complete MSP disulfide-linked αβ chain heterodimer.