The dose-dependent α-fetoprotein (AFP) reactivity of different types of tumor cells and normal embryonal fibroblasts, which are capable of taking up AFP, was investigated. High doses (more than 100 µg/ml) of purified human AFP were shown to induce strongly dose-dependent growth inhibition of human hepatoma HepG2 cells, human lymphoblastoma MT4 cells, lymphoma Jurkat cells and murine fibroblastoma L929 cells. Human mammary carcinoma MCF-7 cells also revealed a growth inhibitory response to AFP, although to a lesser extent. Equivalent doses of human serum albumin (HSA) demonstrated no effect on these cells. On the contrary, normal embryonal fibroblasts of different organ origin showed dose-dependent stimulation (50–90%) of proliferation in response to AFP. A similar stimulative effect was obtained when embryonal fibroblasts were treated with the same doses of HSA. The myeloblastoma cell line U-937 and the normal epidermal fibroblast cell line M19 were shown to be resistant to the AFP action over a wide range of protein concentrations. It was demonstrated that growth factor deprivation (i.e. low serum concentration) could stimulate U-937 cell proliferation in response to high doses of AFP. It was also shown that intensive washing of U-937 and MCF-7 cells with fresh medium to remove secreted cytokines and growth factors distinctly increased cell sensitivity to high-dose-AFP-induced growth-inhibitory activity. Low AFP concentrations (less than 100 µg/ml) failed to induce growth inhibition in all studied cells and rather showed a slight stimulative effect. These findings demonstrate that physiological levels of AFP can exhibit a dose-dependent growth-regulatory activity toward sensitive tumor or developing cells. Our data demonstrated that AFP could reveal either stimulative or inhibitory growth activity, depending on the relative concentration of AFP and on exogenous or endogenous cytokines and growth factors in the cell culture medium. A growth-stimulative activity in normal embryonal fibroblasts and certain tumor cell lines exhibited by low AFP concentrations is supposed to result from the synergistic effects of AFP and various other secreted growth factors.
The Yersinia pestis protein Caf1M is a typical representative of a subfamily of periplasmic molecular chaperones with characteristic structural and functional features, one of which is the location of two conserved cysteine residues close to the putative binding pocket. We show that these residues form a disulphide bond, the reduction and alkylation of which significantly increases the dissociation constant of the Caf1M-Caf1 (where Caf 1 is a polypeptide subunit of the capsule) complex [from a K d of (4.77p0.50)i10 −* M for the intact protein to one of (3.68p0.68)i10 −) M for the modified protein]. The importance of the disulphide bond for the formation of functional Caf1M in i o was demonstrated using an Escherichia coli dsbA mutant carrying the Y. pestis f1 operon. In accordance with the CD and fluorescence measurements, the disulphide bond is not important for maintenance of the overall structure of the Caf1M molecule,
The periplasmic molecular chaperone Caf1M of Yersinia pestis is a typical representative of a subfamily of specific chaperones involved in assembly of surface adhesins with a very simple structure. One characteristic feature of this Caf1M-like subfamily is possession of an extended, variable sequence (termed FGL) between the F1 and subunit binding G1 β-strands. In contrast, FGS subfamily members, characterized by PapD, have a short F1-G1 loop and are involved in assembly of complex pili. To elucidate the structural and functional significance of the FGL sequence, a mutant Caf1M molecule (dCaf1M), in which the 27 amino acid residues between the F1 and G1 β-strands had been deleted, was constructed. Expression of the mutated caf1M in Escherichia coli resulted in accumulation of high levels of dCaf1M. The far-UV circular dichroism spectra of the mutant and wild-type proteins were indistinguishable and exhibited practically the same temperature and pH dependencies. Thus, the FGL sequence of Caf1M clearly does not contribute significantly to the stability of the protein conformation. Preferential cleavage of Caf1M by trypsin at Lys-119 confirmed surface exposure of this part of the FGL sequence in the isolated chaperone and periplasmic chaperone-subunit complex. There was no evidence of surface-localized Caf1 subunit in the presence of the Caf1A outer membrane protein and dCaf1M. In contrast to Caf1M, dCaf1M was not able to form a stable complex with Caf1 nor could it protect the subunit from proteolytic degradation in vivo. This demonstration that the FGL sequence is required for stable chaperone-subunit interaction, but not for folding of a stable chaperone, provides a sound basis for future detailed molecular analyses of the FGL subfamily of chaperones.
We have investigated the effects of purified human α-fetoprotein (AFP) on the growth of the human hepatocarcinoma cells HepG2 in culture. Cancer-derived AFP (cAFP), isolated from the culture medium of AFP-secreting HepG2 cells and embryonal AFP (eAFP), isolated from human cord serum, were used for these studies. Both AFP preparations studied were shown to induce strong dose-dependent inhibition of HepG2 cell proliferation and complete growth arrest at high protein concentrations (more than 0.1 mg/ml). To test whether AFP may trigger an endogenous suicide program in hepatoma cells, we examined whether DNA fragmentation preceded cell death. After exposure of the cells to the high AFP dose (1.0 mg/ml), DNA fragmentation was detected as early as 2 h after treatment, and 70% of cells were apoptotic by 24 h. DNA fragmentation was shown to precede other signs of cell death for several hours. Typical morphological changes of apoptosis were observed after 4 h of exposure of cells to high AFP doses. Low concentrations of cAFP and eAFP (less than 0.1 mg/ml) failed to induce growth inhibition of HepG2 cells, rather showing a weak stimulative effect, demonstrating a biphasic AFP activity. Cell pretreatment with the transcriptional inhibitor actinomycin D had no measurable influence on AFP cytotoxicity. These findings demonstrate that protein synthesis is not required for this mechanism of cell death. The charcoal-treated ligand-free eAFP (eAFPp) had a dose-dependent growth-inhibitory activity, similar to intact protein, but slightly less intensive. The similar growth-inhibitory activities of cAFP, eAFP and eAFPp, which have a significant difference in bound-ligand content, provide evidence that the main role in cell growth regulation may be attributed to the protein moiety of the entire AFP molecule, but not to its ligands. These biologically active AFP ligands could, however, modulate AFP-growth-regulating activity. Growth factor deprivation distinctly enhanced the cytostatic activity of high AFP concentrations and also increased the mitogenic activity of low AFP levels, showing the interdependence of the growth-regulative activity of AFP and growth factors. The findings of this study demonstrated that AFP is directly introduced into the intracellular pathways of cell growth regulation and programmed cell death.
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