In foot-and-mouth disease virus (FMDV)-infected cells, the disappearance of nuclear protein histone H3 and the simultaneous appearance of a new chromatin-associated protein termed Pi can be observed (P. R. Grigera and S. G. Tisminetzky, Virology 136:10-19, 1984). We sequenced the amino terminus of protein Pi and showed that Pi derives from histone H3 by proteolytic cleavage. The 20 N-terminal amino acid residues of histone H3 are specifically cleaved off early during infection. Truncated histone H3 remains chromatin associated. In addition, we showed that the histone H3-Pi transition is catalyzed by the FMDV 3C protease. The only known function of the viral 3C protease was, until now, the processing of the viral polyprotein. The viral 3C protease is the only FMDV protein required to induce the histone H3-Pi transition, as well as being the only viral protein capable of cleaving histone H3. No viral precursor fusion protein is needed for this specific cleavage as was reported for the processing of the poliovirus P1 precursor polyprotein by 3C/D protease. As the deleted part of the histone H3 corresponds to the presumed regulatory domain involved in the regulation of transcriptionally active chromatin in eucaryotes, it seems possible that this specific cleavage of histone H3 is related to the host cell transcription shutoff reported for several picornaviruses.
BackgroundTumor cells in vivo encounter diverse types of microenvironments both at the site of the primary tumor and at sites of distant metastases. Understanding how the various mechanical properties of these microenvironments affect the biology of tumor cells during disease progression is critical in identifying molecular targets for cancer therapy.Methodology/Principal FindingsThis study uses flexible polyacrylamide gels as substrates for cell growth in conjunction with a novel proteomic approach to identify the properties of rigidity-dependent cancer cell lines that contribute to their differential growth on soft and rigid substrates. Compared to cells growing on more rigid/stiff substrates (>10,000 Pa), cells on soft substrates (150–300 Pa) exhibited a longer cell cycle, due predominantly to an extension of the G1 phase of the cell cycle, and were metabolically less active, showing decreased levels of intracellular ATP and a marked reduction in protein synthesis. Using stable isotope labeling of amino acids in culture (SILAC) and mass spectrometry, we measured the rates of protein synthesis of over 1200 cellular proteins under growth conditions on soft and rigid/stiff substrates. We identified cellular proteins whose syntheses were either preferentially inhibited or preserved on soft matrices. The former category included proteins that regulate cytoskeletal structures (e.g., tubulins) and glycolysis (e.g., phosphofructokinase-1), whereas the latter category included proteins that regulate key metabolic pathways required for survival, e.g., nicotinamide phosphoribosyltransferase, a regulator of the NAD salvage pathway.Conclusions/SignificanceThe cellular properties of rigidity-dependent cancer cells growing on soft matrices are reminiscent of the properties of dormant cancer cells, e.g., slow growth rate and reduced metabolism. We suggest that the use of relatively soft gels as cell culture substrates would allow molecular pathways to be studied under conditions that reflect the different mechanical environments encountered by cancer cells upon metastasis to distant sites.
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