Marcela Wildová scite author profile

Prion diseases have been observed to deregulate the transcription of erythroid genes, and prion protein knockout mice have demonstrated a diminished response to experimental anemia. To investigate the role of the cellular prion protein (PrPC) in erythropoiesis, we studied the protein's expression on mouse erythroid precursors in vivo and utilized an in vitro model of the erythroid differentiation of murine erythroleukemia cells (MEL) to evaluate the effect of silencing PrPC through RNA interference.The expression of PrPC and selected differentiation markers was analyzed by quantitative multicolor flow cytometry, western blot analysis and quantitative RT-PCR. The silencing of PrPC expression in MEL cells was achieved by expression of shRNAmir from an integrated retroviral vector genome. The initial upregulation of PrPC expression in differentiating erythroid precursors was detected both in vivo and in vitro, suggesting PrPC's importance to the early stages of differentiation. The upregulation was highest on early erythroblasts (16200±3700 PrPC / cell) and was followed by the gradual decrease of PrPC level with the precursor's maturation reaching 470±230 PrPC / cell on most mature CD71−Ter119+ small precursors. Interestingly, the downregulation of PrPC protein with maturation of MEL cells was not accompanied by the decrease of PrP mRNA. The stable expression of anti-Prnp shRNAmir in MEL cells led to the efficient (>80%) silencing of PrPC levels. Cell growth, viability, hemoglobin production and the transcription of selected differentiation markers were not affected by the downregulation of PrPC.In conclusion, the regulation of PrPC expression in differentiating MEL cells mimics the pattern detected on mouse erythroid precursors in vivo. Decrease of PrPC protein expression during MEL cell maturation is not regulated on transcriptional level. The efficient silencing of PrPC levels, despite not affecting MEL cell differentiation, enables created MEL lines to be used for studies of PrPC cellular function.

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The effect of point mutations within the N-terminal domain of Mason-Pfizer monkey virus capsid protein on virus core assembly and infectivity

Wildová

Hadravová

Štokrová

et al. 2008

Virology

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Retroviral capsid protein (CA) mediates protein interactions driving the assembly of both immature viral particles and the core of the mature virions. Structurally conserved N-terminal domains of several retroviruses refold after proteolytic cleavage into a β-hairpin, stabilized by a salt bridge between conserved N-terminal Pro and Asp residues. Based on comparison with other retroviral CA, we identified Asp50 and Asp57 as putative interacting partners for Pro1 in Mason-Pfizer monkey virus (M-PMV) CA. To investigate the importance of CA Pro1 and its interacting Asp in M-PMV core assembly and infectivity, P1A, P1Y, D50A, T54A and D57A mutations were introduced into M-PMV. The P1A and D57A mutations partially blocked Gag processing and the released viral particles exhibited aberrant cores and were non-infectious. These data indicate that the region spanning residues Asp50–Asp57 plays an important role in stabilization of the β-hairpin and that Asp57 likely forms a salt-bridge with P1 in M-PMV CA.

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Marcela Wildová

NMR Structure of the N-Terminal Domain of Capsid Protein from the Mason–Pfizer Monkey Virus

Expression of Prion Protein in Mouse Erythroid Progenitors and Differentiating Murine Erythroleukemia Cells

The effect of point mutations within the N-terminal domain of Mason-Pfizer monkey virus capsid protein on virus core assembly and infectivity

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