Dynamic simulation of an in vitro multi-enzyme system.

Parameters often are tuned with metabolite concentration time series data to build a dynamic model of metabolism. However, such tuning may reduce the extrapolation ability (generalization capability) of the model. In this study, we determined detailed kinetic parameters of three purified Escherichia coli glycolytic enzymes using the initial velocity method for individual enzymes; i.e., the parameters were determined independently from metabolite concentration time series data. The metabolite concentration time series calculated by the model using the parameters matched the experimental data obtained in an actual multi-enzyme system consisting of the three purified E. coli glycolytic enzymes. Thus, the results indicate that kinetic parameters can be determined without using an undesirable tuning process.

A mode of assembly of P0, P1, and P2 proteins at the GTPase-associated center in animal ribosome: in vitro analyses with P0 truncation mutants.

Ribosomal P0, P1, and P2 proteins, together with the conserved domain of 28 S rRNA, constitute a major part of the GTPase-associated center in eukaryotic ribosomes. We investigated the mode of assembly in vitro by using various truncation mutants of silkworm P0. When compared with wild type (WT)-P0, the C-terminal truncation mutants CDelta65 and CDelta81 showed markedly reduced binding ability to P1 and P2, which was offset by the addition of an rRNA fragment covering the P0.P1-P2 binding site. The mutant CDelta107 lost the P1/P2 binding activity, whereas it retained the rRNA binding. In contrast, the N-terminal truncation mutants NDelta21-NDelta92 completely lost the rRNA binding, although they retained P1/P2 binding capability, implying an essential role of the N terminus of P0 for rRNA binding. The P0 mutants NDelta6, NDelta14, and CDelta18-CDelta81, together with P1/P2 and eL12, bound to the Escherichia coli core 50 S subunits deficient in L10.L7/L12 complex and L11. Analysis of incorporation of (32)P-labeled P1/P2 into the 50 S subunits with WT-P0 and CDelta81 by sedimentation analysis indicated that WT-P0 bound two copies of P1 and P2, but CDelta81 bound only one copy each. The hybrid ribosome with CDelta81 that appears to contain one P1-P2 heterodimer retained lower but considerable activities dependent on eukaryotic elongation factors. These results suggested that two P1-P2 dimers bind to close but separate regions on the C-terminal half of P0. The results were further confirmed by binding experiments using chimeric P0 mutants in which the C-terminal 81 or 107 amino acids were replaced with the homologous sequences of the archaebacterial P0.

Baculovirus-mediated expression and isolation of human ribosomal phosphoprotein P0 carrying a GST-tag in a functional state.

We constructed an overexpression system for human ribosomal phosphoprotein P0, together with P1 and P2, which is crucially important for translation. Genes for these proteins, fused with the glutathione S-transferase (GST)-tag at the N-terminus, were inserted into baculovirus and introduced to insect cells. The fusion proteins, but not the proteins without the tag, were efficiently expressed into cells as soluble forms. The fusion protein GST.P0 as well as GST.P1/GST.P2 was phosphorylated in cells as detected by incorporation of (32)P and reactivity with monoclonal anti-phosphoserine antibody. GST.P0 expressed in insect cells, but not the protein obtained in Escherichia coli, had the ability to form a complex with P1 and P2 proteins and to bind to 28S rRNA. Moreover, the GST.P0-P1-P2 complex participated in high eEF-2-dependent GTPase activity. Baculovirus expression systems appear to provide recombinant human P0 samples that can be used for studies on the structure and function.