55 research outputs found
Structural properties of the human acidic ribosomal P proteins forming the P1-P2 heterocomplex.
The ribosome has a morphologically distinct structural feature called the stalk, recognized as a vital element for its function. The ribosomal P proteins constitute the main part of the eukaryotic ribosomal stalk, forming a pentameric structure P0-(P1-P2)(2). The group of P1/P2 proteins in eukaryotes is very diverse, and in spite of functional and structural similarities they do not fully complement one another, probably constituting an adaptive feature of the ribosome from a particular species to diverse environmental conditions. The functional differences among the P1/P2 proteins were analysed in vivo several times; however, a thorough molecular characterization was only done for the yeast P1/P2 proteins. Here, we report a biophysical analysis of the human P1 and P2 proteins, applying mass spectrometry, CD and fluorescence spectroscopy, cross-linking and size exclusion chromatography. The human P1/P2 proteins form stable heterodimer, as it is the case for P1/P2 from yeast. However, unlike the yeast complex P1A-P2B, the human P1-P2 dimer showed a three-state transition mechanism, suggesting that an intermediate species may exist in solution
Synthetic peptides including acidic clusters as substrates of yeast casein kinase-2.
The synthesis is reported of a series of glutamyl peptide analogs of the model substrate H-Ser-Glu-Glu-Glu-Glu-Glu-OH of casein kinase-2 (CK-2). A convenient HPLC method for the separation of slightly different acidic peptides is also reported. The site specificity of yeast casein kinase-2 (Y-CK2) is examined with the aid of synthesized peptide substrates
Elevated copy number of L-A virus in yeast mutant strains defective in ribosomal stalk.
The eukaryotic ribosomal stalk, composed of the P-proteins, is a part of the GTPase-associated-center which is directly responsible for stimulation of translation-factor-dependent GTP hydrolysis. Here we report that yeast mutant strains lacking P1/P2-proteins show high propagation of the yeast L-A virus. Affinity-capture-MS analysis of a protein complex isolated from a yeast mutant strain lacking the P1A/P2B proteins using anti-P0 antibodies showed that the Gag protein, the major coat protein of the L-A capsid, is associated with the ribosomal stalk. Proteomic analysis revealed that the elongation factor eEF1A was also present in the isolated complex. Additionally, yeast strains lacking the P1/P2-proteins are hypersensitive to paromomycin and hygromycin B, underscoring the fact that structural perturbations in the stalk strongly influence the ribosome function, especially at the level of elongation
Biophysical properties of the eukaryotic ribosomal stalk.
The landing platform for the translational GTPases is located on the 60S ribosomal subunit and is referred to as a GTPase-associated center. The most distinctive feature of this center is an oligomeric complex, the stalk, responsible for the recruitment of translation factors and stimulation of translation factor-dependent GTP hydrolysis. In eukaryotes, the stalk has been investigated in vitro and in vivo, but most information available concerns its individual components only. In the present study, we provide an insight into the biophysical nature of the native stalk isolated from the yeast Saccharomyces cerevisiae. Using fluorescence, circular dichroism, and mass spectrometry analyses, we were able to characterize the natively formed yeast stalk, casting new light on the oligomeric properties of the complex and its quaternary topology, showing that folding and assembly are coupled processes. The pentameric stalk is an exceptionally stable structure with the protein core composed of P0, P1A, and P2B proteins and less tightly bound P1B and P2A capable of dissociating from the stalk core. We obtained also the whole picture of the posttranslational modifications at the logarithmic phase of yeast growth, using mass spectrometry approach, where P proteins are phosphorylated at a single serine residue, P0 may accept two phosphate groups, and P1A none. Additionally, only P1B undergoes N-terminal acetylation after prior methionine removal
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