Previous reports had pointed to serines 62 and 71/79 as possible phosphorylation sites in the yeast acidic ribosomal proteins YP1 alpha and YP2 alpha, respectively. However, it has been found that mutation of these serine residues did not affect the phosphorylation level of the proteins. A detailed examination of the YP2 alpha tryptic digest from the in vivo labeled protein demonstrates the existence of a totally trypsin-insensitive site at lysine 88 that led to a misinterpretation of previous results. The unique YP2 alpha tryptic phosphopeptide obtained contains, in addition to serines 71 and 79, a serine at position 96 near the carboxyl end, which automatic Edman degradation confirmed as the phosphorylated residue. In addition, by using Staphyloccocus protease V8, it was possible to obtain phosphopeptides containing only serine 96, whose phosphorylation has likewise been confirmed by radioactive labeling as well as by chemical methods. A similar analysis of the other 12 kDa acidic proteins, YP1 alpha, YP1 beta, and YP2 beta, has shown the presence of equivalent phosphorylation sites in the four P proteins, which correspond to position 96 in proteins YP1 alpha, YP1 beta, and YP2 alpha and position 100 in YP2 beta. This conclusion has been confirmed by the fact that mutation of serine 96 in proteins YP1 alpha and YP2 alpha abolishes their capacity to be phosphorylated in vivo. The mutation of the phosphorylation site of the individual acidic proteins seems not to alter their interaction with the ribosome. However, it has been found that the level of phosphorylation of the stalk proteins has an effect on the response of the cells to some specific metabolic conditions, indicating that it may modulate the translation of specific proteins.
The eukaryoic ribosomal stalk is thought to consist of the phosphoproteins P1 and P2, which form a complex with protein PO. This complex interacts at the GTPase domain in the large subunit rRNA, overlapping the binding site of the protein L11-like eukaryotic counterpart (Saccharomyces cerevisiae protein L15 and mammalian protein L12). An unusual pool of the dephosphorylated forms of proteins P1 and P2 is detected in eukaryotic cytoplasm, and an exchange between the proteins in the pool and on the ribosome takes place during translation. Quadruply disrupted yeast strains, carrying four inactive acidic protein genes and, therefore, containing ribosomes totally depleted of acidic proteins, are viable but grow with a doubling time threefold higher than wild-type cells. The in vitro translation systems derived from these stains are active but the two-dimensional gel electrophoresis pattern of proteins expressed in vivo and in vitro is partially different. These results indicate that the P1 and P2 proteins are not essential for ribosome activity but are able to affect the translation of some specific mRNAs. Protein PO is analogous to bacterial ribosomal protein L10 but carries an additional carboxyl domain showing a high sequence homology to the acidic proteins P1 and P2, including the terminal peptide DDDMGFGLFD. Successive deletions of the PO carboxyl domain show that removal of the last 21 amino acids from the PO carboxyl domain only slightly affects the ribosome activity in a wild-type genetic background; however, the same deletion is lethal in a quadruple disruptant deprived of acidic P1/P2 proteins. Additional deletions affect the interaction of PO with the P1 and P2 proteins and with the rRNA. The experimental data available support the implication of the eukaryotic stalk components in some regulatory process that modulates the ribosomal activity.
Protein L12, together with the P0/P1/P2 protein complex, forms the protein moiety of the GTPase domain in the eukaryotic ribosome. In Saccharomyces cerevisiae protein L12 is encoded by a duplicated gene, rpL12A and rpL12B. Inactivation of both copies has been performed and confirmed by Southern and Western analyses. The resulting strains are viable but grow very slowly. Growth rate is recovered upon transformation with an intact copy of the L12 gene. Ribosomes from the disrupted strain lack protein L12 but are able to carry out translation in vitro at about one fourth of the control rate. The L12-deficient ribosomes have also a defective stalk containing standard amounts of the 12-kDa acidic proteins P1 and P2␣, but proteins P1␣ and P2 are drastically reduced. Moreover, the affinity of P0 is reduced in the defective ribosomes. Footprinting of the 26 S rRNA GTPase domain indicates that protein L12 protects in different extent residues G1235, G1242, A1262, A1270, and A1272 from chemical modification. The results in this report indicate that protein L12 is not essential for cell viability but has a relevant role in the structure and stability of the eukaryotic ribosomal stalk.
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