Assembly of <i>Saccharomyces cerevisiae</i> Ribosomal Stalk:  Binding of P1 Proteins Is Required for the Interaction of P2 Proteins

Zurdo, Jesús; Parada, Pilar; Berg, Anke van den; Nusspaumer, Gretel; Jiménez-Díaz, Antonio; Remacha, Miguel; Jp, Ballesta

doi:10.1021/bi000362j

Cited by 46 publications

(51 citation statements)

References 31 publications

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“…Protein P0 seems to be able to directly interact only with the P1 proteins as shown previously by ribosome reconstitution tests (58) and double hybrid data (36), and it is possible, therefore, that a direct interaction between P0 and the P2 proteins may not exist in the ribosome. There are at least two ways in which P1␣⅐P2␤ and P1␤⅐P2␣ can be assembled in the stalk (Fig.…”

Section: Figsupporting

confidence: 57%

Asymmetric Interactions between the Acidic P1 and P2 Proteins in the Saccharomyces cerevisiae Ribosomal Stalk

Guarinos

Remacha

Ballesta

2001

Journal of Biological Chemistry

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The Saccharomyces cerevisiae ribosomal stalk is made of five components, the 32-kDa P0 and four 12-kDa acidic proteins, P1␣, P1␤, P2␣, and P2␤. The P0 carboxyl-terminal domain is involved in the interaction with the acidic proteins and resembles their structure. Protein chimeras were constructed in which the last 112 amino acids of P0 were replaced by the sequence of each acidic protein, yielding four fusion proteins, P0-1␣, P0-1␤, P0-2␣, and P0-2␤. The chimeras were expressed in P0 conditional null mutant strains in which wild-type P0 is not present. In S. cerevisiae D4567, which is totally deprived of acidic proteins, the four fusion proteins can replace the wild-type P0 with little effect on cell growth. In other genetic backgrounds, the chimeras either reduce or increase cell growth because of their effect on the ribosomal stalk composition. An analysis of the stalk proteins showed that each P0 chimera is able to strongly interact with only one acidic protein. The following associations were found: P0-1␣⅐P2␤, P0-1␤⅐P2␣, P0-2␣⅐P1␤, and P0-2␤⅐P1␣. These results indicate that the four acidic proteins do not form dimers in the yeast ribosomal stalk but interact with each other forming two specific associations, P1␣⅐P2␤ and P1␤⅐P2␣, which have different structural and functional roles.

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Section: Figsupporting

confidence: 57%

Asymmetric Interactions between the Acidic P1 and P2 Proteins in the Saccharomyces cerevisiae Ribosomal Stalk

Guarinos

Remacha

Ballesta

2001

Journal of Biological Chemistry

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“…There is also a consensus for an anchorage of the P1/P2 dimer by a direct interaction of the P1 N-terminal domain, but not the P2 N-terminal domain with P0 (Gonzalo et al, 2001;Shimizu et al, 2002;Zurdo et al, 2000).…”

Section: Binding Of P1/p2 Dimers (And Equivalents) To P0 (And Equivalmentioning

confidence: 99%

The puzzling lateral flexible stalk of the ribosome

Gonzalo

Reboud

2003

Biology of the Cell

128

131

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The lateral flexible stalk of the large ribosomal subunit is made of several interacting proteins anchored to a conserved region of the 28S (26S) rRNA termed the GTPase-associated domain or thiostrepton loop. This structure is demonstrated to adopt puzzling changes of conformation following the different steps of the elongation cycle. Some of these proteins termed the P-proteins in eukaryotes and L10 and L7/L12 in bacteria, present little structural similarities between Eubacteria on one side and Archae and Eukaryotes on the other side. However, up to now, these proteins seem to present a similar macromolecular organisation and they have been involved in the same functions. Convincing evidence attests that these proteins participate in elongation factor binding to the ribosome, and it has been suggested that these proteins might be evolved in a GTP hydrolysis activating protein activity. Involvement of these proteins in the translational mechanism is discussed. Moreover, in eukaryotes, small P-proteins are also found as isolated proteins in a cytoplasmic pool that exchanges with the ribosome-associated P-proteins. Moreover, a part of the ribosomal proteins is phosphorylated (hence their P-protein names). The biological signification of these particularities is discussed.

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“…P0 has the same 11-amino acid C-terminal sequence as P1 and P2, and the phosphorylation site, Ser-302 in P0, is within this conserved C terminus. Examination of the stalk assembly both in vivo and in vitro has revealed that P2␤ is unable to bind to the ribosome in the absence of P1␣; in contrast P1␣ is capable of binding to the particle in the absence of P2␤ (13). These results have been interpreted to suggest that assembly of the stalk complex is a coordinated process in which P1 proteins provide anchorage to the ribosome for the P2 proteins, whereas the P2 proteins confer functionality to the complex (13).…”

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confidence: 99%

“…Examination of the stalk assembly both in vivo and in vitro has revealed that P2␤ is unable to bind to the ribosome in the absence of P1␣; in contrast P1␣ is capable of binding to the particle in the absence of P2␤ (13). These results have been interpreted to suggest that assembly of the stalk complex is a coordinated process in which P1 proteins provide anchorage to the ribosome for the P2 proteins, whereas the P2 proteins confer functionality to the complex (13). Recent evidence has also shown that the heterodimer P1␣-P2␤ is a stable entity in solution; this observation led to the proposal that the P proteins form dimers in the cytoplasm prior to assembly on the ribosome (14).…”

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confidence: 99%

Mass Spectrometry of Ribosomes from Saccharomyces cerevisiae

Hanson

Videler

Santos

et al. 2004

Journal of Biological Chemistry

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The acidic ribosomal P proteins form a distinct protuberance on the 60 S subunit of eukaryotic ribosomes. In yeast this structure is composed of two heterodimers (P1␣-P2␤ and P1␤-P2␣) attached to the ribosome via P0. Although for prokaryotic ribosomes the isolation of a pentameric stalk complex comprising the analogous proteins is well established, its observation has not been reported for eukaryotic ribosomes. We used mass spectrometry to examine the composition of the stalk proteins on ribosomes from Saccharomyces cerevisiae. The resulting mass spectra reveal a noncovalent complex of mass 77,291 ؎ 7 Da assigned to the pentameric stalk. Tandem mass spectrometry confirms this assignment and is consistent with the location of the P2 proteins on the periphery of the stalk complex, shielding the P1 proteins, which in turn interact with P0. No other oligomers are observed, confirming the specificity of the pentameric complex. At lower m/z values the spectra are dominated by individual proteins, largely from the stalk complex, giving rise to many overlapping peaks. To define the composition of the stalk proteins in detail we compared spectra of ribosomes from strains in which genes encoding either or both of the interacting stalk proteins P1␣ or P2␤ are deleted. This enables us to define novel post-translational modifications at very low levels, including a population of P2␣ molecules with both phosphorylation and trimethylation. The deletion mutants also reveal interactions within the heterodimers, specifically that the absence of P1␣ or P2␤ destabilizes binding of the partner protein on the ribosome. This implies that assembly of the stalk complex is not governed solely by interactions with P0 but is a cooperative process involving binding to partner proteins for additional stability on the ribosome.Ribosomes are the universal translators of messenger RNA into proteins. X-ray analysis of the 30 S subunit from Thermus thermophilus, the 50 S subunit from Haloarcula marismortui, and the intact 70 S particle from T. thermophilus have revealed fascinating insights into the structures of these macromolecular machines (1-3). There are currently, however, no high resolution structures of eukaryotic ribosomes. These 80 S particles consist of two subunits, the 60 and 40 S subunits. Low resolution structures obtained by electron microscopy indicate an overall topology similar to that of the Escherichia coli 70 S ribosome but indicate that the eukaryotic particle is larger and more complex. In general, the core of the ribosome is highly conserved, but in S. cerevisiae there are large differences in the periphery of the particle. This is attributed to the presence of additional ribosomal proteins and ribosomal RNA (rRNA) regions of variable size, interrupting the universal core secondary structure of eukaryotic rRNA (4). The eukaryotic 60 S subunit is larger than the prokaryotic 50 S subunit, but the greatest differences are observed between the 30 S subunit and the eukaryotic 40 S subunit .A common feature of all ribosomes is ...

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Assembly of Saccharomyces cerevisiae Ribosomal Stalk: Binding of P1 Proteins Is Required for the Interaction of P2 Proteins

Cited by 46 publications

References 31 publications

Asymmetric Interactions between the Acidic P1 and P2 Proteins in the Saccharomyces cerevisiae Ribosomal Stalk

Asymmetric Interactions between the Acidic P1 and P2 Proteins in the Saccharomyces cerevisiae Ribosomal Stalk

The puzzling lateral flexible stalk of the ribosome

Mass Spectrometry of Ribosomes from Saccharomyces cerevisiae

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