The eukaryotic small ribosomal subunit (40S) is the smaller subunit of the eukaryotic 80S ribosomes, with the other major component being the large ribosomal subunit (60S). The "40S" and "60S" names originate from the convention that ribosomal particles are denoted according to their sedimentation coefficients in Svedberg units. It is structurally and functionally related to the 30S subunit of 70S prokaryotic ribosomes.[1][2][3][4][5] However, the 40S subunit is much larger than the prokaryotic 30S subunit and contains many additional protein segments, as well as rRNA expansion segments.

Function

The 40S subunit contains the decoding center which monitors the complementarity of tRNA and mRNA in protein translation. It is the largest component of several translation initiation complexes, including the 43S and 48S preinitiation complexes (PICs), being bound by several eukaryotic initiation factors, including eIF1, eIF1A, and eIF3.[6] The 40S ribosomal subunit is also tightly bound by the HCV IRES to form a binary complex mediate by protein-mRNA and rRNA-mRNA interactions.[7] More information can be found in the articles on the ribosome, the eukaryotic ribosome (80S), and the article on protein translation.

Overall structure

The shape of the small subunit can be subdivided into two large segments, the head and the body. Characteristic features of the body include the left and right feet, the shoulder and the platform. The head features a pointed protrusion reminiscent of a bird's beak. The mRNA binds in the cleft between the head and the body, and there are three binding sites for tRNA, the A-site, P-site and E-site (see article on protein translation for details). The core of the 40S subunit is formed by the 18S ribosomal RNA (abbreviated 18S rRNA), which is homologous to the prokaryotic 16S rRNA. This rRNA core is decorated with dozens of proteins. In the figure "Crystal Structure of the Eukaryotic 40S Ribosomal Subunit from T. thermophila", the ribosomal RNA core is represented as a grey tube and expansion segments are shown in red. Proteins which have homologs in eukaryotes, archaea and bacteria are shown as blue ribbons. Proteins shared only between eukaryotes and archaea are shown as orange ribbons and proteins specific to eukaryotes are shown as red ribbons.

40S ribosomal proteins

The table "40S ribosomal proteins" shows the individual protein folds of the 40S subunit colored by conservation. Proteins which have homologs in eukaryotes, archaea and bacteria (EAB) are shown as blue ribbons. Proteins shared only between eukaryotes and archaea (EA) are shown as orange ribbons and proteins specific to eukaryotes (E) are shown as red ribbons. Eukaryote-specific extensions of conserved proteins, ranging from a few residues or loops to very long alpha helices and additional domains, are highlighted in red.[2] For a details, refer to the article on the eukaryotic ribosome. Historically, different nomenclatures have been used for ribosomal proteins. For instance, proteins have been numbered according to their migration properties in gel electrophoresis experiments. Therefore, different names may refer to homologous proteins from different organism, while identical names not necessarily denote homologous proteins. The table "40S ribosomal proteins" crossreferences the human ribosomal protein names with yeast, bacterial and archaeal homologs.[8] Further information can be found in the ribosomal protein gene database (RPG).[8]

40S ribosomal proteins
Structure (Eukaryotic)[9] H. sapiens[8][10] Universal name [11] Conservation[12] S. cerevisiae[13] Bacterial homolog (E. coli) Archaeal homolog
RPSAuS2EABS0S2pS2
RPS2uS5EABS2S5pS5p
RPS3uS3EABS3S3pS3p
RPS3AeS1EAS1n/aS3Ae
RPS4 (RPS4X, RPS4Y1, RPS4Y2)eS4EAS4n/aS4e
RPS5uS7EABS5S7pS5p
RPS6eS6EAS6n/aS6e
RPS7eS7ES7n/an/a
RPS8eS8EAS8n/aS8e
RPS9uS4EABS9S4pS4p
RPS10eS10ES10n/an/a
RPS11uS17EABS11S17pS17p
RPS12eS12ES12n/an/a
RPS13uS15EABS13S15pS15p
RPS14uS11EABS14S11pS11p
RPS15uS19EABS15S19pS19p
RPS15AuS8EABS22S8pS8p
RPS16uS9EABS16S9pS9p
RPS17eS17EAS17n/aS17e
RPS18uS13EABS18S13pS13p
RPS19eS19EAS19n/aS19e
RPS20uS10EABS20S10pS10p
RPS21eS21ES21n/an/a
RPS23uS12EABS23S12pS12p
RPS24eS24EAS24n/aS24e
RPS25eS25EAS25n/aS25e
RPS26eS26EAS26n/aS26e
RPS27eS27EAS27n/aS27e
RPS27AeS31EAS31n/aS27ae
RPS28eS28EAS28n/aS28e
RPS29uS14EABS29S14pS14p
RPS30eS30EAS30n/aS30e
RACK1RACK1EAsc1n/an/a

See also

References

  1. 40S+Ribosomal+Subunits at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  2. 1 2 Rabl, J; Leibundgut, M; Ataide, SF; Haag, A; Ban, N (Feb 2011). "Crystal structure of the eukaryotic 40S ribosomal subunit in complex with initiation factor 1". Science. 331 (6018): 730–736. Bibcode:2011Sci...331..730R. doi:10.1126/science.1198308. hdl:20.500.11850/153130. PMID 21205638. S2CID 24771575.
  3. Ben-Shem, A; Garreau; de Loubresse, N; Melnikov, S; Jenner, L; Yusupova, G; Yusupov, M (Dec 2011). "The structure of the eukaryotic ribosome at 3.0 Å resolution". Science. 334 (6062): 1524–1529. Bibcode:2011Sci...334.1524B. doi:10.1126/science.1212642. PMID 22096102. S2CID 9099683.
  4. Wimberly, BT; Brodersen, DE; Clemons, WM Jr; Morgan-Warren, RJ; Carter, AP; Vonrhein, C; Hartsch, T; Ramakrishnan, V (Sep 2000). "Structure of the 30S ribosomal subunit". Nature. 407 (6802): 327–339. Bibcode:2000Natur.407..327W. doi:10.1038/35030006. PMID 11014182. S2CID 4419944.
  5. Schmeing, TM; Ramakrishnan, V (Oct 2009). "What recent ribosome structures have revealed about the mechanism of translation". Nature. 461 (7268): 1234–1242. Bibcode:2009Natur.461.1234S. doi:10.1038/nature08403. PMID 19838167. S2CID 4398636.
  6. Aitken, Colin E.; Lorsch, Jon R. (2012). "A mechanistic overview of translation initiation in eukaryotes". Nat. Struct. Mol. Biol. 19 (6): 568–576. doi:10.1038/nsmb.2303. PMID 22664984. S2CID 9201095.
  7. Lytle JR, Wu L, Robertson HD (August 2002). "Domains on the hepatitis C virus internal ribosome entry site for 40s subunit binding". RNA. 8 (8): 1045–1055. doi:10.1017/S1355838202029965. PMC 1370315. PMID 12212848.
  8. 1 2 3 Nakao, A; Yoshihama, M; Kenmochi, N (2004). "RPG: the Ribosomal Protein Gene database". Nucleic Acids Res. 32 (Database issue): D168–70. doi:10.1093/nar/gkh004. PMC 308739. PMID 14681386.
  9. Structure of the 'T. thermophila,' proteins from the structures of the large subunit PDBS 417, 4A19 and small subunit PDB 2XZM
  10. Nomenclature according to the ribosomal protein gene database, applies to H. sapiens and T. thermophila
  11. Ban, Nenad; Beckmann, Roland; Cate, Jamie HD; Dinman, Jonathan D; Dragon, François; Ellis, Steven R; Lafontaine, Denis LJ; Lindahl, Lasse; Liljas, Anders; Lipton, Jeffrey M; McAlear, Michael A; Moore, Peter B; Noller, Harry F; Ortega, Joaquin; Panse, Vikram Govind; Ramakrishnan, V; Spahn, Christian MT; Steitz, Thomas A; Tchorzewski, Marek; Tollervey, David; Warren, Alan J; Williamson, James R; Wilson, Daniel; Yonath, Ada; Yusupov, Marat (2014). "A new system for naming ribosomal proteins". Current Opinion in Structural Biology. Elsevier BV. 24: 165–169. doi:10.1016/j.sbi.2014.01.002. hdl:11603/14279. ISSN 0959-440X. PMC 4358319. PMID 24524803.
  12. EAB means conserved in eukaryotes, archaea and bacteria, EA means conserved in eukaryotes and archaea and E means eukaryote-specific protein
  13. Traditionally, ribosomal proteins were named according to their apparent molecular weight in gel electrophoresis, leading to different names for homologous proteins from different organisms. The RPG offers a unified nomenclature for ribosomal protein genes based on homology.
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