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Ribosome recycling factor
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    Ribosome recycling factor

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    Ribosome recycling factor
    Identifiers
    Symbol RRF
    Pfam PF01765
    InterPro IPR002661
    CATH 1ek8
    SCOP2 1ek8 / SCOPe / SUPFAM
    CDD cd00520
    Available protein structures:
    Pfam   structures / ECOD  
    PDB RCSB PDB; PDBe; PDBj
    PDBsum structure summary
    MRRF
    Identifiers
    Aliases MRRF, MRFF, MTRRF, RRF, mitochondrial ribosome recycling factor
    External IDs OMIM: 604602 MGI: 1915121 HomoloGene: 12203 GeneCards: MRRF
    Orthologs
    Species Human Mouse
    Entrez
    Ensembl
    UniProt
    RefSeq (mRNA)

    NM_026422

    RefSeq (protein)

    NP_080698

    Location (UCSC) Chr 9: 122.26 – 122.33 Mb Chr 2: 36.03 – 36.08 Mb
    PubMed search
    Wikidata
    View/Edit Human View/Edit Mouse

    Ribosome recycling factor or ribosome release factor (RRF) is a protein found in bacterial cells as well as eukaryotic organelles, specifically mitochondria and chloroplasts. It functions to recycle ribosomes after completion of protein synthesis (bacterial translation). In humans, the mitochrondrial version is coded by the MRRF gene.

    Discovery

    The ribosome recycling factor was discovered in the early 1970s by the work of Akira Kaji and Akikazu Hiroshima at the University of Pennsylvania. Their work described the requirement for two protein factors to release ribosomes from mRNA. These two factors were identified as RRF, an unknown protein until then, and Elongation Factor G (EF-G), a protein already identified and known to function in protein synthesis. RRF was originally called Ribosome Releasing Factor but is now called Ribosome Recycling Factor.

    Function

    RRF accomplishes the recycling of ribosomes by splitting ribosomes into subunits, thereby releasing the bound mRNA. This also requires the participation of EF-G (GFM2 in humans). Depending on the tRNA, IF1IF3 may also perform recycling.

    Loss of RRF function

    Structure and binding to ribosomes

    The crystal structure of RRF was first determined by X-ray diffraction in 1999. The most striking revelation was that RRF is a near-perfect structural mimic of tRNA, in both size and dimensions. One view of RRF can be seen here.

    Despite the tRNA-mimicry, RRF binds to ribosomes quite differently from the way tRNA does. It has been suggested that ribosomes bind proteins (or protein domain) of similar shape and size to tRNA, and this, rather than function, explains the observed structural mimicry.

    See also

    External links


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