A release factor is a

protein Proteins are large biomolecules and macromolecules that comprise one or more long chains of amino acid residues. Proteins perform a vast array of functions within organisms, including catalysing metabolic reactions, DNA replication, res ...

that allows for the termination of

translation Translation is the communication of the meaning of a source-language text by means of an equivalent target-language text. The English language draws a terminological distinction (which does not exist in every language) between ''transla ...

by recognizing the

termination codon In molecular biology (specifically protein biosynthesis), a stop codon (or termination codon) is a codon (nucleotide triplet within messenger RNA) that signals the termination of the translation process of the current protein. Most codons in mess ...

or stop codon in an

mRNA In molecular biology, messenger ribonucleic acid (mRNA) is a single-stranded molecule of RNA that corresponds to the genetic sequence of a gene, and is read by a ribosome in the process of synthesizing a protein. mRNA is created during the ...

sequence. They are named so because they release new peptides from the ribosome.

Background

During translation of mRNA, most codons are recognized by "charged"

tRNA Transfer RNA (abbreviated tRNA and formerly referred to as sRNA, for soluble RNA) is an adaptor molecule composed of RNA, typically 76 to 90 nucleotides in length (in eukaryotes), that serves as the physical link between the mRNA and the amino ...

molecules, called

aminoacyl-tRNA Aminoacyl-tRNA (also aa-tRNA or charged tRNA) is tRNA to which its cognate amino acid is chemically bonded (charged). The aa-tRNA, along with particular elongation factors, deliver the amino acid to the ribosome for incorporation into the polypept ...

s because they are adhered to specific

amino acid Amino acids are organic compounds that contain both amino and carboxylic acid functional groups. Although hundreds of amino acids exist in nature, by far the most important are the alpha-amino acids, which comprise proteins. Only 22 alpha a ...

s corresponding to each tRNA's

anticodon Transfer RNA (abbreviated tRNA and formerly referred to as sRNA, for soluble RNA) is an adaptor molecule composed of RNA, typically 76 to 90 nucleotides in length (in eukaryotes), that serves as the physical link between the mRNA and the amino ...

. In the standard

genetic code The genetic code is the set of rules used by living cells to translate information encoded within genetic material ( DNA or RNA sequences of nucleotide triplets, or codons) into proteins. Translation is accomplished by the ribosome, which links ...

, there are three mRNA stop codons: UAG ("amber"), UAA ("ochre"), and UGA ("opal" or "umber"). Although these stop codons are triplets just like ordinary codons, they are not decoded by tRNAs. It was discovered by

Mario Capecchi Mario Ramberg Capecchi (born 6 October 1937) is an Italian-born molecular geneticist and a co-awardee of the 2007 Nobel Prize in Physiology or Medicine for discovering a method to create mice in which a specific gene is turned off, known as knock ...

in 1967 that, instead, tRNAs do not ordinarily recognize stop codons at all, and that what he named "release factor" was not a tRNA molecule but a protein. Later, it was demonstrated that different release factors recognize different stop codons.

Classification

There are two classes of release factors. Class 1 release factors recognize stop codons; they bind to the A site of the ribosome in a way mimicking that of

, releasing the new polypeptide as it disassembles the ribosome. Class 2 release factors are

GTPase GTPases are a large family of hydrolase enzymes that bind to the nucleotide guanosine triphosphate (GTP) and hydrolyze it to guanosine diphosphate (GDP). The GTP binding and hydrolysis takes place in the highly conserved P-loop "G domain", a pro ...

s that enhance the activity of class 1 release factors. It helps the class 1 RF dissociate from the ribosome. Bacterial release factors include RF1, RF2, and RF3 (or PrfA, PrfB, PrfC in the "peptide release factor" gene nomenclature). RF1 and RF2 are class 1 RFs: RF1 recognizes UAA and UAG while RF2 recognizes UAA and UGA. RF3 is the class 2 release factor. Eukaryotic and archaeal release factors are named analogously, with the naming changed to "eRF" for "eukaryotic release factor" and vice versa. a/eRF1 can recognize all three stop codons, while eRF3 (archaea use aEF-1α instead) works just like RF3. The bacterial and archaeo-eukaryotic release factors are believed to have evolved separately. The two groups class 1 factors do not show sequence or structural homology with each other. The homology in class 2 is restricted to the fact that both are

s. It is believed that (b)RF3 evolved from

EF-G EF-G (elongation factor G, historically known as translocase) is a prokaryotic elongation factor involved in protein translation. As a GTPase, EF-G catalyzes the movement (translocation) of transfer RNA (tRNA) and messenger RNA (mRNA) through t ...

while eRF3 evolved from eEF1α. In line with their symbiotic origin, eukaryotic mitochondria and plastids use bacterial-type class I release factors. , no definite reports of an organellar class II release factor can be found.

Human genes

* RF1 (mitochondrial): MTRF1, MTRF1L, MRPL58 (ICT1), MTRFR (C12orf65) * eRF1: ETF1 * eRF3:

GSPT1 Eukaryotic peptide chain release factor GTP-binding subunit ERF3A is an enzyme that in humans is encoded by the ''GSPT1'' gene. Interactions GSPT1 has been shown to interact with BIRC2 Baculoviral IAP repeat-containing protein 2 (also known a ...

GSPT2 Eukaryotic peptide chain release factor GTP-binding subunit ERF3B is an enzyme that in humans is encoded by the ''GSPT2'' gene. GSPT2 is closely related to GSPT1 (MIM 139259), a GTP-binding protein that plays an essential role at the G1- to S-pha ...

Structure and function

Crystal structures have been solved for bacterial 70S ribosome bound to each of the three release factors, revealing details in codon recognition by RF1/2 and the EF-G-like rotation of RF3.

Cryo-EM Cryogenic electron microscopy (cryo-EM) is a cryomicroscopy technique applied on samples cooled to cryogenic temperatures. For biological specimens, the structure is preserved by embedding in an environment of vitreous ice. An aqueous sample so ...

structures have been obtained for eukaryotic mamallian 80S ribosome bound to eRF1 and/or eRF3, providing a view of structural rearrangements caused by the factors. Fitting the EM images to previously known crystal structures of individual parts provides identification and a more detailed view of the process. In both systems, the class II (e)RF3 binds to the universal GTPase site on the ribosome, while the class I RFs occupy the A site.

Bacterial

The bacterial class 1 release factors can be divided into four domains. The catalytically-import domains are: * The "tripeptide anticodon" motif in domain 2, in RF1 and in RF2. Only one residue actually participates in stop codon recognition via hydrogen bonding. * The GGQ motif in domain 3, critical for peptidyl-tRNA hydrolase (PTH) activity. As RF1/2 sits in the A site of the ribosome, domains 2, 3, and 4 occupy the space that tRNAs load into during elongation. Stop codon recognition activates the RF, promoting a compact to open conformation change, sending the GGQ motif to the peptidyl transferase center (PTC) next to the 3′ end of the P-site tRNA. By hydrolysis of the peptidyl-tRNA ester bond, which displayed pH-dependence ''in vitro'', the peptide is cut loose and released. RF3 is still needed to release RF1/2 from this translation termination complex. After releasing the peptide, ribosomal recycling is still required to empty the P-site tRNA and mRNA out to make the ribosome usable again. This is done by splitting the ribosome with factors like IF1– IF3 or RRF–

Eukaryotic and archaeal

eRF1 can be broken down into four domains: N-terminal (N), Middle (M), C-terminal (C), plus a minidomain: * The N domain is responsible for stop codon recognition. Motifs include and . * A GGQ motif in the M domain is critical for peptidyl-tRNA hydrolase (PTH) activity. Unlike in the bacterial version, eRF1–eRF3–GTP binds together into a sub-complex, via a motif on RF3. Stop codon recognition makes eRF3 hydrolyze the GTP, and the resulting movement puts the GGQ into the PTC to allow for hydrolysis. The movement also causes a +2-nt movement of the toeprint of the pre-termination complex. The archaeal aRF1–EF1α–GTP complex is similar. The triggering mechanism is similar to that of aa-tRNA–

EF-Tu EF-Tu (elongation factor thermo unstable) is a prokaryotic elongation factor responsible for catalyzing the binding of an aminoacyl-tRNA (aa-tRNA) to the ribosome. It is a G-protein, and facilitates the selection and binding of an aa-tRNA to t ...

–GTP. A homologous system is Dom34/

Pelota Pelota (Spanish for ''ball'') can refer to the popular and shortened names for a number of ball games: * Basque pelota * Chaza * Jai alai * Mesoamerican ballgame * Palla * Pelota mixteca * Valencian pilota * Frontenis * Pétanque Pétanqu ...

– Hbs1, a eukaryotic system that breaks up stalled ribosomes. It does not have GGQ. The recycling and breakup is mediated by ABCE1.

References

External links

* {{GeneticTranslation Proteins Protein biosynthesis