Ribosome recycling by ribosome recycling factor (RRF) ? An important but overlooked step of protein biosynthesis

“…Model for RF3 function in translational termination+ I, complex formation RF1 binds stronger to the termination complex than RF2 (Goldstein et al+, 1970b;Grentzmann et al+, 1995), the thin double-headed arrow indicates lower binding affinity for RF2; II, terminal peptidyl-tRNA hydrolysis; III, ribosome recycling; IV, termination and ribosome recycling in absence of RF3 (Janosi et al+, 1996)+ RF3 is not essential (Grentzmann et al+, 1994;Mikuni et al+, 1994) and termination occurs in the absence of RF3 (Caskey et al+, 1971)+ EF-G has been shown to catalyze ribosome recycling in vitro, in the presence of RRF and GTP (Ogawa & Kaji, 1975;Janosi et al+, 1996) (Fig+ 7, IV)+ At present, we do not know whether EF-G, RF3, or both factors function for disassembly of the termination complex by RRF in vivo+ It is possible that EF-G can replace RF3 in this function in vivo in an RF3 Ϫ mutant or in organisms like Mycoplasma genitalium, which do not contain an RF3 gene (Fraser et al+, 1995)+ On the other hand, it is also possible that the function of RF3 is limited to the termination stop and the ribosome recycling step may as well be catalyzed by EF-G and RRF, as proposed previously (Janosi et al+, 1996)+…”

“…After translational termination by RF1 or RF2, the termination complex must be disassembled in order to recycle ribosomes, tRNA, mRNA, and release factors+ In vitro release of tRNA and mRNA from the ribosome is catalyzed by elongation factor EF-G and the ribosome recycling factor (RRF, formerly called ribosome releasing factor) in presence of GTP (Hirashima & Kaji, 1972;Ogawa & Kaji, 1975;Janosi et al+, 1996)+ RRF is essential for cell growth (Janosi et al+, 1994)+ We tested whether RF3 could replace EF-G GTPase activity to allow ribosome recycling by RRF+ In this paper, we report a GTPase activity with RF3, which is only dependent on ribosomes, much comparable to the GTPase activity of EF-G+ RF3 stimulates RF1-catalyzed termination dependent on GTP, whereas termination with RF2 is stimulated independently of the presence of GTP+ RF3 can replace EF-G in the in vitro mRNA release from the ribosome by RRF, dependent on GTP+ Excess of RF3 and RRF can result in decomposition of the translation complex, independent of previous termination by RF1 or RF2+…”

Release factor RF-3 GTPase activity acts in disassembly of the ribosome termination complex

“…Model for RF3 function in translational termination+ I, complex formation RF1 binds stronger to the termination complex than RF2 (Goldstein et al+, 1970b;Grentzmann et al+, 1995), the thin double-headed arrow indicates lower binding affinity for RF2; II, terminal peptidyl-tRNA hydrolysis; III, ribosome recycling; IV, termination and ribosome recycling in absence of RF3 (Janosi et al+, 1996)+ RF3 is not essential (Grentzmann et al+, 1994;Mikuni et al+, 1994) and termination occurs in the absence of RF3 (Caskey et al+, 1971)+ EF-G has been shown to catalyze ribosome recycling in vitro, in the presence of RRF and GTP (Ogawa & Kaji, 1975;Janosi et al+, 1996) (Fig+ 7, IV)+ At present, we do not know whether EF-G, RF3, or both factors function for disassembly of the termination complex by RRF in vivo+ It is possible that EF-G can replace RF3 in this function in vivo in an RF3 Ϫ mutant or in organisms like Mycoplasma genitalium, which do not contain an RF3 gene (Fraser et al+, 1995)+ On the other hand, it is also possible that the function of RF3 is limited to the termination stop and the ribosome recycling step may as well be catalyzed by EF-G and RRF, as proposed previously (Janosi et al+, 1996)+…”

“…After translational termination by RF1 or RF2, the termination complex must be disassembled in order to recycle ribosomes, tRNA, mRNA, and release factors+ In vitro release of tRNA and mRNA from the ribosome is catalyzed by elongation factor EF-G and the ribosome recycling factor (RRF, formerly called ribosome releasing factor) in presence of GTP (Hirashima & Kaji, 1972;Ogawa & Kaji, 1975;Janosi et al+, 1996)+ RRF is essential for cell growth (Janosi et al+, 1994)+ We tested whether RF3 could replace EF-G GTPase activity to allow ribosome recycling by RRF+ In this paper, we report a GTPase activity with RF3, which is only dependent on ribosomes, much comparable to the GTPase activity of EF-G+ RF3 stimulates RF1-catalyzed termination dependent on GTP, whereas termination with RF2 is stimulated independently of the presence of GTP+ RF3 can replace EF-G in the in vitro mRNA release from the ribosome by RRF, dependent on GTP+ Excess of RF3 and RRF can result in decomposition of the translation complex, independent of previous termination by RF1 or RF2+…”

Release factor RF-3 GTPase activity acts in disassembly of the ribosome termination complex

“…One contradiction that remains to be resolved is whether RRF is able to dissociate the mRNA or not. Pavlov et al [7] have shown no release of the mRNA by RRF in vitro, and there are claims against the early work by Kaji and colleagues (review in [2]). …”

Amber mutations in ribosome recycling factors of Escherichia coli and Thermus thermophilus: evidence for C‐terminal modulator element

“…Translation termination proceeds in two sequential steps: The release of nascent polypeptides at stop codons and the disassembly of the posttermination complex + In bacteria, the ribosome recycling factor (RRF), in concert with the elongation factor EF-G, plays a main role in the second step for the next round of protein synthesis (for a review, see Janosi et al+, 1996)+ After release of nascent polypeptides by polypeptide release factors RF1 and RF2, the ribosomal P-site and A-site remain occupied with a deacylated tRNA and RF1 or RF2 protein+ Another class of bacterial release factor, RF3, accelerates the dissociation of RF1 and RF2 from the ribosome in a GTP-dependent manner, and RF3 is also released from the ribosome upon GTP hydrolysis (Freistroffer et al+, 1997;Pavlov et al+, 1997)+ These processes leave the posttermination complex with mRNA, deacylated tRNA in the P-site, and the empty A-site, which is believed to be a substrate for RRF in concert with EF-G (Hirashima & Kaji, 1972)+ The crystal structure of RRF has recently been solved to 2+55, 2+3, and 2+6 Å resolution by three groups using RRF proteins from Thermotoga maritima (Selmer et al+, 1999), Escherichia coli (Kim et al+, 2000), and Thermus thermophilus (Toyoda et al+, 2000)+ These three molecules are composed of two domains, domain 1 and domain 2, bridged by two loops (a hinge), and superimpose almost perfectly with tRNA Phe except for the amino acid-binding 39 end+ Selmer et al+ (1999) have proposed that RRF is a near perfect tRNA mimic to explain the mechanistic disassembly of the posttermination ribosomal complex+ They speculate that RRF binds to the A-site of the ribosome and that EF-G translocates RRF from the A-to the P-site and deacylated tRNA from the P-to the E-site of the ribosome in a GTP-dependent manner, where it would dissociate rapidly+ RRF, however, is architecturally different from tRNA in that the hinge of RRF forms a flexible "gooseneck" elbow, whereas the elbow of tRNA is rigid, and this flexibility of RRF is vital for its function (Toyoda et al+, 2000)+ Moreover, the model by Selmer et al+ (1999) is not consistent with the biochemical findings of Karimi et al+ (1999), which show, first, that RRF and EF-G split the ribosome into subunits in a reaction that requires GTP hydrolysis and, second, that the initiation factor IF3 is required for the removal of deacylated tRNA from the P-site of the 30S particle+ Thus the mechanistic significance of a tRNA mimic by RRF remains to be tested+ In fact, very little is known about the structureand-function relationship of RRF, which piqued our interest in a functional mapping of the ribosome-binding site in RRF+…”

Functional mapping of ribosome-contact sites in the ribosome recycling factor: A structural view from a tRNA mimic