Reactivation in vitro of inactive ribosomes from stationary phase Escherichia coli

RsfA (YbeB) proteins are conserved ribosomal silencing factors

The YbeB (DUF143) family of uncharacterized proteins is encoded by almost all bacterial and eukaryotic genomes but not archaea. While they have been shown to be associated with ribosomes, their molecular function remains unclear. Here we show that YbeB is a ribosomal silencing factor (RsfA) in the stationary growth phase and during the transition from rich to poor media. A knock-out of the rsfA gene shows two strong phenotypes: (i) the viability of the mutant cells are sharply impaired during stationary phase (as shown by viability competition assays), and (ii) during transition from rich to poor media the mutant cells adapt slowly and show a growth block of more than 10 hours (as shown by growth competition assays). RsfA silences translation by binding to the L14 protein of the large ribosomal subunit and, as a consequence, impairs subunit joining (as shown by molecular modeling, reporter gene analysis, in vitro translation assays, and sucrose gradient analysis). This particular interaction is conserved in all species tested, including Escherichia coli, Treponema pallidum, Streptococcus pneumoniae, Synechocystis PCC 6803, as well as human mitochondria and maize chloroplasts (as demonstrated by yeast two-hybrid tests, pull-downs, and mutagenesis). RsfA is unrelated to the eukaryotic ribosomal anti-association/60S-assembly factor eIF6, which also binds to L14, and is the first such factor in bacteria and organelles. RsfA helps cells to adapt to slow-growth/stationary phase conditions by down-regulating protein synthesis, one of the most energy-consuming processes in both bacterial and eukaryotic cells.

The YbeB/DUF143 family of proteins is one of the most widely conserved proteins with homologues present in almost all bacteria and eukaryotic organelles such as mitochondria and chloroplasts (but not archaea). While it has been shown that these proteins associate with ribosomes, their molecular function remained mysterious. Here we show that a knock-out of the ybeB gene causes a dramatic adaptation block during a shift from rich to poor media and seriously deteriorates the viability during stationary phase. YbeB of six different species binds to ribosomal protein L14. This interaction blocks the association of the two ribosomal subunits and, as a consequence, translation. YbeB is thus renamed “RsfA” (ribosomal silencing factor A). RsfA inhibits translation when nutrients are depleted (or when cells are in stationary phase), which helps the cell to save energy and nutrients, a critical function for all cells that are regularly struggling with limited resources.

Modification of the Ribosome and the Translational Machinery during Reduced Growth Due to Environmental Stress

Escherichia coli strains normally used under laboratory conditions have been selected for maximum growth rates and require maximum translation efficiency. Recent studies have shed light on the structural and functional changes undergone by the translational machinery in E. coli during heat and cold shock and upon entry into stationary phase. In these situations both the composition and the partitioning of this machinery into the different pools of cellular ribosomes are modified. As a result, the translational capacity of the cell is dramatically altered. This review provides a comprehensive account of these modifications, regardless of whether or not their underlying mechanisms and their effects on cellular physiology are known. Not only is the composition of the ribosome modified upon entry into stationary phase, but the modification of other components of the translational machinery, such as elongation factor Tu (EFTu) and tRNAs, has also been observed. Hibernation-promoting factor (HPF), paralog protein Y (PY), and ribosome modulation factor (RMF) may also be related to the general protection against environmental stress observed in stationary-phase E. coli cells, a role that would not be revealed necessarily by the viability assays. Even for the best-characterized ribosome-associated factors induced under stress (RMF, PY, and initiation factors), we are far from a complete understanding of their modes of action.

Effects of growth conditions and mutations in RNA polymerase on translational activity in vitro in Escherichia coli

The translational capacity in vitro in Escherichia coli, using RNA from phage R17 or Q beta as messenger, is several times higher if the extracts are prepared from cells harvested in early exponential phase or grown under conditions of good aeration compared to if extracts are prepared from cells harvested in a later growth phase or grown under semi-aerobic conditions. In low activity extracts the production of phage replicase protein is preferentially affected. Growth of a wild type strain under semi-aerobic conditions has a less pronounced effect on translational capacity in vitro using crude mRNA from normal or T4 infected cells or with poly(U). Mutants were fortuitously found which did not show a lowered translational activity in vitro as a result of entering late phase of growth. Two of these were changed in RNA polymerase. Two different translational inhibitors can be demonstrated in the ribosomal wash fraction obtained from semi-aerobically grown wild type cells, whereas only one was found in the case of aerobically grown cells. The low translational activity of semi-aerobically grown cells in vitro is implied to be dependent on the induction or activation of a translational inhibitor. It behaves like a protein but is not likely to be a protease or RNAse.

Mechanism of protein synthesis inhibition during stationary phase in Bacillus stearothermophilus

The appearance of a protein (association factor I) in ribosomes from Bacillus stearothermophilus at stationary phase of growth is described. Association factor I is present on 30S subunits and 30S-50S ribosomal couples, but not on 50S subunits. This protein is responsible for the low levels of polyphenylalanine synthesis shown by stationary phase ribosomes. Association factor I is able to bind to free 30S-50S ribonsomal couples but not to polysomes, and exerts its effect by inhibiting the initiation step of protein synthesis. Ribonsomes preincubated with association factor I have a decreased ability for polypeptide synthesis directed page mRNA or poly(U).

Metabolic stability of the two forms of initiation factor IF-3 in Escherichia coli during the growth cycle

Possible alteration in the ratio of the long and short forms of initiation factor IF-3 (FEBS Lett. 79, 264-275, 1977) during the growth cycle of Escherichia coli was examined. The ratio was found to remain unchanged between the exponential and stationary growth phases. Contrary to an earlier report (Eur. J. Biochem. 29, 319-325, 1972), the total amount of IF-3 relative to the ribosome content in stationary phase cells was essentially the same as in midlogarithmic phase cells. The activity of IF-3, assayed after its separation from other initiation factors by chromatography, was also the same in extracts from midlogarithmic and stationary phase cells. The data show that in Escherichia coli the ratio of IF-3/ribosome is maintained constant. The ribosomes themselves have been shown to retain virtually full activity in vitro during this transition indicating that growth-cycle-dependent biochemical modifications of the ribosome do not affect its protein synthetic capacity per se.

Heterotrophic nature of the cell-free protein-synthesizing system from the strict chemolithotroph, Thiobacillus thiooxidans

A cell-free protein-synthesizing system prepared from the strict chemolithotroph, Thiobacillus thiooxidans, was similar to that of heterotrophs. The poly-U directed system had a temperature optimum of 37 C, but in the presence of spermidine (3 mM) the optimum shifted to 45 C. Although growth of the chemolithotroph occurs only in acid conditions, the pH optimum for the cell-free system was pH 7.2. The endogenous-directed activity in the presence or absence of spermidine was maximal at pH 7.8. Spermidine had a stimulatory effect; however, this effect was dependent on the magnesium and tris(hydroxymethyl)aminomethane (Tris) concentrations. At low Tris concentrations (10 mM), spermidine (3 to 5 mM) could completely replace magnesium. When the Tris concentration was increased (50 mM), spermidine could not replace magnesium. Supernatant and ribosomal fractions from T. thiooxidans were exchanged with those of Bacillus thuringiensis and Escherichia coli, and the ribosomal fraction from the chemolithotroph gave good to moderate stimulation when exchanged with the supernatant from the heterotrophs. On the other hand, the supernatant from T. thiooxidans gave good stimulation when mixed with ribosomes from B. thuringiensis but poor activity with ribosomes from E. coli. Both supernatant and ribosomal fractions prepared from stationary phase extracts of T. thiooxidans were inactive in the cell-free system.

Effect of elevated temperatures on protein synthesis in Escherichia coli

Upon a temperature shift from 30 C to 42 to 44 C, Escherichia coli experiences a transient slowdown in rate of optical density increase, uridine incorporation, and amino acid incorporation. The data show that the primary target for thermal inactivation is a molecule(s) required for the initiation of protein synthesis. The effect on ribonucleic acid synthesis is a secondary effect.

Peptidyl-puromycin synthesis on polyribosomes from Escherichia coli

Peptide bond synthesis was studied with native polyribosomes of E. coli. With the use of this system for transpeptidation, it was possible to show that a single K(+) activates the ribosome monomers of polyribosomes; that protonation of a single group (probably imidazole or an N-terminal amino group) with a pK(a) equal to about 7.2 inactivates the transpeptidase complex; that Mn(++) can substitute for Mg(++), but that Ca(++), spermidine, and putrescine do so only very poorly; and that the K(m) for puromycin in this system is about 2.4 x 10(-6) M.