GTPases IF2 and EF-G bind GDP and the SRL RNA in a mutually exclusive manner

Allostery is essential for controlled catalysis, signal transmission, receptor trafficking, turning genes on and off, and apoptosis. It governs the organism's response to environmental and metabolic cues, dictating transient partner interactions in the cellular network. Textbooks taught us that allostery is a change of shape at one site on the protein surface brought about by ligand binding to another. For several years, it has been broadly accepted that the change of shape is not induced; rather, it is observed simply because a larger protein population presents it. Current data indicate that while side chains can reorient and rewire, allostery may not even involve a change of (backbone) shape. Assuming that the enthalpy change does not reverse the free-energy change due to the change in entropy, entropy is mainly responsible for binding.

The L7/12 stalk of the large subunit of bacterial ribosomes encompasses protein L10 and multiple copies of L7/12. We present crystal structures of Thermotoga maritima L10 in complex with three L7/12 N-terminal-domain dimers, refine the structure of an archaeal L10E N-terminal domain on the 50S subunit, and identify these elements in cryo-electron-microscopic reconstructions of Escherichia coli ribosomes. The mobile C-terminal helix alpha8 of L10 carries three L7/12 dimers in T. maritima and two in E. coli, in concordance with the different length of helix alpha8 of L10 in these organisms. The stalk is organized into three elements (stalk base, L10 helix alpha8-L7/12 N-terminal-domain complex, and L7/12 C-terminal domains) linked by flexible connections. Highly mobile L7/12 C-terminal domains promote recruitment of translation factors to the ribosome and stimulate GTP hydrolysis by the ribosome bound factors through stabilization of their active GTPase conformation.

Using a modified method that involves minimal manipulation of cells, we report new information about nucleotide pool sizes and changes throughout the Escherichia coli growth curve. Nucleotide pool sizes are critically dependent on sample manipulation and extraction methods. Centrifugation and even short (2 min) lapses in sample preparation can dramatically affect results. The measured ATP concentration at three different growth rates is at least 3 mM, well above the 0.8 mM needed to saturate the rRNA promoter P1 in vitro. Many of the pools, including ATP, GTP, and UTP, begin to decrease while the cells are still in mid-log growth. After an almost universal drop in nucleotide concentration as the cells transition from logarithmic to stationary phase, there is a "rebound" of certain nucleotides, most notably ATP, after the cells enter stationary phase, followed by a progressive decrease. UTP, in contrast, increases as the cells transition into stationary phase. The higher UTP values might be related to elevated UDP-glucose/galactose, which was found to be at higher concentrations than expected in stationary phase. dTTP is the most abundant deoxynucleoside triphosphate (dNTP) in the cell despite the fact that its precursors, UDP and UTP, are not. All dNTPs decrease through the growth curve but do not have the abrupt drop, as seen with other nucleotides when the cells transition into stationary phase.