Ionic regulation in genetic translation systems.

Abstract: The polyelectrolyte theory can provide an interpretation of the interdependence of pH, ionic strength, and polyamines one observes in the activity of ribonuclease acting on RNA. According to this theory:(i) A nucleic acid-enzyme complex and the suspending medium may be considered as two phases in equilibrium, even though within limits, the complex is soluble in water.(ii) The enzymatic catalysis is under tight control of the electrostatic potential generated by the system. Consequently, modification in electro… Show more

“…Fig.8 shows that lowering the pH raised the K" optimum of the 30-S-coupled EF-G GTPase reaction. This suggests [24] that negative charges, probably from ribosomal RNA, are exposed in the vicinity of the catalytic center, upon interaction between the ribosomal subunits.…”

“…Moreover, Douzou and Maurel [24] have shown that they partake in ionic regulation at concentrations far below the amounts required to obtain similar effects with monovalent cations. This led to the distinction between polyamines as 'internal modulators', and monovalent cations or pH as 'external modulators', [24].…”

“…Moreover, Douzou and Maurel [24] have shown that they partake in ionic regulation at concentrations far below the amounts required to obtain similar effects with monovalent cations. This led to the distinction between polyamines as 'internal modulators', and monovalent cations or pH as 'external modulators', [24]. Fig.9 shows that also in our system, spermidine exerts a strong effect: it reduces the EF-G GTPase activity in the presence of the 50-S subunit alone (squares), and it changes the J curve obtained with both subunits from 'type I' (bell-shaped) to one closer to 'type 11' (steadily descending), probably by binding specifically to the phosphate groups of the ribosomal RNA [24].…”

“…This led to the distinction between polyamines as 'internal modulators', and monovalent cations or pH as 'external modulators', [24]. Fig.9 shows that also in our system, spermidine exerts a strong effect: it reduces the EF-G GTPase activity in the presence of the 50-S subunit alone (squares), and it changes the J curve obtained with both subunits from 'type I' (bell-shaped) to one closer to 'type 11' (steadily descending), probably by binding specifically to the phosphate groups of the ribosomal RNA [24]. An intriguing property of the assay system containing spermidine is its great stability against changes in salt concentration: thus, at 6 mM spermidine the Our results indicate that the EF-G-dependent EF-G GTPase activity dependent on both ribosomal GTPase activities expressed in the presence of both subunits was constant between 50 and 200 mM NH: , ribosomal subunits or of the 50-S subunit alone have while 30-S-uncoupled EF-G GTPase activity was the same basic mechanism; indeed, their V , K,, almost totally suppressed.…”

“…A possible approach to examine the interaction between EF-G and the ribosome was furnished by the theory of ionic regulation recently formulated by Douzou and Maurel [24] on the basis of the polyelectrolyte theory ; it envisages participation of locally concentrated electric charges in catalytic reactions. Experimentally, this effect manifests itself in an interdependence between pH and salt optima.…”

Regulation of Turnover GTPase Activity of Elongation Factor G: the 30‐S‐Coupled and 30‐S‐Uncoupled Reactions

“…Fig.8 shows that lowering the pH raised the K" optimum of the 30-S-coupled EF-G GTPase reaction. This suggests [24] that negative charges, probably from ribosomal RNA, are exposed in the vicinity of the catalytic center, upon interaction between the ribosomal subunits.…”

“…Moreover, Douzou and Maurel [24] have shown that they partake in ionic regulation at concentrations far below the amounts required to obtain similar effects with monovalent cations. This led to the distinction between polyamines as 'internal modulators', and monovalent cations or pH as 'external modulators', [24].…”

“…Moreover, Douzou and Maurel [24] have shown that they partake in ionic regulation at concentrations far below the amounts required to obtain similar effects with monovalent cations. This led to the distinction between polyamines as 'internal modulators', and monovalent cations or pH as 'external modulators', [24]. Fig.9 shows that also in our system, spermidine exerts a strong effect: it reduces the EF-G GTPase activity in the presence of the 50-S subunit alone (squares), and it changes the J curve obtained with both subunits from 'type I' (bell-shaped) to one closer to 'type 11' (steadily descending), probably by binding specifically to the phosphate groups of the ribosomal RNA [24].…”

“…This led to the distinction between polyamines as 'internal modulators', and monovalent cations or pH as 'external modulators', [24]. Fig.9 shows that also in our system, spermidine exerts a strong effect: it reduces the EF-G GTPase activity in the presence of the 50-S subunit alone (squares), and it changes the J curve obtained with both subunits from 'type I' (bell-shaped) to one closer to 'type 11' (steadily descending), probably by binding specifically to the phosphate groups of the ribosomal RNA [24]. An intriguing property of the assay system containing spermidine is its great stability against changes in salt concentration: thus, at 6 mM spermidine the Our results indicate that the EF-G-dependent EF-G GTPase activity dependent on both ribosomal GTPase activities expressed in the presence of both subunits was constant between 50 and 200 mM NH: , ribosomal subunits or of the 50-S subunit alone have while 30-S-uncoupled EF-G GTPase activity was the same basic mechanism; indeed, their V , K,, almost totally suppressed.…”

“…A possible approach to examine the interaction between EF-G and the ribosome was furnished by the theory of ionic regulation recently formulated by Douzou and Maurel [24] on the basis of the polyelectrolyte theory ; it envisages participation of locally concentrated electric charges in catalytic reactions. Experimentally, this effect manifests itself in an interdependence between pH and salt optima.…”

Regulation of Turnover GTPase Activity of Elongation Factor G: the 30‐S‐Coupled and 30‐S‐Uncoupled Reactions

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