Metal Ion Requirements for Structure and Catalysis of an RNA Ligase Ribozyme

Abstract: The class I ligase, a ribozyme previously isolated from random sequence, catalyzes a reaction similar to RNA polymerization, positioning its 5′-nucleotide via a Watson-Crick base pair, forming a 3′,5′-phosphodiester bond between its 5′-nucleotide and the substrate, and releasing pyrophosphate. Like most ribozymes, it requires metal ions for structure and catalysis. Here, we report the ionic requirements of this self-ligating ribozyme. 2+ and Co(NH 3 ) 6 3+ inhibit by binding at least two sites, but they appe… Show more

“…In principle, a metal rescue experiment could lend support to the role of some of these oxygens as inner-sphere ligands (Piccirilli et al 1993). However, the ligase is strongly inhibited by the transition metals that are the best candidates for metal rescue (Glasner et al 2002); pilot experiments confirmed that this line of inquiry was unlikely to be productive (data not shown). Instead, the improved ligase crystal structure (Shechner et al 2009) provided a framework for interpreting the interference maps.…”

“…Buffers were the same as described for selection. KCl (200 mM) was included in initial experiments, but omitted in experiments measuring the Mg 2+ -dependence of ligation, and in all reactions in which the concentration of Mg 2+ was <10 mM, because at low Mg 2+ concentration it inhibits the parent ligase (Glasner et al 2002). Omitting KCl did not affect rates of either parent or clones at $10 mM Mg 2+ .…”

“…At 60 mM Mg 2+ and pH 8.0, the cis-acting construct b1-207 reacts with k c = 300 min À1 (Glasner et al 2002), while the trans-acting construct b1-207t reaches k c = 375 min À1 for the multiple turnover reaction (Bergman et al 2000). For the latter construct, k cat /K M is 7 3 10 7 M À1 min À1 , just over an order of magnitude shy of the diffusion-controlled limit.…”

“…For the latter construct, k cat /K M is 7 3 10 7 M À1 min À1 , just over an order of magnitude shy of the diffusion-controlled limit. As fast as class I ligase catalysis is, however, the chemical step remains slower than the folding reaction at pH #7 (Glasner et al 2002). Thus, we decided to target the chemical step for improvement by using a rapid-quench flow apparatus to isolate variants that react rapidly at moderate-to-low pH.…”

A class I ligase ribozyme with reduced Mg²⁺ dependence: Selection, sequence analysis, and identification of functional tertiary interactions

“…In principle, a metal rescue experiment could lend support to the role of some of these oxygens as inner-sphere ligands (Piccirilli et al 1993). However, the ligase is strongly inhibited by the transition metals that are the best candidates for metal rescue (Glasner et al 2002); pilot experiments confirmed that this line of inquiry was unlikely to be productive (data not shown). Instead, the improved ligase crystal structure (Shechner et al 2009) provided a framework for interpreting the interference maps.…”

“…Buffers were the same as described for selection. KCl (200 mM) was included in initial experiments, but omitted in experiments measuring the Mg 2+ -dependence of ligation, and in all reactions in which the concentration of Mg 2+ was <10 mM, because at low Mg 2+ concentration it inhibits the parent ligase (Glasner et al 2002). Omitting KCl did not affect rates of either parent or clones at $10 mM Mg 2+ .…”

“…At 60 mM Mg 2+ and pH 8.0, the cis-acting construct b1-207 reacts with k c = 300 min À1 (Glasner et al 2002), while the trans-acting construct b1-207t reaches k c = 375 min À1 for the multiple turnover reaction (Bergman et al 2000). For the latter construct, k cat /K M is 7 3 10 7 M À1 min À1 , just over an order of magnitude shy of the diffusion-controlled limit.…”

“…For the latter construct, k cat /K M is 7 3 10 7 M À1 min À1 , just over an order of magnitude shy of the diffusion-controlled limit. As fast as class I ligase catalysis is, however, the chemical step remains slower than the folding reaction at pH #7 (Glasner et al 2002). Thus, we decided to target the chemical step for improvement by using a rapid-quench flow apparatus to isolate variants that react rapidly at moderate-to-low pH.…”

A class I ligase ribozyme with reduced Mg²⁺ dependence: Selection, sequence analysis, and identification of functional tertiary interactions

“…Although in principle this approach is general to large ribozymes that use extensive Watson-Crick base pairs, we developed it using the extensively characterized Class I ligase motif of Bartel and colleagues Bergman et al 2000;Glasner et al 2000Glasner et al , 2002.…”

Zeptomole detection of a viral nucleic acid using a target-activated ribozyme

In Vitro Selection of Functional Oligonucleotides and the Origins of Biochemical Activity