Natural RNA catalysts (ribozymes) perform essential reactions in biological RNA processing and protein synthesis, whereby catalysis is intrinsic to RNA structure alone or in combination with metal ion cofactors. The recently discovered glmS ribozyme is unique in that it functions as a glucosamine-6-phosphate (GlcN6P)-dependent catalyst believed to enable "riboswitch" regulation of amino-sugar biosynthesis in certain prokaryotes. However, it is unclear whether GlcN6P functions as an effector or coenzyme to promote ribozyme self-cleavage. Herein, we demonstrate that ligand is absolutely requisite for glmS ribozyme self-cleavage activity. Furthermore, catalysis both requires and is dependent upon the acid dissociation constant (pKa) of the amine functionality of GlcN6P and related compounds. The data demonstrate that ligand is integral to catalysis, consistent with a coenzyme role for GlcN6P and illustrating an expanded capacity for biological RNA catalysis.
The glmS ribozyme resides in the 5' untranslated region of glmS mRNA and functions as a catalytic riboswitch that regulates amino sugar metabolism in certain Gram-positive bacteria. The ribozyme catalyzes self-cleavage of the mRNA and ultimately inhibits gene expression in response to binding of glucosamine-6-phosphate (GlcN6P), the metabolic product of the GlmS protein. We have used nucleotide analog interference mapping (NAIM) and suppression (NAIS) to investigate backbone and nucleobase functional groups essential for ligand-dependent ribozyme function. NAIM using GlcN6P as ligand identified requisite structural features and potential sites of ligand and/or metal ion interaction, whereas NAIS using glucosamine as ligand analog revealed those sites that orchestrate recognition of ligand phosphate. These studies demonstrate that the ligand-binding site lies in close proximity to the cleavage site in an emerging model of ribozyme structure that supports a role for ligand within the catalytic core.
The bacterial glmS ribozyme is a mechanistically unique functional RNA among both riboswitches and RNA catalysts. Its self-cleavage activity is the basis of riboswitch regulation of glucosamine-6-phosphate (GlcN6P) production, and catalysis requires GlcN6P as a coenzyme. Previous work has shown that the ligand amine of GlcN6P is essential for glmS ribozyme self-cleavage as is its protonation state. Metal ions are also essential within the glmS ribozyme core for both structure and function of the ribozyme. Although metal ions do not directly promote catalysis, we show that metal ion identity and the varying physicochemical properties of metal ions impact the rate of glmS ribozyme self-cleavage. Specifically, these studies demonstrate that metal ion identity impacts the overall apparent pKa of ribozyme self-cleavage, and metal ion binding largely reflects phosphate oxygen affinity. Results suggest that metal ions serve alternative roles supporting the mechanism of catalysis.
This study confirms that each of the Robert and lateral views offer unique information and combining both views enhances the ability to assess radiographic disease severity, and should be the recommended set of X-rays for assessing TM osteoarthrosis.
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