Structure, mechanism, and evolution of the mRNA capping apparatus

This chapter discusses the recent progress, concerning the mechanism of cap synthesis, by fungal and mammalian enzymes. Viral capping enzymes are discussed to the extent that their study illuminates the mechanistic features, shared by their cellular counterparts. The chapter discusses the structural...

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Published in	Progress in Nucleic Acid Research and Molecular Biology Vol. 66; pp. 1 - 40
Main Author	Shuman, Stewart
Format	Book Chapter Journal Article
Language	English
Published	United States Elsevier Science & Technology 01.01.2001
Subjects	Acid Anhydride Hydrolases - genetics Acid Anhydride Hydrolases - metabolism Animals Biochemistry Biophysics Evolution, Molecular Fungal Proteins - genetics Fungal Proteins - metabolism Humans messenger RNA Methyltransferases - genetics Methyltransferases - metabolism Microbiology (non-medical) mRNA (nucleoside-2'-O)-methyltransferase Nucleotidyltransferases - genetics Protein Binding RNA Caps - genetics RNA Caps - metabolism RNA, Messenger - genetics RNA, Messenger - metabolism transferases Vaccinia virus
Online Access	Get full text
ISBN	0125400667 9780125400664
ISSN	0079-6603
DOI	10.1016/S0079-6603(00)66025-7

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Abstract	This chapter discusses the recent progress, concerning the mechanism of cap synthesis, by fungal and mammalian enzymes. Viral capping enzymes are discussed to the extent that their study illuminates the mechanistic features, shared by their cellular counterparts. The chapter discusses the structural features of the capping enzymes that are required for guanylyltransferase, triphosphatase, and methyltransferase activities. It also describes how these features are conserved in evolution. The essential structural elements illuminate the reaction mechanisms that are described briefly in this chapter. It emphasizes the importance of recent structure determinations in clarifying the mechanistic models of catalysis, opening new lines of biochemical investigation, and illuminating the surprising structural complexities for seemingly “simple” enzymatic steps. The chapter concludes with the following: (i) the cloning of genes and complementary DNA (cDNA) encoding the cap-forming enzymes from a wide variety of sources; (ii) the delineation of functional domains and catalytically essential amino acid side chains by mutagenesis; and (iii) the application of X-ray crystallography to determine the structure of the capping enzymes. The physical and functional organizations of the component activities diverged during evolution are also discussed in this chapter.
AbstractList	When capping was last reviewed here in 1995, I wrote that "the next several years will be a very exciting period for studies of RNA capping as more investigators join the fray." This prediction has been borne out, and capping is finding its way back into the spotlight as a fertile model for understanding catalysis and enzyme evolution, not to mention the extremely important question of how mRNA processing events are coordinated with mRNA transcription. I have emphasized here the importance of recent structure determinations in clarifying mechanistic models of catalysis, opening new lines of biochemical investigation, and illuminating surprising structural complexities for seemingly "simple" enzymatic steps. The entry of structural biologists such as Dale Wigley and Chris Lima into the capping business has been key to the advances described here. Limiting the scope of this chapter to the three enzymes that synthesize the m7GpppN cap unfortunately deprives me of an opportunity to review the elegant work of Alec Hodel, Paul Gershon, and Florante Quiocho on the crystal structure of vaccinia mRNA (nucleoside-2'-O)-methyltransferase in complex with bound methyl donor and capped RNA methyl acceptor (85-87). The interactions of the capping apparatus with the RNA polymerase II transcription complex, and the potential for such interactions to regulate the catalytic activity of the capping enzymes, are new and fascinating areas opened up by studies from this laboratory and the laboratories of David Bentley, Stephen Buratowski, and Aaron Shatkin. Future capping studies will inevitably converge on the field of transcription elongation. Key questions are: How long does the capping apparatus remain associated with elongating RNA polymerase? Is there a temporal window during elongation during which capping must occur? What events provoke dissociation of the capping enzymes from the transcription complex? Does dynamic remodeling of the CTD phosphorylation array during elongation influence the capping apparatus? Is there a transcriptional checkpoint that senses the 5' terminus of pre-mRNA and arrests or aborts elongation when cap synthesis has failed or is incomplete? Answering these questions will require innovative cell biology in addition to biochemistry and structural biology. This chapter discusses the recent progress, concerning the mechanism of cap synthesis, by fungal and mammalian enzymes. Viral capping enzymes are discussed to the extent that their study illuminates the mechanistic features, shared by their cellular counterparts. The chapter discusses the structural features of the capping enzymes that are required for guanylyltransferase, triphosphatase, and methyltransferase activities. It also describes how these features are conserved in evolution. The essential structural elements illuminate the reaction mechanisms that are described briefly in this chapter. It emphasizes the importance of recent structure determinations in clarifying the mechanistic models of catalysis, opening new lines of biochemical investigation, and illuminating the surprising structural complexities for seemingly “simple” enzymatic steps. The chapter concludes with the following: (i) the cloning of genes and complementary DNA (cDNA) encoding the cap-forming enzymes from a wide variety of sources; (ii) the delineation of functional domains and catalytically essential amino acid side chains by mutagenesis; and (iii) the application of X-ray crystallography to determine the structure of the capping enzymes. The physical and functional organizations of the component activities diverged during evolution are also discussed in this chapter.
Author	Shuman, Stewart
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Snippet	This chapter discusses the recent progress, concerning the mechanism of cap synthesis, by fungal and mammalian enzymes. Viral capping enzymes are discussed to... When capping was last reviewed here in 1995, I wrote that "the next several years will be a very exciting period for studies of RNA capping as more...
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SubjectTerms	Acid Anhydride Hydrolases - genetics Acid Anhydride Hydrolases - metabolism Animals Biochemistry Biophysics Evolution, Molecular Fungal Proteins - genetics Fungal Proteins - metabolism Humans messenger RNA Methyltransferases - genetics Methyltransferases - metabolism Microbiology (non-medical) mRNA (nucleoside-2'-O)-methyltransferase Nucleotidyltransferases - genetics Protein Binding RNA Caps - genetics RNA Caps - metabolism RNA, Messenger - genetics RNA, Messenger - metabolism transferases Vaccinia virus
Title	Structure, mechanism, and evolution of the mRNA capping apparatus
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