Stewart Shuman

Identification of microRNAs of the herpesvirus family

Epstein-Barr virus (EBV or HHV4), a member of the human herpesvirus (HHV) family, has recently been shown to encode microRNAs (miRNAs). In contrast to most eukaryotic miRNAs, these viral miRNAs do not have close homologs in other viral genomes or in the genome of the human host. To identify other miRNA genes in pathogenic viruses, we combined a new miRNA gene prediction method with small-RNA cloning from several virus-infected cell types. We cloned ten miRNAs in the Kaposi sarcoma–associated virus (KSHV or HHV8), nine miRNAs in the mouse gammaherpesvirus 68 (MHV68) and nine miRNAs in the human cytomegalovirus (HCMV or HHV5). These miRNA genes are expressed individually or in clusters from either polymerase (pol) II or pol III promoters, and share no substantial sequence homology with one another or with the known human miRNAs. Generally, we predicted miRNAs in several large DNA viruses, and we could neither predict nor experimentally identify miRNAs in the genomes of small RNA viruses or retroviruses.

What messenger RNA capping tells us about eukaryotic evolution

The 5′ cap is a unique feature of eukaryotic cellular and viral messenger RNA that is absent from the bacterial and archaeal domains of life. The cap is formed by three enzymatic reactions at the 5′ terminus of nascent mRNAs. Although the capping pathway is conserved in all eukaryotes, the structure and genetic organization of the component enzymes vary between species. These differences provide insights into the evolution of eukaryotes and eukaryotic viruses.

Distinct Roles for CTD Ser-2 and Ser-5 Phosphorylation in the Recruitment and Allosteric Activation of Mammalian mRNA Capping Enzyme

Capping is targeted to pre-mRNAs through binding of the guanylyltransferase component of the capping apparatus to the phosphorylated CTD of RNA polymerase II. We report that mammalian guanylyltransferase binds synthetic CTD peptides containing phosphoserine at either position 2 or 5 of the YSPTSPS heptad repeat. CTD peptides containing Ser-5-PO4 stimulate guanylyltransferase activity by enhancing enzyme affinity for GTP and increasing the yield of the enzyme-GMP intermediate. A CTD peptide containing Ser-2-PO4 has no effect on guanylyltransferase activity. This implies an allosteric change in guanylyltransferase conformation that is specified by the position of phosphoserine in the CTD. Stimulation of guanylyltransferase increases with the number of Ser-5-phosphorylated heptads. Our results underscore how mRNA production may be regulated by the display of different CTD phosphorylation arrays during transcription elongation.

Structure, mechanism, and evolution of the mRNA capping apparatus.

Publisher Summary 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.

Friction and torque govern the relaxation of DNA supercoils by eukaryotic topoisomerase IB.

Topoisomerases relieve the torsional strain in DNA that is built up during replication and transcription. They are vital for cell proliferation and are a target for poisoning by anti-cancer drugs. Type IB topoisomerase (TopIB) forms a protein clamp around the DNA duplex and creates a transient nick that permits removal of supercoils. Using real-time single-molecule observation, we show that TopIB releases supercoils by a swivel mechanism that involves friction between the rotating DNA and the enzyme cavity: that is, the DNA does not freely rotate. Unlike a nicking enzyme, TopIB does not release all the supercoils at once, but it typically does so in multiple steps. The number of supercoils removed per step follows an exponential distribution. The enzyme is found to be torque-sensitive, as the mean number of supercoils per step increases with the torque stored in the DNA. We propose a model for topoisomerization in which the torque drives the DNA rotation over a rugged periodic energy landscape in which the topoisomerase has a small but quantifiable probability to religate the DNA once per turn.

X-Ray Crystallography Reveals a Large Conformational Change during Guanyl Transfer by mRNA Capping Enzymes

We have solved the crystal structure of an mRNA capping enzyme at 2.5 A resolution. The enzyme comprises two domains with a deep, but narrow, cleft between them. The two molecules in the crystallographic asymmetric unit adopt very different conformations; both contain a bound GTP, but one protein molecule is in an open conformation while the other is in a closed conformation. Only in the closed conformation is the enzyme able to bind manganese ions and undergo catalysis within the crystals to yield the covalent guanylated enzyme intermediate. These structures provide direct evidence for a mechanism that involves a significant conformational change in the enzyme during catalysis.

RNA capping enzyme and DNA ligase: a superfamily of covalent nucleotidyl transferases.

mRNA capping entails GMP transfer from GTP to a 5′ diphosphate RNA end to form the structure G(5′)ppp(5′)N. A similar reaction involving AMP transfer to the 5′ monophosphate end of DNA or RNA occurs during strand joining by polynucleotide ligases. In both cases, nucleotidyl transfer occurs through a covalent lysyl‐NMP intermediate. Sequence conservation among capping enzymes and ATP‐dependent ligases in the vicinity of the active site lysine (KxDG) and at five other co‐linear motifs suggests a common structural basis for covalent catalysis. Mutational studies support this view. We propose that the cellular and DNA virus capping enzymes and ATP‐dependent ligases constitute a protein superfamily evolved from a common ancestral enzyme. Within this superfamily, the cellular capping enzymes display more extensive similarity to the ligases than they do to the poxvirus capping enzymes. Recent studies suggest that eukaryotic RNA viruses have evolved alternative pathways of cap metabolism catalysed by structurally unrelated enzymes that nonetheless employ a phosphoramidate intermediate. Comparative analysis of these enzymes, particularly at the structural level, should illuminate the shared reaction mechanism while clarifying the basis for nucleotide specificity and end recognition. The capping enzymes merit close attention as potential targets for antiviral therapy.

Structure of an mRNA Capping Enzyme Bound to the Phosphorylated Carboxy-Terminal Domain of RNA Polymerase II

The 2.7 A structure of Candida albicans RNA guanylyltransferase Cgt1 cocrystallized with a carboxy-terminal domain (CTD) peptide composed of four Ser5-PO4 YSPTSPS heptad repeats illuminates distinct CTD-docking sites localized to the Cgt1 N-terminal nucleotidyl transferase domain. Tyr1, Pro3, Pro6, and Ser5-PO4 side chains from each of two YSPTSPS repeats contribute to the interface. Comparison to the Pin1-CTD structure shows that the CTD can assume markedly different conformations that are templated by particular binding partners. Structural plasticity combined with remodeling of CTD primary structure by kinases and phosphatases provides a versatile mechanism by which the CTD can recruit structurally dissimilar proteins during transcription. A binding site for the RNA triphosphatase component of the capping apparatus was also uncovered within the Cgt1 OB domain.

The DExH protein NPH-II is a processive and directional motor for unwinding RNA.

All aspects of cellular RNA metabolism and processing involve DExH/D proteins, which are a family of enzymes that unwind or manipulate RNA in an ATP-dependent fashion. DExH/D proteins are also essential for the replication of many viruses, and therefore provide targets for the development of therapeutics. All DExH/D proteins characterized to date hydrolyse nucleoside triphosphates and, in most cases, this activity is stimulated by the addition of RNA or DNA. Several members of the family unwind RNA duplexes in an NTP-dependent fashion in vitro; therefore it has been proposed that DExH/D proteins couple NTP hydrolysis to RNA conformational change in complex macromolecular assemblies. Despite the central role of DExH/D proteins, their mechanism of RNA helicase activity remains unknown. Here we show that the DExH protein NPH-II unwinds RNA duplexes in a processive, unidirectional fashion with a step size of roughly one-half helix turn. We show that there is a quantitative connection between ATP utilization and helicase processivity, thereby providing direct evidence that DExH/D proteins can function as molecular motors on RNA.

Bacterial DNA repair by non-homologous end joining

The capacity to rectify DNA double-strand breaks (DSBs) is crucial for the survival of all species. DSBs can be repaired either by homologous recombination (HR) or non-homologous end joining (NHEJ). The long-standing notion that bacteria rely solely on HR for DSB repair has been overturned by evidence that mycobacteria and other genera have an NHEJ system that depends on a dedicated DNA ligase, LigD, and the DNA-end-binding protein Ku. Recent studies have illuminated the role of NHEJ in protecting the bacterial chromosome against DSBs and other clastogenic stresses. There is also emerging evidence of functional crosstalk between bacterial NHEJ proteins and components of other DNA-repair pathways. Although still a young field, bacterial NHEJ promises to teach us a great deal about the nexus of DNA repair and bacterial pathogenesis.