Jeffrey S. Kieft

Elevated Histone Expression Promotes Life Span Extension

Changes to the chromatin structure accompany aging, but the molecular mechanisms underlying aging and the accompanying changes to the chromatin are unclear. Here, we report a mechanism whereby altering chromatin structure regulates life span. We show that normal aging is accompanied by a profound loss of histone proteins from the genome. Indeed, yeast lacking the histone chaperone Asf1 or acetylation of histone H3 on lysine 56 are short lived, and this appears to be at least partly due to their having decreased histone levels. Conversely, increasing the histone supply by inactivation of the histone information regulator (Hir) complex or overexpression of histones dramatically extends life span via a pathway that is distinct from previously known pathways of life span extension. This study indicates that maintenance of the fundamental chromatin structure is critical for slowing down the aging process and reveals that increasing the histone supply extends life span.

CRYSTAL STRUCTURE OF AN RNA TERTIARY DOMAIN ESSENTIAL TO HCV IRES-MEDIATED TRANSLATION INITIATION

The hepatitis C virus (HCV) internal ribosome entry site (IRES) RNA drives internal initiation of viral protein synthesis during host cell infection. In the tertiary structure of the IRES RNA, two helical junctions create recognition sites for direct binding of the 40S ribosomal subunit and eukaryotic initiation factor 3 (eIF3). The 2.8 Å resolution structure of the IIIabc four-way junction, which is critical for binding eIF3, reveals how junction nucleotides interact with an adjacent helix to position regions directly involved in eIF3 recognition. Two of the emergent helices stack to form a nearly continuous A-form duplex, while stacking of the other two helices is interrupted by the insertion of junction residues into the helix minor groove. This distorted stack probably serves as an important recognition surface for the translational machinery.

Toward a structural understanding of IRES RNA function

Protein synthesis of an RNA template can start by two different known mechanisms: cap-dependent translation initiation and cap-independent translation initiation. The latter is driven by RNA sequences called internal ribosome entry sites (IRESs) that are found in both viral RNAs and cellular mRNAs. The diverse mechanisms used by IRESs are reflected in their structural diversity, and this structural diversity challenges us to develop a cohesive model linking IRES function to structure. With more direct structural information available for the viral IRESs, data suggest an inverse correlation between the degree to which an IRES RNA can form a stable structure on its own and the number of factors that it requires to function. Lessons learned from the viral IRESs may help understand the cellular IRESs, although more structural data are needed before any strong links can be made.

Solution structure of a metal-binding site in the major groove of RNA complexed with cobalt (III) hexammine.

BACKGROUND Solvated metal ions are critical for the proper folding and function of RNA. Despite the importance of these ions, the details of specific metal ion-RNA interactions are poorly understood. The crystal structure of a group I intron ribozyme domain characterized several metal-binding sites in the RNA with osmium (III) hexammine bound in the major groove. A corresponding method for locating and characterizing metal-binding sites of RNA in solution is of obvious interest. NMR should be ideal for localizing metal hexammine ions bound to the RNA because of the large concentration of protons around the metal center. RESULTS We have solved the solution structure of the P5b stem loop from a group I intron ribozyme bound to a cobalt (III) hexammine ion. The location of the ion is precisely determined by intermolecular nuclear Overhausser effect cross-peaks between the cobalt (III) hexammine protons and both exchangeable and non-exchangeable RNA protons in the major groove. The binding site consists of tandem G-U base pairs in a sequence of four consecutive G residues ending in a GAAA tetraloop, as originally identified in the crystal structure. The edges of the bases in the major groove present an electrostatically negative face and a variety of hydrogen-bond acceptors for the cobalt (III) hexammine ion. The metal ion ligand is bound near the guanosine nucleotides of the adjacent G-U base pairs, where it makes hydrogen bonds with the N7 and carbonyl groups of both guanines. The carbonyl groups of the uracil residues add to the negative surface of the binding pocket, but do not form hydrogen bonds with the hexammine. Additional hydrogen bonds form with other guanine residues of the GGGG sequence. The structure of the binding site does not change significantly on binding the cobalt (III) hexammine. The structure of the complex in solution is very similar to the structure in the crystal. CONCLUSIONS The structure presents a picture of how tandem G-U base pairs bind and position metal ions within the RNA major groove. The binding site is performed in the absence of metal ions, and presents a negative pocket in the major groove with a variety of hydrogen-bond acceptors. Because G-U base pairs are such a common motif in RNA sequences, it is possible that this RNA-metal ion interaction is critical in forming large complex RNA structures such as those found in the ribosome and self-splicing introns. This structure was determined using cobalt (III) hexammine as an analog for hexahydrated magnesium, a technique that may be applicable to other RNA sequences. Metal hexammines may prove to be useful general probes for locating RNA metal ion binding sites in solution.

Structural Basis for Ribosome Recruitment and Manipulation by a Viral IRES RNA

Canonical cap-dependent translation initiation requires a large number of protein factors that act in a stepwise assembly process. In contrast, internal ribosomal entry sites (IRESs) are cis-acting RNAs that in some cases completely supplant these factors by recruiting and activating the ribosome using a single structured RNA. Here we present the crystal structures of the ribosome-binding domain from a Dicistroviridae intergenic region IRES at 3.1 angstrom resolution, providing a view of the prefolded architecture of an all-RNA translation initiation apparatus. Docking of the structure into cryo–electron microscopy reconstructions of an IRES-ribosome complex suggests a model for ribosome manipulation by a dynamic IRES RNA.

Hepatitis C Virus Internal Ribosome Entry Site (IRES) Stem Loop IIId Contains a Phylogenetically Conserved GGG Triplet Essential for Translation and IRES Folding

ABSTRACT The hepatitis C virus (HCV) internal ribosome entry site (IRES) is a highly structured RNA element that directs cap-independent translation of the viral polyprotein. Morpholino antisense oligonucleotides directed towards stem loop IIId drastically reduced HCV IRES activity. Mutagenesis studies of this region showed that the GGG triplet (nucleotides 266 through 268) of the hexanucleotide apical loop of stem loop IIId is essential for IRES activity both in vitro and in vivo. Sequence comparison showed that apical loop nucleotides (UUGGGU) were absolutely conserved across HCV genotypes and the GGG triplet was strongly conserved among related Flavivirus andPestivirus nontranslated regions. Chimeric IRES elements with IIId derived from GB virus B (GBV-B) in the context of the HCV IRES possess translational activity. Mutations within the IIId stem loop that abolish IRES activity also affect the RNA structure in RNase T1-probing studies, demonstrating the importance of correct RNA folding to IRES function.

tRNA–mRNA mimicry drives translation initiation from a viral IRES

Internal ribosome entry site (IRES) RNAs initiate protein synthesis in eukaryotic cells by a noncanonical cap-independent mechanism. IRESes are critical for many pathogenic viruses, but efforts to understand their function are complicated by the diversity of IRES sequences as well as by limited high-resolution structural information. The intergenic region (IGR) IRESes of the Dicistroviridae viruses are powerful model systems to begin to understand IRES function. Here we present the crystal structure of a Dicistroviridae IGR IRES domain that interacts with the ribosomes decoding groove. We find that this RNA domain precisely mimics the transfer RNA anticodon–messenger RNA codon interaction, and its modeled orientation on the ribosome helps explain translocation without peptide bond formation. When combined with a previous structure, this work completes the first high-resolution description of an IRES RNA and provides insight into how RNAs can manipulate complex biological machines.

The Structural Basis of Pathogenic Subgenomic Flavivirus RNA (sfRNA) Production

Resisting the Chop Dengue, West Nile, and Yellow Fever viruses are all flaviviruses that have single-stranded RNA genomes and form specific, short flaviviral RNAs (sfRNAs) during infection that cause viral pathogenicity. These sfRNAs are produced by the incomplete degradation of viral RNA by the host-cell exonuclease Xrn1. What stops the host enzyme from completely chopping up the viral RNA? Chapman et al. (p. 307) reveal a pseudoknot in the structure of the Xrn1-resistant segment of a sfRNA from Murray Valley Encephalitis Virus, which, perhaps, the host Xrn1 exonuclease cannot untangle. A pseudoknot in a flavivirus RNA resists efforts by a host nuclease to untangle it. Flaviviruses are emerging human pathogens and worldwide health threats. During infection, pathogenic subgenomic flaviviral RNAs (sfRNAs) are produced by resisting degradation by the 5′→3′ host cell exonuclease Xrn1 through an unknown RNA structure-based mechanism. Here, we present the crystal structure of a complete Xrn1-resistant flaviviral RNA, which contains interwoven pseudoknots within a compact structure that depends on highly conserved nucleotides. The RNA’s three-dimensional topology creates a ringlike conformation, with the 5′ end of the resistant structure passing through the ring from one side of the fold to the other. Disruption of this structure prevents formation of sfRNA during flaviviral infection. Thus, sfRNA formation results from an RNA fold that interacts directly with Xrn1, presenting the enzyme with a structure that confounds its helicase activity.

RNA structures that resist degradation by Xrn1 produce a pathogenic Dengue virus RNA

Dengue virus is a growing global health threat. Dengue and other flaviviruses commandeer the host cell’s RNA degradation machinery to generate the small flaviviral RNA (sfRNA), a noncoding RNA that induces cytopathicity and pathogenesis. Host cell exonuclease Xrn1 likely loads on the 5′ end of viral genomic RNA and degrades processively through ∼10 kB of RNA, halting near the 3′ end of the viral RNA. The surviving RNA is the sfRNA. We interrogated the architecture of the complete Dengue 2 sfRNA, identifying five independently-folded RNA structures, two of which quantitatively confer Xrn1 resistance. We developed an assay for real-time monitoring of Xrn1 resistance that we used with mutagenesis and RNA folding experiments to show that Xrn1-resistant RNAs adopt a specific fold organized around a three-way junction. Disrupting the junction’s fold eliminates the buildup of disease-related sfRNAs in human cells infected with a flavivirus, directly linking RNA structure to sfRNA production. DOI: http://dx.doi.org/10.7554/eLife.01892.001

Structural basis of chronic beryllium disease: linking allergic hypersensitivity and autoimmunity.

T-cell-mediated hypersensitivity to metal cations is common in humans. How the T cell antigen receptor (TCR) recognizes these cations bound to a major histocompatibility complex (MHC) protein and self-peptide is unknown. Individuals carrying the MHCII allele, HLA-DP2, are at risk for chronic beryllium disease (CBD), a debilitating inflammatory lung condition caused by the reaction of CD4 T cells to inhaled beryllium. Here, we show that the T cell ligand is created when a Be(2+) cation becomes buried in an HLA-DP2/peptide complex, where it is coordinated by both MHC and peptide acidic amino acids. Surprisingly, the TCR does not interact with the Be(2+) itself, but rather with surface changes induced by the firmly bound Be(2+) and an accompanying Na(+) cation. Thus, CBD, by creating a new antigen by indirectly modifying the structure of preexisting self MHC-peptide complex, lies on the border between allergic hypersensitivity and autoimmunity.