Daniele Fabris

The RNA modification database, RNAMDB: 2011 update

Since its inception in 1994, The RNA Modification Database (RNAMDB, http://rna-mdb.cas.albany.edu/RNAmods/) has served as a focal point for information pertaining to naturally occurring RNA modifications. In its current state, the database employs an easy-to-use, searchable interface for obtaining detailed data on the 109 currently known RNA modifications. Each entry provides the chemical structure, common name and symbol, elemental composition and mass, CA registry numbers and index name, phylogenetic source, type of RNA species in which it is found, and references to the first reported structure determination and synthesis. Though newly transferred in its entirety to The RNA Institute, the RNAMDB continues to grow with two notable additions, agmatidine and 8-methyladenosine, appended in the last year. The RNA Modification Database is staying up-to-date with significant improvements being prepared for inclusion within the next year and the following year. The expanded future role of The RNA Modification Database will be to serve as a primary information portal for researchers across the entire spectrum of RNA-related research.

Complex interactions of HIV-1 nucleocapsid protein with oligonucleotides

The HIV-1 nucleocapsid (NC) protein is a small, basic protein containing two retroviral zinc fingers. It is a highly active nucleic acid chaperone; because of this activity, it plays a crucial role in virus replication as a cofactor during reverse transcription, and is probably important in other steps of the replication cycle as well. We previously reported that NC binds with high-affinity to the repeating sequence d(TG)n. We have now analyzed the interaction between NC and d(TG)4 in considerable detail, using surface plasmon resonance (SPR), tryptophan fluorescence quenching (TFQ), fluorescence anisotropy (FA), isothermal titration calorimetry (ITC) and electrospray ionization Fourier transform mass spectrometry (ESI-FTMS). Our results show that the interactions between these two molecules are surprisngly complex: while the Kd for binding of a single d(TG)4 molecule to NC is only ∼5 nM in 150 mM NaCl, a single NC molecule is capable of interacting with more than one d(TG)4 molecule, and conversely, more than one NC molecule can bind to a single d(TG)4 molecule. The strengths of these additional binding reactions are quantitated. The implications of this multivalency for the functions of NC in virus replication are discussed.

Prospective Type 1 and Type 2 Disulfides of Keap1 Protein

Experiments were carried out to detect cysteine residues on human Keap1 protein that may be sensors of oxidative stress that gives rise to changes in the GSH/GSSG redox couple. Human Keap1 protein, at a final concentration of 6 microM, was incubated for two hours in aqueous buffer containing 0.010 M GSH, pH 8, in an argon atmosphere. Subsequently, excess iodoacetamide and trypsin were added to generate a peptide map effected by LCMS analysis. Peptides containing all 27 carboxamidomethylated cysteines were identified. Replacement of GSH by 0.010 M GSSG yielded a map in which 13 of the original carboxamidomethylated peptides were unperturbed, while other caboxamidomethylated cysteine-containing peptides were undetected, and a number of new cysteine-containing peptide peaks were observed. By mass analysis, and in some cases, by isolation, reduction, carboxamidomethylation, and reanalysis, these were identified as S-glutathionylated (Type 1) or Cys-Cys (Type 2) disulfides. Such peptides derived from the N-terminal, dimerization, central linker, Kelch repeat and C-terminal domains of Keap1. Experiments were carried out in which Keap1 was incubated similarly but in the presence of various GSH/GSSG ratios between 100 and 1 ([GSH + GSSG] = 0.010 M), with subsequent caraboxamidomethylation and trypsinolysis to determine differences in sensitivities of the different cysteines to the type 1 and type 2 modifications. Cysteines most sensitive to S-glutathionylation include Cys77, Cys297, Cys319, Cys368, and Cys434, while cysteine disulfides most readily formed are Cys23-Cys38 and Cys257-Cys297. The most reducing conditions at which these modifications are at GSH/GSSG = 10, which computes to an oxidation potential of E h = -268.5 mV, a physiologically relevant value. Under somewhat more oxidizing, but still physiologically relevant, conditions, GSH/GSSG = 1 ( E h = -231.1 mV), a Cys319-Cys319 disulfide is detected far from the dimerization domain of the Keap1 homodimer. The potential impact on protein structure of the glutathionylation of Cys434 and Cys368, the two modified residues in the Kelch repeat domain, was analyzed by docking and energy minimizations of glutathione residues attached to the Kelch repeat domain, whose coordinates are known. The energy minimizations indicated marked alterations in structure with a substantial constriction of Neh2 binding domain of the Keap1 Kelch repeat domain. This alteration appears to be enforced by an extended hydrogen-bonding network between residues on the glutathione moiety attached to Cys434 and amino acid side chains that have been shown to be essential for repression of Nrf2 by Keap1. The modifications of Keap1 detected in the present study are discussed in the context of previous work of others who have examined the sensitivity of cysteines on Keap1 to electrophile assault.

Targeting Loop Adenines in G-Quadruplex by a Selective Oxirane

Caught in the oxirane: Naphthalene diimides conjugated to a quinone methide and an oxirane have been synthesized and investigated as selective DNA G-quadruplex alkylating agents. The oxirane derivative generates a stable adduct with a G-quadruplex and shows selective alkylation of the loop adenines, as illustrated.

Resistance to RevM10 inhibition reflects a conformational switch in the HIV-1 Rev response element

Nuclear export of certain HIV-1 mRNAs requires an interaction between the viral Rev protein and the Rev response element (RRE), a structured element located in the Env region of its RNA genome. This interaction is an attractive target for both drug design and gene therapy, exemplified by RevM10, a transdominant negative protein that, when introduced into host cells, disrupts viral mRNA export. However, two silent G->A mutations in the RRE (RRE61) confer RevM10 resistance, which prompted us to examine RRE structure using a novel chemical probing strategy. Variations in region III/IV/V of mutant RNAs suggest a stepwise rearrangement to RevM10 resistance. Mass spectrometry was used to directly assess Rev “loading” onto RRE and its variants, indicating that this is unaffected by RNA structural changes. Similarity in chemical footprints with mutant protein implicates additional host factors in RevM10 resistance.

MS3D structural elucidation of the HIV-1 packaging signal

The structure of HIV-1 Ψ-RNA has been elucidated by a concerted approach combining structural probes with mass spectrometric detection (MS3D), which is not affected by the size and crystallization properties of target biomolecules. Distance constraints from bifunctional cross-linkers provided the information required for assembling an all-atom model from the high-resolution coordinates of separate domains by triangulating their reciprocal placement in 3D space. The resulting structure revealed a compact cloverleaf morphology stabilized by a long-range tertiary interaction between the GNRA tetraloop of stemloop 4 (SL4) and the upper stem of stemloop 1 (SL1). The preservation of discrete stemloop structures ruled out the possibility that major rearrangements might produce a putative supersite with enhanced affinity for the nucleocapsid (NC) domain of the viral Gag polyprotein, which would drive genome recognition and packaging. The steric situation of single-stranded regions exposed on the cloverleaf structure offered a valid explanation for the stoichiometry exhibited by full-length Ψ-RNA in the presence of NC. The participation of SL4 in a putative GNRA loop-receptor interaction provided further indications of the plasticity of this region of genomic RNA, which can also anneal with upstream sequences to stabilize alternative conformations of the 5′ untranslated region (5′-UTR). Considering the ability to sustain specific NC binding, the multifaceted activities supported by the SL4 sequence suggest a mechanism by which Gag could actively participate in regulating the vital functions mediated by 5′-UTR. Substantiated by the 3D structure of Ψ-RNA, the central role played by SL4 in specific RNA-RNA and protein-RNA interactions advances this domain as a primary target for possible therapeutic intervention.

Conversions of Formaldehyde-modified 2′-Deoxyadenosine 5′-Monophosphate in Conditions Modeling Formalin-fixed Tissue Dehydration

Formalin-fixed, paraffin-embedded specimens typically provide molecular biologists with low yields of extractable nucleic acids that exhibit extensive strand cleavage and covalent modification of nucleic acid bases. This study supports the idea that these deleterious effects are promoted by the first step in formalin-fixed tissue processing—i.e., tissue dehydration with a graded series of alcohols. We analyzed the conversions of formaldehyde-modified 2′-deoxyadenosine 5′-monophosphate (dAMP) by reverse-phase ion-pair, high-performance liquid chromatography and found that dehydration does not stabilize N-methylol groups in the modified nucleotide. Furthermore, spontaneous demodification in a dry state or in anhydrous ethanol can be as fast as it is in aqueous solutions if the preparation is contaminated with salts of orthophosphoric acid. In ethanol, orthophosphates also catalyze formation of abundant N6-ethoxymethyl-dAMP, as well as cross-linking and depurination of nucleotides present in the mixture. Identification of the products was performed using ultraviolet absorbance spectroscopy and electrospray ionization Fourier-transform ion cyclotron resonance mass spectrometry. Alternatives to the traditional processing of formalin-fixed tissues are discussed.

Elucidating the higher-order structure of biopolymers by structural probing and mass spectrometry: MS3D

Chemical probing represents a very versatile alternative for studying the structure and dynamics of substrates that are intractable by established high-resolution techniques. The implementation of MS-based strategies for the characterization of probing products has not only extended the range of applicability to virtually all types of biopolymers but has also paved the way for the introduction of new reagents that would not have been viable with traditional analytical platforms. As the availability of probing data is steadily increasing on the wings of the development of dedicated interpretation aids, powerful computational approaches have been explored to enable the effective utilization of such information to generate valid molecular models. This combination of factors has contributed to making the possibility of obtaining actual 3D structures by MS-based technologies (MS3D) a reality. Although approaches for achieving structure determination of unknown targets or assessing the dynamics of known structures may share similar reagents and development trajectories, they clearly involve distinctive experimental strategies, analytical concerns and interpretation paradigms. This Perspective offers a commentary on methods aimed at obtaining distance constraints for the modeling of full-fledged structures while highlighting common elements, salient distinctions and complementary capabilities exhibited by methods used in dynamics studies. We discuss critical factors to be addressed for completing effective structural determinations and expose possible pitfalls of chemical methods. We survey programs developed for facilitating the interpretation of experimental data and discuss possible computational strategies for translating sparse spatial constraints into all-atom models. Examples are provided to illustrate how the concerted application of very diverse probing techniques can lead to the solution of actual biological systems.

High-energy collision-induced dissociation of multiply charged polypeptides produced by electrospray

The recent commercial implementation of an electrospray source on a four-sector mass spectrometer has allowed the study of high-energy collisional activation of multiply charged cations. With this configuration, higher mass-to-charge ratios can be accommodated in both precursor ion selection and fragment ion detection. Good mass accuracy facilitates analysis of fragment ions and allows more reliable mechanistic correlation of these fragments. A convenient scheme was devised to permit the use of kilovolt potentials in both MS-I and MS-II, with precursors of varying charge states. Algorithms were devised to assign masses of different types of multiply charged fragment ions. Nine polypeptides were studied in the mass range 2000–5000 Da. Through this entire mass range, fragment ions were observed to be amply formed by cleavages in both the backbone and side chains, analogous to high-energy collisional activation of singly charged ions. This stands in sharp contrast to the patterns reported with low-energy, multiple collisions. Abundances of sequence ion series are influenced by the positions of basic residues. Analysis of charge distributions in fragment ions also indicates that the charges tend to be spread out across the peptides.

Cation-directed self-assembly of lipophilic nucleosides: the cation's central role in the structure and dynamics of a hydrogen-bonded assembly

Abstract This paper focuses on the cations central role in controlling the self-assembly of a lipophilic nucleoside, isoguanosine (isoG) 2 , in organic solvents. First, we use 1H NMR spectroscopy to show that a Ba2+ cation directs a mixture of the isomers isoG 2 and guanosine (G) 1 to self-sort into separate assemblies, without any detectable G–isoG cross-association. Next, we use electrospray ionization mass spectrometry to show that the cation controls the reversible self-assembly of isoG 2 . Final section focuses on the dynamic exchange of components between two different assemblies, namely, a (isoG 2 )5–Li+ pentamer and a (isoG 2 )10–Li+ decamer. Our 1H and 7Li NMR data is consistent with a cation-filled pentamer, (isoG 2 )5–Li+, moving as a unit during a bimolecular pentamer–decamer exchange. These data highlight crucial aspects regarding the cation-templated self-assembly of lipophilic nucleosides: (1) the structural information encoded within each nucleoside dictates the size and shape of the hydrogen-bonded assembly; (2) a cation is required to template and stabilize these discrete hydrogen-bonded assemblies, and (3) dynamic exchange of cation-filled, hydrogen-bonded units is likely to be a hallmark of these multi-layered nucleoside assemblies.