Probing RegA/RNA interactions using electrospray ionization-fourier transform ion cyclotron resonance-mass spectrometry

Post-transcriptional control by bacteriophage T4: mRNA decay and inhibition of translation initiation

Over 50 years of biological research with bacteriophage T4 includes notable discoveries in post-transcriptional control, including the genetic code, mRNA, and tRNA; the very foundations of molecular biology. In this review we compile the past 10 - 15 year literature on RNA-protein interactions with T4 and some of its related phages, with particular focus on advances in mRNA decay and processing, and on translational repression. Binding of T4 proteins RegB, RegA, gp32 and gp43 to their cognate target RNAs has been characterized. For several of these, further study is needed for an atomic-level perspective, where resolved structures of RNA-protein complexes are awaiting investigation. Other features of post-transcriptional control are also summarized. These include: RNA structure at translation initiation regions that either inhibit or promote translation initiation; programmed translational bypassing, where T4 orchestrates ribosome bypass of a 50 nucleotide mRNA sequence; phage exclusion systems that involve T4-mediated activation of a latent endoribonuclease (PrrC) and cofactor-assisted activation of EF-Tu proteolysis (Gol-Lit); and potentially important findings on ADP-ribosylation (by Alt and Mod enzymes) of ribosome-associated proteins that might broadly impact protein synthesis in the infected cell. Many of these problems can continue to be addressed with T4, whereas the growing database of T4-related phage genome sequences provides new resources and potentially new phage-host systems to extend the work into a broader biological, evolutionary context.

A role for the MS analysis of nucleic acids in the post-genomics age

The advances of mass spectrometry in the analysis of nucleic acids have tracked very closely the exciting developments of instrumentation and ancillary technologies, which have taken place over the years. However, their diffusion in the broader life sciences community has been and will be linked to the ever evolving focus of biomedical research and its changing demands. Before the completion of the Human Genome Project, great emphasis was placed on sequencing technologies that could help accomplish this project of exceptional scale. After the publication of the human genome, the emphasis switched toward techniques dedicated to the exploration of sequences not coding for actual protein products, which amount to the vast majority of transcribed elements. The broad range of capabilities offered by mass spectrometry is rapidly advancing this platform to the forefront of the technologies employed for the structure-function investigation of these noncoding elements. Increasing focus on the characterization of functional assemblies and their specific interactions has prompted a re-evaluation of what has been traditionally construed as nucleic acid analysis by mass spectrometry. Inspired by the accelerating expansion of the broader field of nucleic acid research, new applications to fundamental biological studies and drug discovery will help redefine the evolving role of MS-analysis of nucleic acids in the post-genomics age.

Crystal structure of Thermus thermophilus tRNA m1A58 methyltransferase and biophysical characterization of its interaction with tRNA

Methyltransferases from the m(1)A(58) tRNA methyltransferase (TrmI) family catalyze the S-adenosyl-l-methionine-dependent N(1)-methylation of tRNA adenosine 58. The crystal structure of Thermus thermophilus TrmI, in complex with S-adenosyl-l-homocysteine, was determined at 1.7 A resolution. This structure is closely related to that of Mycobacterium tuberculosis TrmI, and their comparison enabled us to enlighten two grooves in the TrmI structure that are large enough and electrostatically compatible to accommodate one tRNA per face of TrmI tetramer. We have then conducted a biophysical study based on electrospray ionization mass spectrometry, site-directed mutagenesis, and molecular docking. First, we confirmed the tetrameric oligomerization state of TrmI, and we showed that this protein remains tetrameric upon tRNA binding, with formation of complexes involving one to two molecules of tRNA per TrmI tetramer. Second, three key residues for the methylation reaction were identified: the universally conserved D170 and two conserved aromatic residues Y78 and Y194. We then used molecular docking to position a N(9)-methyladenine in the active site of TrmI. The N(9)-methyladenine snugly fits into the catalytic cleft, where the side chain of D170 acts as a bidentate ligand binding the amino moiety of S-adenosyl-l-methionine and the exocyclic amino group of the adenosine. Y194 interacts with the N(9)-methyladenine ring, whereas Y78 can stabilize the sugar ring. From our results, we propose that the conserved residues that form the catalytic cavity (D170, Y78, and Y194) are essential for fashioning an optimized shape of the catalytic pocket.

Understanding the isomerization of the HIV-1 dimerization initiation domain by the nucleocapsid protein

The specific binding of HIV-1 nucleocapsid (NC) to the hinge region of the kissing-loop (KL) dimer formed by stemloop 1 (SL1) can have significant consequences on its ability to isomerize into the corresponding extended duplex (ED) form. The binding determinants and the effects on the isomerization process were investigated in vitro by a concerted strategy involving ad hoc RNA mutants and electrospray ionization-Fourier transform ion cyclotron resonance (ESI-FTICR) mass spectrometry, which enabled us to characterize the stoichiometry and conformational state of all possible protein-RNA and RNA-RNA assemblies present simultaneously in solution. For the first time, NC-hinge interactions were observed in constructs including at least one unpaired guanine at the 5'-end of the loop-loop duplex, whereas no interactions were detected when the unpaired guanine was placed at its 3'-end. This binding mode is supported by the presence of a grip-like motif described by recent crystal structures, which is formed by the 5'-purines of both hairpins held together by mutual stacking interactions. Using tandem mass spectrometry, hinge interactions were clearly shown to reduce the efficiency of KL/ED isomerization without inducing its complete block. This outcome is consistent with the partial stabilization of the extra-helical grip by the bound protein, which can hamper the purine components from parting ways and initiate the strand exchange process. These findings confirm that the broad binding and chaperone activities of NC induce unique effects that are clearly dependent on the structural context of the cognate nucleic acid substrate. For this reason, the presence of multiple binding sites on the different forms assumed by SL1 can produce seemingly contrasting effects that contribute to a fine modulation of the two-step process of RNA dimerization and isomerization.

Activation of large ions in FT-ICR mass spectrometry

The advent of soft ionization techniques, notably electrospray and laser desorption ionization methods, has enabled the extension of mass spectrometric methods to large molecules and molecular complexes. This both greatly extends the applications of mass spectrometry and makes the activation and dissociation of complex ions an integral part of these applications. This review emphasizes the most promising methods for activation and dissociation of complex ions and presents this discussion in the context of general knowledge of reaction kinetics and dynamics largely established for small ions. We then introduce the characteristic differences associated with the higher number of internal degrees of freedom and high density of states associated with molecular complexity. This is reflected primarily in the kinetics of unimolecular dissociation of complex ions, particularly their slow decay and the higher energy content required to induce decomposition--the kinetic shift (KS). The longer trapping time of Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS) significantly reduces the KS, which presents several advantages over other methods for the investigation of dissociation of complex molecules. After discussing general principles of reaction dynamics related to collisional activation of ions, we describe conventional ways to achieve single- and multiple-collision activation in FT-ICR MS. Sustained off-resonance irradiation (SORI)--the simplest and most robust means of introducing the multiple collision activation process--is discussed in greatest detail. Details of implementation of this technique, required control of experimental parameters, limitations, and examples of very successful application of SORI-CID are described. The advantages of high mass resolving power and the ability to carry out several stages of mass selection and activation intrinsic to FT-ICR MS are demonstrated in several examples. Photodissociation of ions from small molecules can be effected using IR or UV/vis lasers and generally requires tuning lasers to specific wavelengths and/or utilizing high flux, multiphoton excitation to match energy levels in the ion. Photodissociation of complex ions is much easier to accomplish from the basic physics perspective. The quasi-continuum of vibrational states at room temperature makes it very easy to pump relatively large amounts of energy into complex ions and infrared multiphoton dissociation (IRMPD) is a powerful technique for characterizing large ions, particularly biologically relevant molecules. Since both SORI-CID and IRMPD are slow activation methods they have many common characteristics. They are also distinctly different because SORI-CID is intrinsically selective (only ions that have a cyclotron frequency close to the frequency of the excitation field are excited), whereas IRMPD is not (all ions that reside on the optical path of the laser are excited). There are advantages and disadvantages to each technique and in many applications they complement each other. In contrast with these slow activation methods, the less widely appreciated activation method of surface induced dissociation (SID) appears to offer unique advantages because excitation in SID occurs on a sub-picosecond time scale, instantaneously relative to the observation time of any mass spectrometer. Internal energy deposition is quite efficient and readily adjusted by altering the kinetic energy of the impacting ion. The shattering transition--instantaneous decomposition of the ion on the surface--observed at high collision energies enables access to dissociation channels that are not accessible using SORI-CID or IRMPD. Finally, we discuss some approaches for tailoring the surface to achieve particular aims in SID.

Analysis of nucleic acids by FTICR MS

Fourier transform ion cyclotron resonance (FTICR) mass spectrometry represents a unique platform with which to study nucleic acids and non-covalent complexes containing nucleic acids moieties. In particular, systems in which very high mass measurement accuracy is required, very complex mixtures are to be analyzed, or very limited amounts of sample are available may be uniquely suited to interrogation by FTICR mass spectrometry. Although the FTICR platform is now broadly deployed as an integral component of many high-end proteomics-based research efforts, momentum is still building for the application of the platform towards nucleic acid-based analyses. In this work, we review fundamental aspects of nucleic acid analysis by FTICR, focusing primarily on the analysis of DNA oligonucleotides but also describing applications related to the characterization of RNA constructs. The goal of this review article is to give the reader a sense of the breadth and scope of the status quo of FTICR analysis of nucleic acids and to summarize a few recently published reports in which researchers have exploited the performance attributes of FTICR to characterize nucleic acids in support of basic and applied research disciplines including genotyping, drug discovery, and forensic analyses.

Contributions of mass spectrometry in the study of nucleic acid-binding proteins and of nucleic acid-protein interactions

Nucleic-acid-protein (NA-P) interactions play essential roles in a variety of biological processes-gene expression regulation, DNA repair, chromatin structure regulation, transcription regulation, RNA processing, and translation-to cite only a few. Such biological processes involve a broad spectrum of NA-P interactions as well as protein-protein (P-P) interactions. These interactions are dynamic, in terms of the chemical composition of the complexes involved and in terms of their mere existence, which may be restricted to a given cell-cycle phase. In this review, the contributions of mass spectrometry (MS) to the deciphering of these intricate networked interactions are described along with the numerous applications in which it has proven useful. Such applications include, for example, the identification of the partners involved in NA-P or P-P complexes, the identification of post-translational modifications that (may) regulate such complexes' activities, or even the precise molecular mapping of the interaction sites in the NA-P complex. From a biological standpoint, we felt that it was worth the reader's time to be as informative as possible about the functional significance of the analytical methods reviewed herein. From a technical standpoint, because mass spectrometry without proper sample preparation would serve no purpose, each application described in this review is detailed by duly emphasizing the sample preparation-whenever this step is considered innovative-that led to significant analytical achievements.

Binding stoichiometry of an RNA aptamer and its transcription factor target

RNA molecules serve informational, structural, and catalytic roles in cells. RNA also offers an interesting raw material for the design or genetic selection of modifiers of gene expression. We have been interested in the possibility that natural and/or artificial RNA ligands might be identified for DNA-binding proteins. With these concepts in mind, our laboratory previously isolated a 31-nucleotide RNA aptamer that specifically binds to human transcription factor NF-kappaB. This RNA aptamer (alpha-p50) competitively inhibits DNA binding by NF-kappaB in vitro. The aptamer may target the DNA-binding groove formed by the junction of the two monomers of NF-kappaB, perhaps mimicking kappaB duplex DNA. This model predicts a binding stoichiometry of one RNA aptamer per NF-kappaB dimer. To test this hypothesis, two complementary biophysical methods were utilized. Both analytical ultracentrifugation and microelectrospray mass spectrometry suggest that 1 mol of alpha-p50 RNA binds per mole of NF-kappaB p50 homodimer. Such a result is consistent with the observed ability of the RNA aptamer to block the access of transcription factor NF-kappaB to its binding site on DNA and highlights the question of how an RNA stem-loop structurally mimics a DNA duplex. This work also demonstrates the successful application of mass spectrometry to characterize noncovalent RNA/protein interactions.

Electrospray ionization mass spectrometry of oligonucleotide complexes with drugs, metals, and proteins

I. Introduction 61 II. Binding of Small Molecules to DNA 62 A. Covalent Binding 62 B. Reversible (Noncovalent) DNA-Binding Agents 65 III. DNA-Metal Ion Complexes 67 A. Platinum Complexes 70 B. Other Metal Ions 73 IV. DNA-Protein Complexes 74 A. Introduction 74 B. ESI-MS of DNA-Protein Complexes 76 C. ESI-MS Analysis of Proteolytic Products of DNA-Protein Complexes 79 D. ESI-MS of Ternary DNA-Protein-Ligand Complexes 80 V. Conclusions 80 Abbreviations 81 References 81 --Interactions of DNA with drugs, metal ions, and proteins are important in a wide variety of biological processes. With the advent of electrospray ionization (ESI) and matrix-assisted laser desorption ionization (MALDI), mass spectrometry (MS) is now a well-established tool for the characterization of the primary structures of biopolymers. The gentle nature of the ESI process, however, means that ESI-MS is also finding application for the study of noncovalent and other fragile biomolecular complexes. We outline here the progress, to date, in the use of ESI-MS for the study of noncovalent drug-DNA and protein-DNA complexes together with strategies that can be employed to examine the binding of small molecules and metal complexes to DNA. In the case of covalent complexes with DNA, sequence information can be derived from ESI-MS used in conjunction with tandem mass spectrometry (MS/MS) and/or enzymatic digestion. MS/MS can also be used to probe the relative binding affinities of drugs that bind to DNA via noncovalent interactions. Overall, the work in this area, to date has demonstrated that ESI-MS and MS/MS will prove to be valuable complements to other structural methods, offering advantages in terms of speed, specificity, and sensitivity. (c) 2001 John Wiley & Sons, Inc.

RNA-RNA noncovalent interactions investigated by microspray ionization mass spectrometry

Electrospray ionization mass spectrometry is playing an increasing role in the study of noncovalent interactions involving biomolecules. RNA-RNA complexes are important in many areas of biology, including RNA catalysis, RNA splicing, ribosome function, and gene regulation. Here, microelectrospray mass spectrometry (microESI-MS) is used to study noncovalent base-pairing interactions between RNA oligonucleotides, an area not previously explored by this technique. Using a set of complementary RNA oligonucleotides, we demonstrate the formation of the expected double-helical RNA complexes composed of three distinct oligonucleotides. The ability to study specific RNA noncovalent interactions by microESI-MS has the potential to provide a unique method by which to analyze and assign precise molecular masses to RNA-RNA complexes.

Characterization of human alcohol dehydrogenase isoenzymes by capillary isoelectric focusing-mass spectrometry

The human liver alcohol dehydrogenase (ADH) isoenzymes are currently believed to play a major role in ethanol metabolism, accounting for most of the ethanol oxidized in the liver. They have similar molecular masses and similar isoelectric point (pI) values (the 13 possible isoenzymes having pIs in the range of 8.26-8.87), making their characterization a significant analytical challenge. Capillary isoelectric focusing (CIEF) coupled on-line with electrospray ionization - Fourier transform ion cyclotron resonance (ESI-FTICR) mass spectrometry was applied to separate and characterize mixtures of alphaalpha, beta1beta1 and beta3beta3 ADH isoenzymes. Seven different species were resolved by the separation in the pI 8.26-8.67 range. ESI-FTICR analysis of native ADHs revealed that each noncovalent ADH complex contains two monomeric protein units and four zinc atoms. The combination of CIEF separations with mass spectrometry appears well-suited for detailed characterization of ADH isozymes, and the attomole level sensitivity of FTICR should allow very small samples to be addressed.

Protein folding and interactions revealed by mass spectrometry

Mass spectrometry is capable of examining very large, dynamic proteins and this ability, coupled with its relatively high throughput and low sample requirements, is reflected by its increasing importance for the characterisation of protein structure. Recent developments in mass spectrometry, in particular the refinement of the electrospray process and its coupling with time-of-flight mass analysis, mean that it is poised to contribute not only as a complementary tool but also with a defined role in many areas of chemical biology.

Electrospray ionization-mass spectrometry study of the interaction of cisplatin-adducted oligonucleotides with human XPA minimal binding domain protein

Nucleotide excision repair (NER) is the process responsible for eliminating most ultraviolet (UV) radiation damage from DNA, as well as base alterations caused by a variety of mutagens. The xeroderma pigmentosum group A complementing protein (XPA) is believed to be involved in the early step of NER by recognizing and binding damaged DNA. Recent work has suggested that electrospray ionization-mass spectrometry (ESI-MS) can be an effective tool for the study of protein-DNA complexes. We have used ESI-Fourier transform ion cyclotron resonance (FTICR) mass spectrometry to examine the cisplatin-adducted oligonucleotide and its interaction with the human XPA minimal binding domain (XPA-MBD). High-resolution FTICR experiments of the binding products showed that both double-stranded damaged 20-mer and double-stranded undamaged 20-mer formed 1:1 noncovalent complexes with XPA-MBD. A 2:1 binding stoichiometry complex was also observed between XPA-MBD and double-stranded damaged 20-mer. Competitive binding experiments indicated only slightly preferential binding of XPA-MBD with the double-stranded damaged 20-mer compared to the undamaged 20-mer. The results demonstrate that ESI-FTICR mass spectrometry provides a fast and efficient approach for characterizing weak protein-DNA interactions such as the binding between XPA-MBD and a 20-mer oligonucleotide system.

Bioanalytic applications of mass spectrometry

Mass spectrometry has suddenly expanded out of research and assay laboratories into biology, medicine and therapeutics. Electrospray ionization and matrix-assisted laser desorption/ionization yield increased mass-range and sensitivity, leading to novel applications and sparking new analyzer designs, software, and robotics.