Progress in mass spectrometry of nucleic acid constituents: analysis of xenobiotic modifications and measurements at high mass

The multifaceted roles of mass spectrometric analysis in nucleic acids drug discovery and development

The deceptively simple concepts of mass determination and fragment analysis are the basis for the application of mass spectrometry (MS) to a boundless range of analytes, including fundamental components and polymeric forms of nucleic acids (NAs). This platform affords the intrinsic ability to observe first-hand the effects of NA-active drugs on the chemical structure, composition, and conformation of their targets, which might affect their ability to interact with cognate NAs, proteins, and other biomolecules present in a natural environment. The possibility of interfacing with high-performance separation techniques represents a multiplying factor that extends these capabilities to cover complex sample mixtures obtained from organisms that were exposed to NA-active drugs. This report provides a brief overview of these capabilities in the context of the analysis of the products of NA-drug activity and NA therapeutics. The selected examples offer proof-of-principle of the applicability of this platform to all phases of the journey undertaken by any successful NA drug from laboratory to bedside, and provide the rationale for its rapid expansion outside traditional laboratory settings in support to ever growing manufacturing operations.

The effect of organic modifiers on electrospray ionization charge-state distribution and desorption efficiency for oligonucleotides

The chemical composition of the solution has a critical impact on the electrospray desorption efficiency of oligonucleotides. Several physiochemical properties of various organic modifiers were investigated with respect to their role in the desorption process of oligonucleotides. The Henry's Law Constant, which reflects the volatility of alkylamines, was found to have a prominent effect on both the electrospray charge state distribution and desorption efficiency of oligonucleotides. Alkylamines with higher k(H,cc)(aq/gas) values such as hexylamine, piperidine, and imidazole reduced the charge state distribution by forming complexes with the oligonucleotide and dissociating from it in the gas phase, while alkylamines with extremely low k(H,cc)(aq/gas) values reduced the electrospray charge state distribution by facilitating ion emission at an earlier stage of the electrospray desorption process. Ion-pairing agents with moderate k(H,cc)(aq/gas) values do not alter the electrospray charge state distribution of oligonucleotides and their ability to enhance oligonucleotide ionization followed the order of decreasing k(H,cc)(aq/gas) values. The Henry's Law Constant also correlated to the impact of the acidic modifiers on oligonucleotide ionization efficiency. Ionization enhancement effects were observed with hexafluoroisopropanol, and this effect was attributed to its low k(H,cc)(aq/gas) and moderate acidity. The comprehensive effects of both alkylamine and hexafluoroisoproapnol on the electrospray ionization desorption of oligonucleotides were also evaluated, and acid-base equilibrium was found to play a critical role in determining these effects.

Frontiers of mass spectrometry in nucleic acids analysis

Nucleic acids research is a highly competitive field of research. A number of well established methods are available. The current output of high throughput ("next generation") sequencing technologies is impressive, and still technologies are continuing to make progress regarding read lengths, bp per second, accuracy and costs. Although in the 1990s MS was considered as an analytical platform for sequencing, it was soon realized that MS will never be competitive. Thus, the focus shifted from de novo sequencing towards other areas of application where MS has proven to be a powerful analytical tool. Potential niches for the application of MS in nucleic acids research include genotyping of genetic markers (single nucleotide polymorphisms, short tandem repeats, and combinations thereof), quality control of synthetic oligonucleotides, metabolic profiling of therapeutics, characterization of modified nucleobases in DNA and RNA molecules, and the study of non covalent interactions among nucleic acids as well as interactions of nucleic acids with drugs and proteins. The diversity of possible applications for MS highlights its significance for nucleic acid research.

Toward building a database of bifunctional probes for the MS3D investigation of nucleic acids structures

This report illustrates the approaches employed to investigate critical aspects of the activity of crosslinking reagents toward nucleic acid substrates, which should be evaluated to identify candidate probes for mass spectrometric 3D (MS3D) investigations of biomolecules and macromolecular complexes. Representative members of different classes of bifunctional reagents were taken into consideration, including bikethoxal and phenyl-diglyoxal [bis-(1,2-dicarbonyls)], cisplatin (coordinative binding agents), chlorambucil and nitrogen mustard [bis-(2-chloroethyl)amines], and sym-triazine trichloride (triazines). Nanospray-Fourier transform mass spectrometry (FTMS) was applied without desalting or separation procedures to characterize the covalent products obtained by probing dinucleotide and trinucleotide substrates under a variety of experimental conditions in vitro. The carefully controlled composition of these substrates enabled us to obtain valid comparisons of probe activity toward individual nucleotides and evaluate possible base-specific effects, including the stability of the different adducts in solution under the selected reaction conditions. The gas-phase behavior of the observed products was investigated using sustained off-resonance irradiation collision-induced dissociation (SORI-CID) to obtain valuable information for guiding the design of sequencing experiments and helping the data interpretation. Structured RNA substrates, such as HIV-1 stemloop 1, were finally employed to investigate the structural determinant of adduct formation and highlight the different nature of the spatial information provided by the various candidate probes.

The use of MassARRAY technology for high throughput genotyping

This chapter will explore the role of mass spectrometry (MS) as a detection method for genotyping applications and will illustrate how MS evolved from an expert-user-technology to a routine laboratory method in biological sciences. The main focus will be time-of-flight (TOF) based devices and their use for analyzing single-nucleotide-polymorphisms (SNPs, pronounced snips). The first section will describe the evolution of the use of MS in the field of bioanalytical sciences and the protocols used during the early days of bioanalytical MALDI TOF mass spectrometry. The second section will provide an overview on intraspecies sequence diversity and the nature and importance of SNPs for the genomic sciences. This is followed by an exploration of the special and advantageous features of mass spectrometry as the key technology in modern bioanalytical sciences in the third chapter. Finally, the fourth section will describe the MassARRAY technology as an advanced system for automated high-throughput analysis of SNPs.

Detection of DNA adducts of benzo[a]pyrene using immunoelectrophoresis with laser-induced fluorescence. Analysis of A549 cells

Detection of benzo[a]pyrene diol epoxide (BPDE)-damaged DNA in a human lung carcinoma cell line (A549) has been performed using free zone affinity capillary electrophoresis with laser-induced fluorescence (LIF). Using BPDE as a model carcinogenic compound, the speed, sensitivity and specificity of this technique was demonstrated. Under free zone conditions, an antibody bound adduct was baseline-resolved from an unbound adduct in less than 2 min. The efficiencies of separation were in excess of 6 x 10(5) and 1 x 10(6) plates per meter for the antibody-bound and unbound adducts, respectively. Separation using a low ionic strength buffer permitted the use of a high electric field (830 V/cm) without the loss of resolving power. Using LIF detection, a concentration detection limit of roughly 3 x 10(-10) M was achieved for a 90-mer oligonuleotide containing a single BDPE. The use of formamide in the incubation buffer to enhance denaturing of DNA did not affect the stability of the complex between the antibody and the adducts. Using a fluorescently labeled BPDE-modified DNA adduct probe, a competitive assay was established to determine the levels of BPDE-DNA adducts in A549 cells.

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.

Differentiation of isomeric photomodified oligodeoxynucleotides by fragmentation of ions produced by matrix-assisted laser desorption ionization and electrospray ionization

UV irradiation of oligodeoxynucleotides at 254 nm generates several different types of DNA photoproducts, including cis-syn cyclobutane pyrimidine dimers, pyrimidine[6-4] pyrimidone photoproducts and their Dewar valence isomers, and thymine-adenine photoproducts (TA*). Studies of photoproducts in oligodeoxynucleotides require the development of suitable structure determination methods such as mass spectrometry. In an earlier study (Vollmer et al. Int. J. Mass Spectrom. Ion Processes 1997, 165/166, 487-496), we showed that fast atom bombardment and tandem sector mass spectrometry can be used to locate the site of photomodification and identify most of the photoproducts of d(TATTAT). One goal of the present research was to expand the method to the more sensitive electrospray ionization (ESI) and matrix-assisted laser desorption/ionization (MALDI) methods. A second goal was to test the generality of the methods by investigating not only the photoproducts of d(TATTAT) but also those of three other oligodeoxynucleotides, d(GTATTAT), d(GGCTATAA), and d(AATTAA). The photoproducts of these sequences were separated by HPLC and gave characteristic fragment ions in postsource decompositions of MALDI-produced ions and collisionally activated decompositions of ESI-produced ions.

Indirect mass spectrometric methods for characterizing and sequencing oligonucleotides

The use of mass spectrometry for the characterization and sequence determination of oligonucleotides is reviewed. This review focuses primarily on the use of mass spectrometry to analyze sequence-specific fragments of oligonucleotides that are generated via solution-phase chemical reactions. The majority of these "indirect" sequencing methods are a result of recent advances in electrospray ionization and matrix-assisted laser desorption/ionization for the generation of intact gas-phase ions from oligonucleotides. Descriptions of the current indirect sequencing protocols will be presented as well as a comparison of the applicability of these procedures for analyzing "real world" samples. The applicability of indirect mass spectrometric sequencing to antisense oligonucleotides will be discussed in detail. © 1997 John Wiley & Sons, Inc.

Mass spectrometry of nucleic acids

The present article is a survey of ESI and MALDI mass spectrometric analysis of nucleic acid oligomers and polymers. In order to limit the extent of the review, mass spectrometry of mononucleotides is generally not considered, except where such data are important for an understanding of the analysis of larger nucleic acids. The first part of the review is a condensed description of the structure and the acid-base properties of nucleic acids. The remaining part is divided into three main sections, dealing with the practical aspects of the two ionization techniques, fragmentation, and applications, respectively. The first section includes an extensive discussion of experimental parameters and problems, which are important for the analysis of different types of nucleic acid samples, including noncovalent complexes and mixtures. At the end of this section, as well as the following one, a comparison between MALDI and ESI as ionization techniques for nucleic acid is given. In addition to a detailed discussion of ion fragmentation, the fragmentation section includes an overview of the direct mass spectrometric sequencing of nucleic acids performed with either technique. The fragmentation reactions occurring upon MALDI and ESI are compared. The last section describes the life science applications of ESI-MS and MALDI-MS of nucleic acids; an account of experiments demonstrating the potential of a method, and of the bona fide solving of problems by ESI and MALDI is given. © 1997 John Wiley & Sons, Inc.

Molecular mass measurement of intact ribonucleic acids via electrospray ionization quadrupole mass spectrometry

The use of electrospray ionization mass spectrometry for the accurate determination of molecular masses of polynucleotides and small nucleic acids is developed. The common problem of gas phase cation adduction that is particularly prevalent in the mass spectrometric analysis of nucleic acids is reduced through the use of ammonium acetate precipitations and by the addition of chemical additives that compete for adduct ions in solution. The addition of chelating agents such as trans-1,2-diaminocyclohexane-N,N,N,',N'-tetraacetic acid to remove divalent metal ions and triethylamine to displace monovalent cations from the analyte, in conjunction with ammonium acetate precipitation, reduces cation adduction to levels that permit accurate mass analysis (mass errors of less than 0.01%) without further complex cleanup procedures. The potential utility of accurate mass measurements of small ribonucleic acids is discussed.

Matrix design for matrix-assisted laser desorption ionization: Sensitive determination of PAH-DNA adducts

Two matrices, 4-phenyl-α-eyanocinnamic acid (PCC) and 4-benzyloxy-α-eyanocinnamic acid (BCC), were identified for the determination of polycyclic aromatic hydrocarbon (PAH) adducts of DNA bases by matrix-assisted laser desorption ionization. These matrices were designed based on the concept that the matrix and the analyte should have structural similarities. PCC is a good matrix for the desorption of not only PAH-modified DNA bases, but also PAHs themselves and their metabolites. Detections can be made at the femtomolar level.

Ion trap tandem mass spectrometry applied to small multiply charged oligonucleotides with a modified base

Two isomeric oligodeoxynucleotide hexamers, 5'-d(N-6meATGCAT)-3' and 5'-d(ATGSmeCAT)-3', were subjected to analysis by electrospray and ion trap mass spectrometry. In the case of the isomer with a modified adenine, location of the modified base in the sequence was straightforward and a triple mass spectrometry experiment provided information on the identity of the modification. In contrast, the isomer with the methylated cytosine did not yield definitive information on the location or identity of the modification. Tandem mass spectrometry data in this case could indicate that the modification was present on either the third or fourth nucleoside. The two isomers represent extremes in the facility with which modified bases can be identified and located in a small oligonucleotide via multiple mass spectrometry of multiply charged anions. A preference for loss of particular bases strongly influences which structurally diagnostic ions are formed upon collisional activation. The likelihood for locating and identifying a modified base is dependent, therefore, upon the likelihood that the base is lost directly from the parention.

Collision-induced dissociation of uracil and its derivatives

The collision-induced dissociation of protonated uracil has been studied by tandem mass spectrometry using models extensively labeled with stable isotopes, and derivatives of the kinds found in nucleic acids. Following collisional activation at 30 eV translational energy, protonated uracil dissociates through two principal pathways which do not occur in electron ionization mass spectra: (1) elimination of NH3 almost entirely from N-3, followed by loss of CO from C-4, 0(4); (2) loss of H2O, equally from 0(2) and 0(4). Elimination of HNCO, also the principal dissociation process from odd-electron molecular ions, proceeds primarily by loss of N-3, C-Z, O(2) and 10% from N-l, C-Z, 0(2). Several secondary dissociation products are formed with quantitative site specificity of skeletal atoms: C,HO+ (4-C0, C-5, C-6); H2CN+ (N-l, C-6); C2H2+ (N-l, C-5, C-6). First-step dissociation reactions are interpreted in terms of pyrimidine ring opening at likely sites of protonation after collisional activation of MH+. Collision-induced dissociation mass spectra of uracils with structural themes common to nucleic acids (methylation, replacement of 0 by S, C-5 substitution) follow analogous reaction paths which permit assignment of sites of substitution, and exhibit ion abundance changes attributed to differences in substituent basicity and electron density.

Direct observation of UV-crosslinked protein-nucleic acid complexes by matrix-assisted laser desorption ionization mass spectrometry

Interactions between proteins and nucleic acids are important in the fundamental cellular processes that drive replication, recombination, dynamic alteration and repair of DNA, transcription and processing of RNA, synthesis of proteins, and regulation of enzyme activities. As part of an effort to develop a general, sensitive mass spectrometric strategy for the characterization of protein-nucleic acid interactions, we have used matrix-assisted laser desorption-ionization (MALDI) time-of-flight mass spectrometry to analyze protein-nucleic acid complexes that have been covalently crosslinked by ultraviolet (UV) light. In general, the application of MALDI mass spectrometric techniques to studies of UV-induced crosslinking of nucleoprotein complexes is demonstrated to be feasible. Specifically, MALDI mass analysis was used to determine the molecular weights of the phage T4 gene 32 protein (gp32) crosslinked to the oligonucleotide (dT)20, and the Escherichia coli transcription termination factor rho, photoaffinity labeled with 4-thio-uridine-diphosphate (4sUDP). The covalent gp32:(dT)20 complex is readily detected at a concentration of 1-2 microM in 1 microL of an unpurified solution of reactants that has been exposed to a single, 266 nm UV laser pulse. Mass spectrometric molecular weight determinations of the covalent rho:4sUDP complex add directness and specificity to the ATPase inactivation assay normally used to monitor the formation of 4sUDP photoaffinity labeled rho. It is found that successful MALDI mass spectrometry of protein-nucleic acid complexes is as critically dependent on the choice of solvents and additives as it is on the primary matrix compound.

Methyl guanine isomer distinction by hydrogen / deuterium exchange using a fourier transform mass spectrometer

Analytical Chemistry Division, Oak Ridge National Laboratory, Oak Ridge, Tennessee, USA Differentiation of the seven isomers of methyl guanine has been accomplished by monitoring gas-phase hydrogen/deuterium (H/D) exchange reactions of the protonated molecular ions with deuterium oxide (D2O) in a Fourier transform mass spectrometer. In each case a distinctive reaction rate for the first H/D exchange was observed, and exchanges of up to three deuterium atoms occurred with characteristic ion abundances that could be used to differentiate the isomers. O(6)-Methyl guanine, for example, showed only one slow H/D exchange with D2O, whereas l-methyl guanine exchanged two hydrogen atoms at a significantly faster rate. On comparison of the possible resonance structures of each protonated isomer with the experimental information about the number and rate of H/D exchanges observed, a reaction mechanism involving a concerted proton abstraction-deuterium cation donation was proposed.