Mass spectrometry of nucleic acids: the promise of matrix-assisted laser desorption-ionization (MALDI) mass spectrometry

Review of fragmentation of synthetic single-stranded oligonucleotides by tandem mass spectrometry from 2014 to 2022

The fragmentation of oligonucleotides by mass spectrometry allows for the determination of their sequences. It is necessary to understand how oligonucleotides dissociate in the gas phase, which allows interpretation of data to obtain sequence information. Since 2014, a range of fragmentation mechanisms, including a novel internal rearrangement, have been proposed using different ion dissociation techniques. The recent publications have focused on the fragmentation of modified oligonucleotides such as locked nucleic acids, modified nucleobases (methylated, spacer, nebularine and aminopurine) and modification to the carbon 2'-position on the sugar ring; these modified oligonucleotides are of great interest as therapeutics. Comparisons of different dissociation techniques have been reported, including novel approaches such as plasma electron detachment dissociation and radical transfer dissociation. This review covers the period 2014-2022 and details the new knowledge gained with respect to oligonucleotide dissociation using tandem mass spectrometry (without priori sample digestion) during that time, with a specific focus on synthetic single-stranded oligonucleotides.

Effects of Dl-3-n-butylphthalide on Cerebral Ischemia Infarction in Rat Model by Mass Spectrometry Imaging

Dl-3-n-butylphthalide (NBP) is a drug that is used in the treatment of ischaemic stroke. However, to the best of our knowledge, there are no systematic studies investigating the effects of dl-3-n-butylphtalide on the brain metabolism of small molecules. In this study, we first investigated the effects of dl-3-n-butylphthalide on the spatial distribution of small molecules in the brains of rats with permanent middle cerebral artery occlusion (pMCAO) using matrix-assisted laser desorption ionization time of flight mass spectrometry (MALDI–TOF–MS) imaging. After pMCAO modelling or a sham operation, rats were given four mg/kg of dl-3-n-butylphthalide through the caudal vein or saline once a day for nine days. The degree of neurological deficit in rats was evaluated using the modified neurological severity score (mNSS). MALDI–TOF–MS imaging was used to observe the content and distribution of small molecules related to metabolism during focal cerebral ischaemia. Multiple reaction monitoring (MRM) mode with liquid chromatography tandem mass spectrometry (LC–MS/MS) was used to verify the results obtained from MALDI–TOF–MS imaging. These small molecules were found to be involved in glucose metabolism, ATP metabolism, the glutamate–glutamine cycle, malate aspartate shuttle, oxidative stress, and inorganic ion homeostasis. Of the 13 metabolites identified by MALDI–TOF–MS imaging, seven compounds, ATP, ADP, AMP, GMP, N-acetylaspartic acid, ascorbic acid and glutathione, were further validated by LC–MS/MS. Taken together, these results indicate that dl-3-n-butylphthalide significantly improved ATP metabolism, level of antioxidants, and sodium-potassium ion balance in a rat model of pMCAO.

Effect of Structured Surfaces on MALDI Analyte Peak Intensities

A surface modification method is presented: a sodium chloride crystal, a transparent wide bandgap insulator, was deposited onto a stainless steel surface. The surface was subjected to various stimuli to induce surface defects either on the steel surface or salt crystal and the ion yield of substance P, a model peptide, was investigated as a function of stimuli. The interaction of the laser at potential defect sites resulted in an increase in the ion yield of substance P (3–17 fold increase relative to no stimuli).

Matrix-assisted laser desorption/ionization for simultaneous quantitation of (acyl-)carnitines and organic acids in dried blood spots

RATIONALE

Screening for inborn errors of metabolism using mass spectrometry is part of nationwide newborn screening programs and involves the detection of disease relevant (acyl-)carnitines and organic acids from dried blood spots. Matrix-Assisted Laser Desorption/Ionization Mass Spectrometry (MALDI-MS) is a well-established tool for proteomics approaches. In recent years, this technique has become more and more integrated in analysis and identification of small metabolites and disease biomarkers in daily clinical laboratories.

METHODS

We used a combination of both MALDI and high-resolution accurate mass (HR/AM) mass spectrometry using a linear ion trap-Orbitrap for the identification of small molecules from dried blood spots that serve as biomarkers for inborn errors of metabolism. The levels of detected metabolite species were compared between healthy newborns and affected patients with various inborn errors of metabolism using isotopically labeled internal standards and new bioinformatics software, respectively.

RESULTS

(Acyl-)carnitine levels from normal and affected patients could be quantified and differentiated. Additionally, using the high resolving power of full scan Orbitrap mass spectrometry and novel software tools we demonstrated the identification and quantification of disease-specific organic acids.

CONCLUSIONS

MALDI-HR/AM and full scan spectra to obtain information for the metabolic status of patients is a promising complementary approach to electrospray ionization mass spectrometry by simplified sample preparation, facilitating the screening of hundreds of metabolites from small sample volumes.

Applications of mass spectrometry to the study of siRNA

RNA interference (RNAi) has quickly become a well-established laboratory tool for regulating gene expression and is currently being explored for its therapeutic potential. The design and use of double-stranded RNA oligonucleotides as therapeutics to trigger the RNAi mechanism and a greater effort to understand the RNAi pathway itself is driving the development of analytical techniques that can characterize these oligonucleotides. Electrospray (ESI) and MALDI have been used routinely to analyze oligonucleotides and their ability to provide mass and sequence information has made them ideal for this application. Reviewed here is the work done to date on the use of ESI and MALDI for the study of RNAi oligonucleotides as well as the strategies and issues associated with siRNA analysis by mass spectrometry. While there is not a large body of literature on the specific application of mass spectrometry to RNAi, the work done in this area is a good demonstration of the range of experiments that can be conducted and the value that ESI and MALDI can provide to the RNAi field.

Structure determination of beta-glucans from Ganoderma lucidum with matrix-assisted laser desorption/ionization (MALDI) mass spectrometry

A novel method that uses matrix-assisted laser desorption/ionization (MALDI) mass spectrometry to analyze molecular weight and sequencing of glucan in Ganoderma lucidum is presented. Thus, β-glucan, which was isolated from fruiting bodies of G. lucidum, was measured in a direct and fast way using MALDI mass spectrometry. In addition, tandem mass spectrometry of permethylated glucans of G. lucidum, dextran, curdlan and maltohexaose were also pursued and different fragment patterns were obtained. The G. lucidum glucan structure was determined and this method for linkage analysis of permethylated glucan has been proven feasible.

Let them fly or light them up: matrix-assisted laser desorption/ionization time of flight (MALDI-TOF) mass spectrometry and fluorescence in situ hybridization (FISH)

This review focuses on clinical bacteriology and by and large does not cover the detection of fungi, viruses or parasites. It discusses two completely different but complementary approaches that may either supplement or replace classic culture-based bacteriology. The latter view may appear provocative in the light of the actual market penetration of molecular genetic testing in clinical bacteriology. Despite its elegance, high specificity and sensitivity, molecular genetic diagnostics has not yet reached the majority of clinical laboratories. The reasons for this are manifold: Many microbiologists and medical technologists are more familiar with classical microbiological methods than with molecular biology techniques. Culture-based methods still represent the work horse of everyday routine. The number of available FDA-approved molecular genetic tests is limited and external quality control is still under development. Finally, it appears difficult to incorporate genetic testing in the routine laboratory setting due to the limited number of samples received or the lack of appropriate resources. However, financial and time constraints, particularly in hospitals as a consequence of budget cuts and reduced length of stay, lead to a demand for significantly shorter turnaround times that cannot be met by culture-dependent diagnosis. As a consequence, smaller laboratories that do not have the technical and personal equipment required for molecular genetic amplification techniques may adopt alternative methods such as fluorescence in situ hybridization (FISH) that combines easy-to-perform molecular hybridization with microscopy, a technique familiar to every microbiologist. FISH is hence one of the technologies presented here. For large hospital or reference laboratories with a high sample volume requiring massive parallel high-throughput testing we discuss matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF) of nucleic acids, a technology that has evolved from the post-genome sequencing era, for high-throughput sequence variation analysis (1, 2).

Accurate mass measurement of DNA oligonucleotide ions using high-resolution time-of-flight mass spectrometry

Matrix-assisted laser desorption/ionization (MALDI) and electrospray ionization (ESI) time-of-flight mass spectrometry (TOFMS) play an essential role in the analysis of biological molecules, not only peptides and proteins, but also DNA and RNA. Tandem mass spectrometry used for sequence analysis has been a major focus of technological developments in mass spectrometry, but accurate mass measurements by high-resolution TOFMS are equally important. This paper describes the role that high mass measurement accuracy can play in DNA composition assignment and discusses the influence of several parameters on mass measurement accuracy in both MALDI and ESI mass spectra. Five oligonucleotides (5-13mers) were used to test the resolving power and mass measurement accuracy obtained with MALDI and ESI instruments with reflectron TOF mass analyzers. The results from the experimental studies and additional theoretical calculations provide a basis to predict the practical utility of high-resolution TOFMS for the analysis of larger oligonucleotides.

Instrumentation for the genome project

Much of the recent rapid progress in large-scale genomic sequencing has been driven by the dramatic improvements both in the area of biological protocols and in the availability of improved laboratory instrumentation and automation platforms. We discuss recent developments in the area of bioinstrumentation that are contributing to the current revolution in genetic analysis. Examples of systems for laboratory automation are described together with specific single-purpose instruments. Emphasis is placed on those tools that are contributing significantly to the scale-up of genomic mapping and sequencing efforts. In addition, we present a selection of more advanced measurement techniques and instrumentation developments that are likely to contribute significantly to future advances in sequencing and genome analysis.

Laser desorption electron attachment time-of-flight mass spectrometry: a new approach to detection of involatile compounds

We report initial results of a new method for obtaining mass spectra of involatile compounds: laser desorption electron attachment time-of-flight mass spectrometry. With this approach, laser desorbed neutral molecules are entrained in a molecular beam and subsequently ionized by low energy electron attachment. Mass analysis is carried out by a linear time-of-flight. We present a description of the apparatus and a number of examples of our early results on: van der Waals condensates of SF6, Fullerenes, derivatized Fullerenes, perfluorinated polyethers, polyphenylethers, and 5-bromouracil.

Quantitative mutant analysis of viral quasispecies by chip-based matrix-assisted laser desorption/ ionization time-of-flight mass spectrometry

RNA viruses exist as quasispecies, heterogeneous and dynamic mixtures of mutants having one or more consensus sequences. An adequate description of the genomic structure of such viral populations must include the consensus sequence(s) plus a quantitative assessment of sequence heterogeneities. For example, in quality control of live attenuated viral vaccines, the presence of even small quantities of mutants or revertants may indicate incomplete or unstable attenuation that may influence vaccine safety. Previously, we demonstrated the monitoring of oral poliovirus vaccine with the use of mutant analysis by PCR and restriction enzyme cleavage (MAPREC). In this report, we investigate genetic variation in live attenuated mumps virus vaccine by using both MAPREC and a platform (DNA MassArray) based on matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry. Mumps vaccines prepared from the Jeryl Lynn strain typically contain at least two distinct viral substrains, JL1 and JL2, which have been characterized by full length sequencing. We report the development of assays for characterizing sequence variants in these substrains and demonstrate their use in quantitative analysis of substrains and sequence variations in mixed virus cultures and mumps vaccines. The results obtained from both the MAPREC and MALDI-TOF methods showed excellent correlation. This suggests the potential utility of MALDI-TOF for routine quality control of live viral vaccines and for assessment of genetic stability and quantitative monitoring of genetic changes in other RNA viruses of clinical interest.

Improving spot homogeneity by using polymer substrates in matrix-assisted laser desorption/ionization mass spectrometry of oligonucleotides

We describe a method for improving the homogeneity of MALDI samples prepared for analysis of small, single-stranded oligonucleotides using the widely used DNA matrix system, 3-hydroxypicolinic acid/picolinic acid/ ammonium citrate. This matrix system typically produces large crystals around the rim of the dried sample and requires tedious searching of this rim with the laser. However, when a substrate is prepared using both Nafion and a hydrophilic, high-molecular-weight polymer, such as linear polyacrylamide, linear poly(ethylene oxide), or methyl cellulose, oligonucleotide-doped matrix crystals tend to be smaller and more uniformly distributed across the entire spot, thus decreasing the time that is required for locating a usable signal. In addition to MALDI characterization of the spatial distribution of "sweet spots," fluorescence microscopy allows for imaging dye-labeled DNA in dried MALDI spots. The mechanism of enhanced uniformity may involve increased viscosity in the MALDI sample droplet due to partial solubilization of the substrate by the MALDI sample solvent as well as partitioning of the matrix or DNA between the solvent and the undissolved portion of the polymer substrate.

MALDI TOF mass spectrometry: an emerging platform for genomics and diagnostics

Matrix-assisted laser desorption/ionization-time of flight (MALDI TOF) mass spectrometry has become, in recent years, a tool of choice for large molecule analyses. The platform is ideal for analysis of protein and nucleic acid sequence, structure and purity. MALDI TOF is the method of choice for quality assurance in oligo and peptide synthesis. Exact mass measurements along with signal intensity detection provide a high level of quality assurance as to the accuracy of the measurement. This accuracy has the potential to significantly lower the level of indeterminate assays that require retest.

PCR-CTPP: a new genotyping technique in the era of genetic epidemiology

A new PCR method, PCR-CTPP (polymerase chain reaction with confronting two-pair primers) was invented to genotype a relatively large number of samples in a cost-effective and time-saving manner. In this method, allele-specific DNA products are amplified by means of applying appropriately designed two-pair primers (four primers) into an ordinary PCR tube. Single genotyping for G2886T at L-myc, Arg72Pro of p53 and Glu487Lys of ALDH2 as well as duplex genotyping for C-31T of IL-1B with VNTR of IL-1RN and A385T of secretor gene with se5, are demonstrated as examples with the primers and PCR conditions.

Automated mass spectrometry: a revolutionary technology for clinical diagnostics

For various diagnostic analyses and the studies of functional genomics, the use of an accurate and cost-effective analytic platform to analyze large numbers of samples is essential. An automated platform called MassArray (Sequenom, Inc, San Diego, CA), designed for high-throughput diagnostic analyses, has recently been validated. The platform combines miniaturized, two-dimensional chip arrays with proven high-fidelity enzymatic procedures and matrix-assisted laser-desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry. Nanoliter dispensing of samples in high-density formats of 384 or greater results in improved throughput and reduced costs. Automation prevails from the initial assay design through sample processing and data analysis, for the most part eliminating the labor component of assay development and implementation. The MassArray platform is being used in the following areas: (1) molecular diagnosis of genetic disease and infectious agents, (2) pharmacogenomics, (3) paternity and/or identity testing, and (4) agriculture (e.g., marker-assisted breeding). MALDI-TOF mass spectrometry can also be used for analyzing proteins; therefore, genotype/phenotype testing can be performed on a single platform.

Automation for genomics, part two: sequencers, microarrays, and future trends

Automation for genomics has enabled a 43-fold increase in the total finished human genomic sequence in the world in the past four years. This is the second half of a two-part, noncomprehensive review that presents an overview of different types of automation equipment used in genome sequencing. The first part of the review, published in the previous issue, focused on automated procedures used to prepare DNA for sequencing or analysis. This second part of the review presents a look at available DNA sequencers and array technology and concludes with a look at future technologies. Alternate sequencing technologies including mass spectrometry, biochips, and single molecule analysis are included in this review.

Evidence for unfolding of the single-stranded GCCA 3'-End of a tRNA on its aminoacyl-tRNA synthetase from a stacked helical to a foldback conformation

The conformation of a tRNA in its initial contact with its cognate aminoacyl-tRNA synthetase was investigated with the Escherichia coli glutamyl-tRNA synthetase-tRNA(Glu) complex. Covalent complexes between the periodate-oxidized tRNA(Glu) and its synthetase were obtained. These complexes are specific since none were formed with any other oxidized E. coli tRNA. The three major residues cross-linked to the 3'-terminal adenosine of oxidized tRNA(Glu) are Lys115, Arg209, and Arg48. Modeling of the tRNA(Glu)-glutamyl-tRNA synthetase based on the known crystal structures of Thermus thermophilus GluRS and of the E. coli tRNA(Gln)-glutaminyl-tRNA synthetase complex shows that these three residues are located in the pocket that binds the acceptor stem, and that Lys115, located in a 26 residue loop closed by coordination to a zinc atom in the tRNA acceptor stem-binding domain, is the first contact point of the 3'-terminal adenosine of tRNA(Glu). In our model, we assume that the 3'-terminal GCCA single-stranded segment of tRNA(Glu) is helical and extends the stacking of the acceptor stem. This assumption is supported by the fact that the 3' CCA sequence of tRNA(Glu) is not readily circularized in the presence of T4 RNA ligase under conditions where several other tRNAs are circularized. The two other cross-linked sites are interpreted as the contact sites of the 3'-terminal ribose on the enzyme during the unfolding and movement of the 3'-terminal GCCA segment to position the acceptor ribose in the catalytic site for aminoacylation.

Single-nucleotide polymorphism analysis by MALDI-TOF mass spectrometry

Single-nucleotide polymorphisms (SNPs) have great potential for use in genetic-mapping studies, which locate and characterize genes that are important in human disease and biological function. For SNPs to realize their full potential in genetic analysis, thousands of different SNP loci must be screened in a rapid, accurate and cost-effective manner. Matrix-assisted laser desorption-ionization-time-of-flight (MALDI-TOF) mass spectrometry is a promising tool for the high-throughput screening of SNPs, with future prospects for use in genetic analysis.

Four Common Mutations of the Cystathionine β-Synthase Gene Detected by Multiplex PCR and Matrix-assisted Laser Desorption/Ionization Time-of-Flight Mass Spectrometry

Background: A deficiency of cystathionine β-synthase (CBS) is the most frequent cause of homocystinuria. The effect of therapy is related to the underlying CBS genotype, which makes early diagnosis of this genetic defect important. Our aim was to develop a fast and reliable method based on matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry for the determination of common mutations of the CBS gene.

Methods: We used MALDI-TOF mass spectrometry to detect four common CBS mutations (G307S, T272M, I278T, and V320A). The method is based on multiplex PCR of exons 7, 8, and 9, followed by single nucleotide extension in the presence of dideoxy NTPs of four primers targeted at the separate mutation sites. The extension products, as well as the 3-hydroxypicolinic acid matrix, were incubated with cation-exchange beads to remove disturbing salt contaminants.

Results: The above-mentioned mutations were determined in samples from 12 homocystinuria patients. The MALDI-TOF spectra allowed unambiguous discrimination between primers and extension products (>9 Da) in the mass range between 4500 and 7500 Da. No labeled primers or ddNTPs were required. The genotyping was verified by reference technique.

Conclusion: Our results demonstrate fast, simple, and unambiguous multiplex genotyping of four common CBS mutations by MALDI-TOF mass spectrometry.

A new method for determining the stereochemistry of DNA cleavage reactions: application to the SfiI and HpaII restriction endonucleases and to the MuA transposase

A new method was developed for tracking the stereochemical path of enzymatic cleavage of DNA. DNA with a phosphorothioate of known chirality at the scissile bond is cleaved by the enzyme in H218O. The cleavage produces a DNA molecule with the 5'-[16O,18O, S]-thiophosphoryl group, whose chirality depends on whether the cleavage reaction proceeds by a single-step hydrolysis mechanism or by a two-step mechanism involving a protein-DNA covalent intermediate. To determine this chirality, the cleaved DNA is joined to an oligonucleotide by DNA ligase. Given the strict stereochemistry of the DNA ligase reaction, determined here, the original chirality of the phosphorothioate dictates whether the 18O is retained or lost in the ligation product, which can be determined by mass spectrometry. This method has advantages over previous methods in that it is not restricted to particular DNA sequences, requires substantially less material, and avoids purification of the products at intermediate stages in the procedure. The method was validated by confirming that DNA cleavage by the EcoRI restriction endonuclease causes inversion of configuration at the scissile phosphate. It was then applied to the reactions of the SfiI and HpaII endonucleases and the MuA transposase. In all three cases, DNA cleavage proceeded with inversion of configuration, indicating direct hydrolysis of the phosphodiester bond by water as opposed to a reaction involving a covalent enzyme-DNA intermediate.

Laser desorption of DNA oligomers larger than one kilobase from cooled 4-nitrophenol

A unique matrix system consisting mostly of 4-nitrophenol has shown to be very effective for matrix-assisted laser desorption/ionization time-of-flight mass spectrometric analysis of large DNA oligomers when a cooled sample stage was used to prevent the sublimation of this matrix under vacuum. Using this 4-nitrophenol matrix with UV laser desorption, detection of picomole quantities of DNA oligomers containing up to approximately 800 nucleotides was routinely achieved. The effectiveness of this matrix was further demonstrated by the observation of a double-stranded DNA oligomer larger than 1000 base pairs, seen as a denatured single-stranded species, with a molecular ion mass exceeding 300 000 Da. The potential applications of 4-nitrophenol as a matrix for DNA sizing are discussed.

MALDI-TOF analysis of polymerase chain reaction products from methanotrophic bacteria

Polymerase chain reaction (PCR) assays were designed to amplify 56- and 99-base regions of the pmoA gene from Methylosinus trichosporium OB3b and Methylomicrobium albus BG8, two species of methanotrophic bacteria that are of interest for monitoring bioremediation activity. The PCR product sizes are in a mass range that is accessible to analysis by MALDI-TOF mass spectrometry. A rapid purification procedure using commercially available reversed-phase cartridges was applied prior to MALDI-TOF analysis. A small aliquot (1.5%, 1.5 microL) from a single 100-microL PCR reaction was sufficient for reliable detection. No cross-amplification products were observed when primers designed for one bacterial species were used with genomic DNA of the other species. The methodology described here has potential to allow less expensive and faster characterization of the ability of microbial populations to destroy pollutants in groundwater and soil at contaminated industrial sites.

Applications of mass spectrometry to the characterization of oligonucleotides and nucleic acids

Mass spectrometry-based techniques continue to undergo active development for applications to nucleic acids, fueled by methods based on electrospray and matrix-assisted laser desorption ionization. In the past two years, notable advances have occurred in multiple interrelated areas, including sequencing techniques for oligonucleotides, approaches to mixture analysis, microscale sample handling and targeted DNA assays, and improvements in instrumentation for greater sensitivity and mass resolution.

DNA typing of human leukocyte antigen sequence polymorphisms by peptide nucleic acid probes and MALDI-TOF mass spectrometry

A novel analytical method using PNA probes detected by matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOFMS) was applied to type sequence polymorphisms within the human leukocyte antigen (HLA), DQA locus. Streptavidin-coated magnetic beads were used to immobilize biotinylated DNA. PNA probes representing possible alleles were then prepared for the immobilized DNA hybridization. The nonspecific PNA probes were removed with stringent washes. The PNA/DNA/beads conjugate was analyzed by MALDI-TOFMS. The genotype of the DNA was determined by the detected molecular masses of the released PNA probes. Reproducible and accurate genotyping was achieved by this analytical method.

Detecting CFTR gene mutations by using primer oligo base extension and mass spectrometry

A new method for the reliable identification of localized variations in DNA by detection of associated diagnostic products with matrix-assisted laser desorption ionization time-of-flight mass spectrometry is described. The diagnostic products are generated by the primer oligo base extension (PROBE) reaction, which requires a single detection primer complementary to a region downstream of a target strand’s variable site. On addition of a polymerase, three dNTPs, and the fourth nucleotide in dideoxy form, the primer is extended through the mutation region until the first ddNTP is incorporated; the mass of the extension products determines the composition of the variable site. Tests for five cystic fibrosis mutations, including two exon 11 sites measured in a biplex reaction, and for differentiating between three common alleles of the poly(T) tract at the intron 8 splice acceptor site of the CFTR gene are presented. All experimental steps required for PROBE are amenable to the high degree of automation desirable for a high-throughput diagnostic setting. Furthermore, it requires no fluorescent, chemiluminescent, or radioactive labeling; the mass signals measured offer a far more analytically definitive signal, leading in all cases to high-quality unambiguous and easily interpreted results.

Identification and sequence analysis of contact sites between ribosomal proteins and rRNA in Escherichia coli 30 S subunits by a new approach using matrix-assisted laser desorption/ionization-mass spectrometry combined with N-terminal microsequencing

Cross-linked peptide-oligoribonucleotide complexes derived from distinct regions of the rRNA and individual ribosomal proteins of the 30 S ribosomal subunits from Escherichia coli were isolated and purified. Cross-linking sites at the amino acid and nucleotide level were determined by N-terminal amino acid sequence analysis in combination with matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). MALDI-MS analysis performed subsequent to a partial alkaline hydrolysis of cross-linked peptide-oligoribonucleotide complexes allowed for the first time the cross-linked rRNA moiety to be sequenced by this technique. In this manner Lys-44 in S4 was determined to be cross-linked to the oligoribonucleotide at positions 1531-1542 on the 16 S RNA (whereby either U-1541 or A-1542 is the actual cross-link site), Lys-75 in S7 to positions 1374-1379 (C-1378 cross-linked), Met-114 in S7 to 1234-1241 (U-1240 cross-linked), Lys-55 in S8 to 651-654 (U-653 cross-linked), and Lys-29 in S17 to 629-633 (U-632 cross-linked). The novel approach applied here promises to be useful for similar studies on other known protein.RNA complexes.

Metal complexation reactions of quinolone antibiotics in a quadrupole ion trap

We have undertaken a systematic study of the nature of quinolone metal complexes formed by electrospray ionization and laser desorption/ion-molecule reactions to evaluate the analytical utility of metal complexation as an alternative to conventional ionization via protonation. Metal ionization with laser-desorbed copper and nickel ions results in addition products of the form (L + Cu+) and (L + Ni+), respectively, where L is the quinolone, whereas addition-elimination products of the form (L + Co(+)-28) are observed when cobalt is used. The elimination of CO in order to form this unusual latter product seems to be favored by the formation of a cyclized structure that is stabilized by intramolecular hydrogen bonding. The CAD patterns of the Ni+ complexes prove to be the most structurally informative, more so than the fragmentation patterns of the protonated quinolones. Quinolone-metal complexes of the type [MII(L-H+)-(dipy)]+, where M is either Cu, Co, or Ni and dipy is 2,2'-dipyridine, are generated by electrospray ionization of a methanolic solution containing a quinolone antibiotic, a transition metal ion salt, and an auxiliary diimine ligand. Upon collisional activation, the ESI-generated complexes dissociate predominantly by loss of CO2, which is also the most common fragmentation pathway for the metal complexes formed through laser desorption/ion-molecule reactions. However, there are fewer structurally diagnostic fragment ions in the CAD spectra of the ESI complexes relative to those of the LD complexes.

Towards inexpensive DNA diagnostics

Methodologies to obtain DNA sequence information efficiently and accurately will provide the basis for a broad spectrum of economical products and applications to a variety of industrial sectors, in addition to healthcare. Such technologies will build upon the evolving molecular biology and instrumentation base that is serving a specific research market. This will require the efficient integration of technical advances in microchemistry, micromachining, separation technologies, detection systems, microelectronics and information technology, and will involve the expertise of engineers, physicists, chemists, mathematicians, computer scientists and molecular biologists. The biotechnology, microelectronics, software, instrumentation, pharmaceutical and fine chemical industries will be vital to this development.

Biochemical mass spectrometry: worth the weight?

The utility of mass spectrometry for the analysis of biological molecules has been enhanced by the development of two techniques that generate gas-phase ions via nondestructive vaporization and ionization. These techniques can be used not only to determine the primary structure of biological molecules with unprecedented accuracy, but also to map noncovalent biomolecular interactions.

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.