MS for identification of single nucleotide polymorphisms and MS/MS for discrimination of isomeric PCR products

Pytheas: a software package for the automated analysis of RNA sequences and modifications via tandem mass spectrometry

Mass spectrometry is an important method for analysis of modified nucleosides ubiquitously present in cellular RNAs, in particular for ribosomal and transfer RNAs that play crucial roles in mRNA translation and decoding. Furthermore, modifications have effect on the lifetimes of nucleic acids in plasma and cells and are consequently incorporated into RNA therapeutics. To provide an analytical tool for sequence characterization of modified RNAs, we developed Pytheas, an open-source software package for automated analysis of tandem MS data for RNA. The main features of Pytheas are flexible handling of isotope labeling and RNA modifications, with false discovery rate statistical validation based on sequence decoys. We demonstrate bottom-up mass spectrometry characterization of diverse RNA sequences, with broad applications in the biology of stable RNAs, and quality control of RNA therapeutics and mRNA vaccines.

Determination of mutated genes in the presence of wild-type DNA by using molecular beacons as probe

Low-abundance mutations in the presence of wild-type DNA can be determined using molecular beacon (MB) as probe. A MB is generally used as DNA probe because it can distinguish single-base mismatched target DNA from fully matched target DNA. However, the probe can not determine low-abundance mutations in the presence of wild-type DNA. In this study, this limitation is addressed by enhancing the stability of unpaired base-containing dsDNA with a hydrogen-bonding ligand, which was added after hybridization of the MB to the target DNA. The ligand formed hydrogen bonds with unpaired bases and stabilized the unpaired base-containing dsDNA if target DNA is mutated one. As a result, more MBs were opened by the mutant genes in the presence of the ligand and a further increase in the fluorescence intensity was obtained. By contrast, fluorescence intensity did not change if target DNA is wild-type one. Consequent increase in the fluorescence intensity of the MB was regarded as a signal derived from mutant genes. The proposed method was applied in synthetic template systems to determine point mutation in DNA obtained from PCR analysis. The method also allows rapid and simple discrimination of a signal if it is originated in the presence of mutant gene or alternatively by a lower concentration of wild gene.

Identification of RNA sequence isomer by isotope labeling and LC-MS/MS

Recently, we developed a method for modified ribonucleic acid (RNA) analysis based on the comparative analysis of RNA digests (CARD). Within this CARD approach, sequence or modification differences between two samples are identified through differential isotopic labeling of two samples. Components present in both samples will each be labeled, yielding doublets in the CARD mass spectrum. Components unique to only one sample should be detected as singlets. A limitation of the prior singlet identification strategy occurs when the two samples contain components of unique sequence but identical base composition. At the first stage of mass spectrometry, these sequence isomers cannot be differentiated and would appear as doublets rather than singlets. However, underlying sequence differences should be detectable by collision-induced dissociation tandem mass spectrometry (CID MS/MS), as y-type product ions will retain the original enzymatically incorporated isotope label. Here, we determine appropriate instrumental conditions that enable CID MS/MS of isotopically labeled ribonuclease T1 (RNase T1) digestion products such that the original isotope label is maintained in the product ion mass spectrum. Next, we demonstrate how y-type product ions can be used to differentiate singlets and doublets from isomer sequences. We were then able to extend the utility of this approach by using CID MS/MS for the confirmation of an expected RNase T1 digestion product within the CARD analysis of an Escherichia coli mutant strain even in the presence of interfering and overlapping digestion products from other transfer RNAs.

Nucleic acid ion structures in the gas phase

Nucleic acids are diverse polymeric macromolecules that are essential for all life forms. These biomolecules possess a functional three-dimensional structure under aqueous physiological conditions. Mass spectrometry-based approaches have on the other hand opened the possibility to gain structural information on nucleic acids from gas-phase measurements. To correlate gas-phase structural probing results with solution structures, it is therefore important to grasp the extent to which nucleic acid structures are preserved, or altered, when transferred from the solution to a fully anhydrous environment. We will review here experimental and theoretical approaches available to characterize the structure of nucleic acids in the gas phase (with a focus on oligonucleotides and higher-order structures), and will summarize the structural features of nucleic acids that can be preserved in the gas phase on the experiment time scale.

Instantaneous derivatization technology for the simultaneous and homogeneous detection of multiple double-stranded PCR amplicons

Herein we report on the development of instantaneous derivatization technology for the homogeneous and simultaneous detection of multiple PCR amplicons specific to the Hepatitis B Virus (HBV) by using three carriers: magnetic beads, polystyrene beads, and thermo-sensitive poly-N-isopropylacrylamide (PNIP). Briefly, PCR amplicons are labeled with digoxin, biotin or FITC via the modified up-stream primers respectively. After PCR amplification, the immunoreactions occur between a mixture of three target PCR amplicons and three modified carriers with anti-digoxin antibody, streptavidin or anti-FITC antibody in a single vessel, and then each carrier is separated from the others under different conditions based on their physio-chemical attributes. And then direct CL detection proceeds via the instantaneous derivatization reaction between intrinsic guanine nucleobases and 3,4,5-trimethoxylphenylglyoxal (TMPG). This new protocol directly measures the double-stranded DNA and therefore does not require a denaturing step, thus offering an enhanced sensitivity due to the absence of competitive hybridization, i.e., the detection limit had a 20-fold improvement on the conventional PCR measurement. Additionally, by comparison of previous guanine based detection formats, this protocol is easy to be used for the detection of any guanine containing targets without the use of guanine-free or inosine-substituted capture probes. Overall, the proposed technique takes the advantages of sensitivity, high-speed and cost-effectivity, which provides a promising alternative for the analysis of multiple PCR targets in a variety of clinical, environmental, and biodefense fields.

Mass spectrometry of RNA: linking the genome to the proteome

Ribonucleic acids (RNAs) are continuing to attract increased attention as they are found to play pivotal roles in biological systems. Just as genomics and proteomics have been enabled by the development of effective analytical techniques and instrumentation, the large-scale analysis of non-protein coding (nc)RNAs will benefit as new analytical methodologies, such as mass spectrometry (MS), are developed for their analysis. Mass spectrometry offers a number of advantages for RNA analysis arising from its ability to provide mass and sequence information starting with limited amounts of sample. This review will highlight recent developments in the field of MS that enable the characterization of RNA modification status, RNA tertiary structures, and ncRNA expression levels. These developments will also be placed in perspective of how MS of RNAs can help elucidate the link between the genome and proteome.

Accurate determination of allelic frequencies in mitochondrial DNA mixtures by electrospray ionization time-of-flight mass spectrometry

The mitochondrial locus 16519T/C was used as a model for the evaluation of the benefits of ion-pair reversed-phase high-performance liquid chromatography on-line hyphenated to electrospray ionization time-of-flight mass spectrometry (ICEMS assay) for the determination of allelic frequencies of single nucleotide polymorphisms. This marker has gained interest in forensic science owing to its ability to increase the discrimination power of mitochondrial DNA testing as a consequence of its high variability across various populations. In a first set of experiments, artificial mitochondrial DNA mixtures prepared from all four theoretically possible 16519 alleles served as samples. Any allele occurring at a frequency of as low as 1-5% was unequivocally detectable irrespective of the kind of allelic mixture. Measured and expected allelic frequencies correlated well following correction of observed experimental bias, which was most probably attributable to differential PCR amplification and/or preferential ionization. For thirteen different T/C mixtures with C contents in the range 1.0-99.0%, an average error of 1.2% and a maximum error of 2.2% were observed. Furthermore, ICEMS was applied to the quantitative genotyping of eight selected individuals of which four were heteroplasmic with C contents in the range 1.9-34.1%. To check the reliability of these results, allelic proportions were additionally determined by a cloning assay. The results of the two assays correlated well (R (2)=0.9971). In all cases, deviations were obtained that were smaller than 5.4%. The overall observed assay performance suggests that the described mass spectrometric technique represents one of the most powerful assays for the determination of allelic frequencies available today.

Analysis of single nucleotide polymorphism sites in exon 4 of the p53 gene using high-performance liquid chromatography electrospray ionization mass spectrometry tandem mass spectrometry

Three groups of four oligonucleotides with special single nucleotide polymorphisms (SNP) sites in exon 4 of the p53 gene were analyzed with ion-pair reversed-phase high-performance liquid chromatography electrospray ionization mass spectrometry tandem mass spectrometry. The retention order of four oligonucleotides with SNPs was C < G < A < T, regardless of whether the polymorphisms were at the 3' end, the 5' end, or the middle of the oligonucleotides. The charge state of the molecular ion affects the MS/MS spectra of the oligonucleotides. SNPs at the 3' end can be easily identified from the fragmentation pattern of the 2- charge state, but not from the 3- charge state, especially from the w1 fragment. The single base may be taken as the symbol of the 5' end SNP site derived from [M3H]2, but not from the [M3H]2 charge state. The oligonucleotides with SNPs in the middle were also determined from the [M2H]2 precursor ion.

Mass spectrometry provides accurate characterization of two genetic marker types in Bacillus anthracis

Epidemiological and forensic analyses of bioterrorism events involving Bacillus anthracis could be improved if both variable number tandem repeats (VNTRs) and single nucleotide polymorphisms (SNPs) could be combined on a single analysis platform. Here we present the use of electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry (ESI-FTICR-MS) to characterize 24 alleles from 6 VNTR loci and 11 alleles from 7 SNP loci in B. anthracis. The results obtained with ESI-FTICR-MS were consistent with independent results obtained from traditional approaches using electrophoretic detection of fluorescent products. However, ESI-FTICR-MS improves on the traditional approaches because it does not require fluorescent labeling of PCR products, minimizes post-PCR processing, obviates electrophoresis, and provides unambiguous base composition of both SNP and VNTR PCR products. In addition, ESI-FTICR-MS allows both marker types to be examined simultaneously and at a rate of approximately 1 sample per min. This technology represents a significant advance in our ability to rapidly characterize B. anthracis isolates using VNTR and SNP loci.

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.

Shotgun sequencing small oligonucleotides by nozzle-skimmer dissociation and electrospray ionization mass spectrometry

Nozzle-skimmer dissociation in combination with de novo sequencing was investigated as an approach for increasing the throughput of oligonucleotide analysis attainable by electrospray ionization mass spectrometry. An experimental method allowing for the sequential generation of precursor and fragment ion data during direct infusion of sample was developed. These data can then be used with readily available de novo sequencing software to characterize small oligonucleotides. When this approach was applied to mixtures of oligonucleotides, it was found that de novo sequencing becomes limited due to spectral congestion and overlapping oligonucleotide m/z dissociation product values. Self-packed C(18) microspray emitters were investigated as a means of reducing spectral complexity. It was found that such emitters allow for the analysis of oligonucleotide mixtures with minimal component overlap, and these emitters provide additional benefits of pre- concentrating and desalting the sample. These developments can provide a route for the more rapid characterization of ribonucleic acid endonuclease digestion mixtures.

Applicability of tandem mass spectrometry to the automated comparative sequencing of long-chain oligonucleotides

An algorithm for the comparative sequencing (COMPAS) of oligonucleotides is shown to be suitable for the sequence verification of nucleic acids ranging in length from a few to 80 nucleotides. The algorithm is based on the matching of a fragment ion spectrum generated by collision-induced dissociation to m/z values predicted from a known reference sequence employing established fragmentation pathways. Prior to mass spectrometric investigation, the oligonucleotides were on-line purified by ion-pair reversed-phase high-performance liquid chromatography using monolithic separation columns. This study evaluated the potential and the limits of COMPAS regarding the length and the charge state of oligonucleotides, the selected collision energy, and the analyzed amount of sample using a quadrupole ion trap mass spectrometer. The results revealed that oligonucleotides could be very reliably re-sequenced up to 60-mers, although the algorithm was successfully used to even verify sequences up to 80-mers. The relative collision energy was typically in the range between 13 and 20%, which allowed in most cases a verification of the reference sequence in a window of at least three consecutive collision energies. To select a proper charge state for fragmentation, a compromise had to be found between high signal intensity and low charge state. Furthermore, by reducing the eluent flow rate during elution of the oligonucleotide, the sequence of a 50-mer was successfully verified from the analysis of 295 fmol of the raw product. COMPAS was proven to be reproducible and was applied to the genotyping of the polymorphic, Y-chromosomal locus M9 contained in a 62-base pair polymerase chain reaction product.

Automated de novo sequencing of nucleic acids by liquid chromatography-tandem mass spectrometry

We present the first global computer-aided sequencing algorithm for the de novo determination of short nucleic acid sequences. The method compares the fragment ion spectra generated by collision-induced dissociation of multiply charged oligodeoxynucleotide-ions to the m/z values predicted employing established fragmentation pathways from a known reference sequence. The closeness of matching between the measured spectrum and the predicted set of fragment ions is characterized by the fitness, which takes into account the difference between measured and predicted m/z values, the intensity of the fragment ions, the number of fragments assigned, and the number of nucleotide positions not covered by fragment ions in the experimental spectrum. Smaller values for the fitness indicate a closer match between the measured spectrum and predicted m/z values. In order to find the sequence most closely matching the experimental spectrum, starting from a given nucleotide composition all possible oligonucleotide sequences are assembled followed by identification of the correct sequence by the lowest fitness value. Using this concept, sequences of 5- to 12-mer oligodeoxynucleotides were successfully de novo determined. High sequence coverage with fragment ions was essential for obtaining unequivocal sequencing results. Moreover, the collision energy was shown to have an impact on the interpretability of tandem mass spectra by the de novo sequencing algorithm. Experiments revealed that the optimal collision energy should be set to a value just sufficient for complete fragmentation of the precursor ion.

Characterization of G-rich and T-rich oligonucleotides using ion-pair reversed-phase high-performance liquid chromatography/tandem electrospray ionization mass spectrometry

Characteristics of G-rich and T-rich oligonucleotides were investigated to compare their retention time, total ion current (TIC) intensity, charge-state distribution and product ion using ion-pair reversed-phase high- performance liquid chromatography/tandem electrospray ionization mass spectrometry (IP-RP-HPLC/ESI-MS) at room temperature. Three commonly used mobile phases for the analysis of oligonucleotides, triethylammonium acetate (TEAA), triethylammonium bicarbonate (TEAB) and triethylammonium hexafluoroisopropanol (HFIP) have been utilized. Retention time of G-rich and T-rich oligonucleotides was significantly different in TEAA and TEAB buffer systems, while in the HFIP buffer system it was affected more by the length of oligonucleotides. On the other hand, the ESI-MS ion abundance in the HFIP buffer system was higher than that in both TEAA and TEAB buffers. The TIC intensity of T-rich oligonucleotides was much higher than that of G-rich oligonucleotides in all mobile phases. In addition, much higher charge-state fragments were observed in HFIP buffer system than that in the case of TEAA and TEAB buffer systems. Product ions of both G-rich and T-rich oligonucleotides were affected by charge state of parent ions and collision energy.

Implications of hydrophobicity and free energy of solvation for characterization of nucleic acids by electrospray ionization mass spectrometry

Electrospray ionization (ESI) is a dynamic process that, when coupled with mass spectrometry (MS), serves as an invaluable tool for analysis of biomolecules. Our group, as well as others, has observed that there is a bias in signal intensity for one strand of a PCR amplicon over the complementary strand in an ESI mass spectrum. In this report, we have investigated the contributions of hydrophobicity and free energy of solvation to relative signal intensities in ESI-MS spectra of nucleic acids. We developed approaches for predicting which strand of the PCR amplicon will be the most intense: one based on a rate equation for calculating ion flux using values from the literature for hydrophobicity and free energy of solvation and the other based on the percentage of the relatively hydrophilic guanines present in the strand. A trend in signal intensity for deoxyribonucleotide triphosphates, oligonucleotides, and PCR amplicons was observed that was consistent with our model. On the basis of the observation that increased hydrophobicity correlates with greater signal intensity, we selectively enhanced the signal intensity of a 20-mer with the addition of an alkyl chain to the 5' terminus, which subsequently improved the limit of detection to 1 nM, an improvement by 1 order of magnitude. This was extended to a 53-bp PCR amplicon by modifying one primer with the hydrophobic moiety, which resulted in a 16% increase in signal intensity. We capitalized on this result to determine allele frequencies from pooled DNA for single-nucleotide polymorphisms down to 1%.

Automated discrimination of polymerase chain reaction products with closely related sequences by software-based detection of characteristic peaks in product ion spectra

A computer-based method is described for automated detection of peaks in product ion spectra that allows discrimination of structurally related polymerase chain reaction (PCR) products. PCR products of K-ras mutants having single nucleotide substitutions and isomeric sequence changes in positions 1 and 2 of codon 12 (e.g. TGT and GTT) were used as a model system. SpecDiff, a tool for differentiating pairs of mass spectra by identifying peaks that either differ in relative intensity between spectra or only appear in one of a pair of spectra, was created to help automate detection. This program was demonstrated to have great utility in detection of mutations and could also be useful as a general tool for differentiating other molecules of closely related structure.

Enzymatic strategies for the characterization of nucleic acids by electrospray ionization mass spectrometry

Electrospray ionization mass spectrometry (ESI-MS) is a powerful technique used for the identification and characterization of DNA polymorphisms. Continual improvement in instrument design assures high mass measurement accuracy, sensitivity, and resolving power. This work describes an eclectic array of enzymatic strategies we have invoked in order to detect single-nucleotide polymorphisms by ESI-MS, although other applications may be envisioned. One strategy combines the use of two enzymes, exonuclease III and lambda exonuclease, to provide a ladder of single-stranded DNA fragments for straightforward sequence identification by mass spectrometry. A second strategy combines restriction enzymes to screen for polymorphisms present within specific amplicons. Finally, we describe the use of stable-isotope-labeled nucleotides for the determination of length and base composition of a PCR product.

Single nucleotide polymorphism genotyping by on-line liquid chromatography-mass spectrometry in forensic science of the Y-chromosomal locus M9

A method is described for genotyping alleles of the Y-chromosomal locus M9, incorporating DNA extraction, amplification by polymerase chain reaction (PCR), sample purification by ion-pair reversed-phase high-performance liquid chromatography (IP-RP-HPLC), and allele identification by on-line hyphenation to electrospray ionization mass spectrometry (ESI-MS). The alleles G and C were differentiated in 114 base pair amplicons on the basis of intact molecular mass measurements with a mass accuracy between 0.007 and 0.017%. The accuracy of mass determination was significantly reduced to less than 0.0036% upon amplification of a short, 61 bp fragment. The application of steep gradients of acetonitrile in 25 mM butyldimethylammonium bicarbonate not only enabled the efficient separation of non-target components from the PCR product in a monolithic, poly-(styrene-divinylbenzene)-based capillary column, but also allowed the high-throughput analysis of the PCR products with cycle times of 2 min. The new method was compared to a conventional restriction fragment length polymorphism assay with capillary gel electrophoretic analysis. In a blind study, 90 samples of unrelated individuals were genotyped. The high accuracy (<0.004%) and small relative standard deviation (<0.007%, n=20) of mass measurements, which enables even the differentiation of A and T alleles with a mass difference of 9 mass units, make IP-RP-HPLC-ESI-MS a potent tool for the routine characterization of SNPs in forensic science.

Mass spectrometry and tandem mass spectrometry, alone or after liquid chromatography, for analysis of polymerase chain reaction products in the detection of genomic variation

The availability of the sequences of entire bacterial and human genomes has opened up tremendous opportunities in biomedical research. The next stage in genomics will include utilizing this information to obtain a clearer understanding of molecular diversity among pathogens (helping improved identification and detection) and among normal and diseased people (e.g. aiding cancer diagnosis). To delineate such differences it may sometimes be necessary to sequence multiple representative genomes. However, often it may be adequate to delineate structural differences between genes among individuals. This may be readily achieved by high-throughput mass spectrometry analysis of polymerase chain reaction products.

Monolithic capillary columns for liquid chromatography-electrospray ionization mass spectrometry in proteomic and genomic research

Peptides, proteins, single-stranded oligonucleotides, and double-stranded DNA fragments were separated with high resolution in micropellicular, monolithic capillary columns prepared by in situ radical copolymerization of styrene and divinylbenzene. Miniaturized chromatography both in the reversed-phase and the ion-pair reversed-phase mode could be realized in the same capillary column because of the nonpolar character of the poly-(styrene/divinylbenzene) stationary phase. The high chromatographic performance of the monolithic stationary phase facilitated the generation of peak capacities for the biopolymers in the range of 50-140 within 10 min under gradient elution conditions. Employing volatile mobile phase components, separations in the two chromatographic separation modes were on-line hyphenated to electrospray ionization (tandem) mass spectrometry, which yielded intact accurate molecular masses as well as sequence information derived from collision-induced fragmentation. The inaccuracy of mass determination in a quadrupole ion trap mass spectrometer was in the range of 0.01-0.02% for proteins up to a molecular mass of 20000, and 0.02-0.12% for DNA fragments up to a molecular mass of 310000. High-performance liquid chromatography-electrospray ionization mass spectrometry utilizing monolithic capillary columns was applied to the identification of proteins by peptide mass fingerprinting, tandem mass spectrometric sequencing, or intact molecular mass determination, as well as to the accurate sizing of double-stranded DNA fragments ranging in size from 50 to 500 base pairs, and to the detection of sequence variations in DNA fragments amplified by the polymerase chain reaction.

Genotyping single nucleotide polymorphisms by mass spectrometry

In the last decade, the demand for high-throughput DNA analysis methods has dramatically increased, mainly due to the advent of the human genome sequencing project that is now nearing completion. Even though mass spectrometry did not contribute to that project, it is clear that it will have an important role in the post-genome sequencing era, in genomics and proteomics. In genomics, mainly matrix-assisted laser desorption/ionization (MALDI) mass spectrometry will contribute to large-scale single nucleotide polymorphism (SNP) genotyping projects. Here, the development and history of DNA analysis by mass spectrometry is reviewed and put into the context with the requirements of genomics. All major contributions to the field and their status and limitations are described in detail.

Re-sequencing of multiple single nucleotide polymorphisms by liquid chromatography-electrospray ionization mass spectrometry

Allelic discrimination of single nucleotide polymorphisms (SNPs) and, particularly, determination of the phase of multiple variations are of utmost importance in genetics. The physicochemical separation of alleles by completely denaturing ion-pair reversed-phase high-performance liquid chromatography and their on-line sequence determination by electrospray ionization mass spectrometry is demonstrated. Simultaneous genotyping of two and three simple sequence polymorphisms contained within 73-114 bp was accomplished with low femtomolar amounts of unpurified amplicons from polymerase chain reaction. Determination of allelic composition is enabled by the high accuracy (better than 0.019%) of intact mass measurements or by comparative sequencing using gas-phase fragmentation and tandem mass spectrometry in combination with fully automated, computer-aided data interpretation.

Multi-charged oligonucleotide ion formation in sonic spray ionization

An oligonucleotide tends to release hydrogen atoms from a phosphoric acid group and to form negative ions that can be detected by mass spectrometry. Usually, with a solution-spray based ionization technique, the negative ions are present in different charge states. Ion formation for the nucleotide is quite complicated and is easily influenced by matrix and other constituents in a sample solution, as well as by the operating parameters for a mass spectrometer. In this work, we studied oligonucleotide ion formation by using an ion trap mass spectrometer combined with a sonic spray ionization (SSI) source. An oligonucleotide with 20 bases was measured. Effects from contaminants and parameters affecting the ion production, such as a high voltage applied to the ionization source and sample solution-flow rate, were investigated. Our results showed that an ion with about one charge for every three bases was most abundant. However, the signal intensity and the mass spectrum pattern were sensitive to the matrix and operating parameters. One of the reasons for such sensitivity is that there are various ion states for an oligonucleotide. Any change in the matrix or an operating parameter may shift the balances between the ion states. Adding Tris, or (hydroxymethyl)aminomethane, enhanced the signal intensity of the oligonucleotide and promoted formation of the oligonucleotide ion with higher charges, while adding acetic acid favored the ions with lower charges, compared with that obtained in the medium without adding Tris and acetic acid. The effects on charged droplets and chemical enhancement were investigated. The mechanism for oligonucleotide ion formation is discussed.

Oligonucleotide mixture analysis via electrospray and ion/ion reactions in a quadrupole ion trap

Electrospray ionization combined with ion/ion reactions in a quadrupole ion trap can be used for the direct analysis of oligonucleotide mixtures. Elements to the success of this approach include factors related to ionization, ion/ion reactions, and mass analysis. This paper deals with issues regarding the ion polarity combination, viz., positive oligonucleotides/negative charge-transfer agent versus negative oligonucleotides/positive charge-transfer agent. Anions derived from perfluorocarbons appear to be directly applicable to mixtures of positive ions derived from electrospray of oligonucleotides, in direct analogy with positive protein ions. Conditions for forming positive oligonucleotide ions devoid of adducts were more difficult to establish than for forming relatively clean negative oligonucleotide ions. A new approach for manipulating negative ion charge states in the ion trap is described and is based on use of the electric field of the positive charge-transfer agent for storage of high-mass negative ions formed during the ion/ion reaction period. Oxygen cations are shown to be acceptable for charge-state manipulation of mixed-base oligomers but induce fragmentation in polyadenylate homopolymers. Protonated isobutylene (C4H9+), on the other hand, is shown to induce significantly less fragmentation of polyadenylate homopolymers.

Structural analysis of oligosaccharides by atmospheric pressure matrix-assisted laser desorption/ionisation quadrupole ion trap mass spectrometry

An ion source incorporating a fibre optic interface has been constructed for atmospheric pressure matrix-assisted laser desorption/ionisation quadrupole ion trap mass spectrometry. The configuration has been applied to the study of linear and complex oligosaccharides. Multi-stage tandem mass spectrometry (MSn, n = 2-4) experiments carried out in the ion trap enable extended fragmentation pathways to be investigated that yield structural information. Collisional activation of sodiated oligosaccharides, as demonstrated on the model compound maltoheptaose, produces primarily B and Y fragments resulting from cleavage of glycosidic bonds; fragments from cross-ring cleavages are also observed following further stages of tandem mass spectrometry, providing additional linkage information. The analyses of mixtures of complex oligosaccharides are demonstrated for N-linked glycans from chicken egg glycoproteins and a ribonuclease glycan mixture. Mass spectrometric and tandem mass spectrometric data for sugars with molecular weights up to 4000 Da is shown for mixtures of linear dextrans and N-linked glycans. The use of MSn (n = 3, 4) on these complex molecules enabled structural information to be elucidated that confirms data observed in the MS/MS spectra.

Comparative sequencing of nucleic acids by liquid chromatography-tandem mass spectrometry

An algorithm was developed for the computer-aided interpretation of fragment ion spectra from collision-induced dissociation of multiply charged oligodeoxynucleotide ions generated by electrospray ionization. The method compares the experimental spectrum to the m/z values predicted by employing established fragmentation pathways from a known reference sequence. The closeness of matching between the measured spectrum and the predicted set of fragment ions is characterized by the fitness, which takes into account the difference between measured and predicted m/z values, the intensity of the fragment ions, the number of fragments assigned, and the number of nucleotide positions not covered by fragment ions in the experimental spectrum. Smaller values for the fitness indicate a closer match between measured spectrum and predicted m/z values. To substantiate the identity of investigated sequence and reference sequence, or to identify point mutations or insertions/deletions, the reference sequence is systematically varied by incorporating all four possible nucleotides A, T, G, and C at each position in the sequence followed by identification of the correct sequence by the lowest fitness value. Collision energy was shown to have a major impact on the interpretability of the tandem mass spectra by the comparative sequencing algorithm, and the optimal collision energy depended on the length of the fragmented oligodeoxynucleotide. The analytical system was successfully applied to verify DNA sequences as well as to detect and localize point mutations or insertions/deletions in 5-51-mer oligodeoxynucleotides.

CEPH family 1362 STR database: an online resource for characterization of PCR products using electrospray ionization mass spectrometry

An online database has been established in order to validate electrospray ionization mass spectrometry (ESI-MS) for genotyping and to publicize the procedures developed in our laboratory for the characterization of PCR products by ESI-MS. Genotypes derived from short tandem repeat (STR) loci that were obtained using ESI Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS) have been posted for fifteen members of the CEPH family 1362 pedigree. The website provides specific information such as PCR parameters, PCR product cleanup approaches, and ESI solution compositions to enable other laboratories to reproduce our data. Links are provided to related websites in an effort to integrate information regarding the CEPH family, STR genotyping, and mass spectrometry. The database, currently available at http://www.people.vcu.edu/ -dcmuddim/genotype/ will be routinely updated with genotypes from additional STR loci including PCR parameters as well as PCR cleanup strategies as further developments are completed.

Electrospray ionization quadrupole time-of-flight mass spectrometry and quadrupole mass spectrometry for genotyping single nucleotide substitutions in intact polymerase chain reaction products in K-ras and p53

Single nucleotide polymorphisms (SNPs) and mutations were genotyped for both homozygous and heterozygous PCR products of p53, a tumor suppressor gene, and K-ras, an oncogene, using electrospray ionization (ESI) quadrupole time-of-flight (Q-TOF) mass spectrometry (MS) and ESI-quadrupole MS analysis. Mass accuracy was adequate for both instruments to detect genetic changes in homozygous PCR products, including the most difficult to distinguish (adenine [A] --> thymine [T] transversion). However, for the detection of A --> T shifts (9.0 Da difference) in heterozygous PCR products, the increased resolution of ESI-Q-TOFMS proved essential. Although, greater mass differences in heterozygotes (e.g. cytosine [C] <--> T or guanine [G] <--> A) can be discriminated using ESI-quadrupole MS analysis.

High-throughput biopolymer desalting by solid-phase extraction prior to mass spectrometric analysis

In the last 10 years mass spectrometry (MS) has become an important method for analysis of peptides, proteins and DNA. It was recently utilized for accurate high-throughput protein identification, sequencing and DNA genotyping. The presence of non-volatile buffers compromises sensitivity and accuracy of MS biopolymer analysis; it is essential to remove sample contaminants prior to analysis. We have developed a fast and efficient method for desalting of DNA oligonucleotides and peptides using 96-well solid-phase extraction plates packed with 5 mg of Waters Oasis HLB sorbent (Waters, Milford, MA, USA). This reversed-phase sorbent retains the biopolymer analytes, while non-retained inorganic ions are washed out with pure deionized water. DNA oligonucleotides or peptides are eluted using a small amount (20-100 microl) of acetonitrile-water (70:30, v/v) solution. The SPE desalting performance meets the requirements for MS applications such as protein digest analysis and DNA genotyping.

Factors determining the performance of triple quadrupole, quadrupole ion trap and sector field mass spectrometer in electrospray ionization mass spectrometry. 2. Suitability for de novo sequencing

The sequence coverage by fragment ions resulting from collision-induced dissociation in a triple stage quadrupole (TSQ) and a quadrupole ion trap (QIT) mass spectrometer of 10-20-mer oligonucleotides was investigated. While (a-B) and w ion series were the most abundant on both instruments, additional ion series of sequence relevance were preferably formed in the TSQ. Thus, a total number of 83 fragment ions were used to deduce the complete sequence of a 10-mer oligonucleotide of mixed sequence from a tandem mass spectrum recorded on the TSQ. The complete sequence was also encoded in the 28 fragments that were obtained from the QIT under comparable fragmentation conditions. Spectrum complexity increased considerably at the cost of signal-to-noise ratio upon fragmentation of a 20-mer oligonucleotide in the TSQ, whereas spectrum interpretation with longer oligonucleotides was significantly more straightforward in spectra recorded on the QIT. The extent of fragmentation had to be optimized by appropriate setting of collision energy and choice of precursor ion charge state in order to obtain full sequence coverage by fragments for de novo sequencing. Moreover, full sequence information was also dependent on base sequence because of the low tendency of backbone cleavage at thymidines. Tandem mass spectrometry on the QIT yielded redundant information that was successfully utilized to deduce the complete sequence of 20-mer oligonucleotides with high confidence.

Genotyping single nucleotide polymorphisms using intact polymerase chain reaction products by electrospray quadrupole mass spectrometry

Both single nucleotide polymorphisms (SNPs) and mutations are commonly observed in the gene encoding the tumor suppressor protein, p53. SNPs occur at specific locations within genes whereas mutations may be distributed across large regions of genes. When determining nucleotide differences, mass spectrometry is the only method other than Sanger sequencing which offers direct structural information. Electrospray ionization (ESI) quadrupole mass spectrometry (MS) analysis of intact polymerase chain reaction (PCR) products was performed following a simple purification and on-line heating to limit ion adduction. The PCR products were amplified directly from genomic DNA rather than plasmids, as in our previous work. Two known polymorphisms of the p53 gene were genotyped. A cytosine (C) or guanine (G) transversion, designated C <--> G (G <--> C on the opposite strand), were each detected by a 40.0 Da change upon ESI quadrupole MS analysis. Using known PCR products as standards, the genotypes determined for 10 human samples corresponded with restriction fragment length polymorphism (RFLP) analysis. Cytosine/thymine (T) transitions, designated C <--> T (G <--> A on the opposite strand), were also genotyped by ESI-MS. This SNP is discriminated by a 15.0 Da change on one strand (C <--> T) and a 16.0 Da change on the other (G <--> A). Appropriate sample preparation and instrumental configuration (including heated sample inlet syringe and MS source), to limit adducts, are both vital for successful ESI quadrupole MS analysis of intact PCR products.

Factors determining the performance of triple quadrupole, quadrupole ion trap and sector field mass spectrometers in electrospray ionization tandem mass spectrometry of oligonucleotides. 1. Comparison of performance characteristics

The performance of triple-stage quadrupole (TSQ), quadrupole ion trap (QIT), and double focusing sector field (DFSF) mass spectrometers for the generation of fragment ions to obtain sequence information about oligonucleotides was compared. Upon electrospray ionization (ESI), the charge-state distribution of candidate precursor ions not only varied significantly with the type of mass spectrometer, but also with the size and sequence of the investigated oligonucleotides. While concentration limits of detection for an octanucleotide were in the 100 pmol/L range on the QIT and in the 5-10 nmol/L range on the TSQ and DFSF instruments, those of a 24-mer were in the 2-13 nmol/L range on all three instruments. Reproducibility of mass determination, an important prerequisite for reliable identification of fragment ions, was highest on the TSQ with 0.0037% relative standard deviation over three days. Finally, the tandem mass spectra of a dimethoxytritylated pentanucleotide recorded on the three instruments were compared. Relatively simple spectra dominated by complete series of fragment ions of the (a-B) and w type were obtained on the QIT. Complete series of (a-B) and w ions were also observed on the TSQ. However, additional fragments belonging to the b, c, d, x and z series were found in the spectrum. In the spectrum recorded after in-source fragmentation in the DFSF, only fragments corresponding to the loss of a nucleobase and a complete series of w ions were observed. All three mass spectrometers were suitable for the generation of fragment ions, from which the complete nucleotide sequence of the pentanucleotide could be deduced.