Detection of delta F508 mutation of the cystic fibrosis gene by matrix-assisted laser desorption/ionization mass spectrometry

Ionic liquid-assisted electrospray ionization of polysaccharides

In this work, we give the report of significant detection sensitivity improvement of electrospray ionization (ESI) mass spectra of polysaccharides by adding various ionic liquid compounds into samples. Mass spectra obtained were greatly simplified and appeared to be similar to spectra from matrix-assisted laser desorption/ionization due to the narrow charge number distribution. Mass spectra of polysaccharides with the attachment of either anion or cation of ionic liquid compounds were observed. No protonated or deprotonated polysaccharide ions were detected when ionic liquid compounds were added into samples. Little alkali-attached polysaccharide ions were observed. Ionic liquid-assisted ESI (ILA-ESI) mass spectrometry has significantly improved the detection sensitivity of large neutral polysaccharide compounds.

Review of a current role of mass spectrometry for proteome research

This review is intended to give readers a snapshot of current mass spectrometry for proteomics research. It covers a brief history of mass spectrometry proteomic research, peptidomics and proteomics for biomarker search, quantitative proteomics, proteomics with post-translational modification and future perspective of proteomics.

Analysis of oligonucleotides by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

MALDI-MS is one of the most useful techniques available for determining biomolecule mass. It offers high mass accuracy, good sensitivity, simplicity, and speed. Because singly charged ions of oligonucleotides are typically observed, MALDI-MS spectra are easy to interpret. This unit presents protocols for sample preparation and purification, matrix preparation, and matrix/analyte sample preparation. It provides an introduction to the instrumentation and its calibration, and a discussion of some of the useful applications of MALDI-MS analysis in the study of oligonucleotides. This technique is typically used for 120-mer or smaller oligonucleotides.

Matrix-assisted laser desorption/ionization (MALDI) mechanism revisited

Although matrix-assisted laser desorption/ionization (MALDI) was developed more than a decade ago and broad applications have been successfully demonstrated, detailed mechanism of MALDI is still not well understood. Two major models; namely photochemical ionization (PI) and cluster ionization (CI) mechanisms have been proposed to explain many of experimental results. With the photochemical ionization model, analyte ions are considered to be produced from a protonation or deprotonation process involving an analyte molecule colliding with a matrix ion in the gas phase. With the cluster ionization model, charged particles are desorbed with a strong photoabsorption by matrix molecules. Analyte ions are subsequently produced by desolvation of matrix from cluster ions. Nevertheless, many observations still cannot be explained by these two models. In this work, we consider a pseudo proton transfer process during crystallization as a primary mechanism for producing analyte ions in MALDI. We propose an energy transfer induced disproportionation (ETID) model to explain the observation of an equal amount of positive and negative ions produced in MALDI for large biomolecules. Some experimental results are used for comparisons of various models.

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.

Fragmentation pathway studies of oligonucleotides in matrix-assisted laser desorption/ionization mass spectrometry by charge tagging and H/D exchange

The desorption and decompositions of synthesized oligonucleotides bearing fixed charge sites have been investigated by linear, delayed-extraction, reflecting and post-source decay mode matrix-assisted laser desorption/ionization (MALDI) mass spectrometry. In contrast to the conventional [M + H]+ forms of unmodified molecules where a proton is likely attached to a nucleobase, here the charge is fixed at one of the termini. In this case the observed fragment ions always incorporate the charge-tag. H/D exchange experiments provide no evidence for intramolecular migration of protons on the phosphate backbone to initiate the fragmentation event. New unique pathways of proton migration from the ribose have been elucidated and are rationalized by a charge-remote fragmentation pathway.

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.

Laser desorption mass spectrometry for microbial DNA analysis

Recently, we demonstrated that a matrix-assisted laser desorption/ionization time-of-flight mass spectrometer (MALDI-TOF MS) can be used to determine the molecular weight of polymerase chain reaction (PCR) products of intact 16S rRNA regions and to profile their restriction digests. This is the first time that MALDI-TOF MS with ultraviolet (UV) photoionization has been used to analyze a PCR product of approximately 1600 nucleotides in length.

Sugar additives for MALDI matrices improve signal allowing the smallest nucleotide change (A:T) in a DNA sequence to be resolved

Sample preparation for matrix-assisted laser desorption/ionization (MALDI) mass spectrometry (MS) of DNA is critical for obtaining high quality mass spectra. Sample impurity, solvent content, substrate surface and environmental conditions (temperature and humidity) all affect the rate of matrix-analyte co-crystallization. As a result, laser fluence threshold for desorption/ionization varies from spot to spot. When using 3-hydroxypicolinic acid (3-HPA) as the matrix, laser fluence higher than the threshold value reduces mass resolution in time-of-flight (TOF) MS as the excess energy transferred to DNA causes metastable decay. This can be overcome by either searching for 'hot' spots or adjusting the laser fluence. However, both solutions may require a significant amount of operator manipulation and are not ideal for automatic measurements. We have added various sugars for crystallization with the matrix to minimize the transfer of excess laser energy to DNA molecules. Fructose and fucose were found to be the most effective matrix additives. Using these additives, mass resolution for DNA molecules does not show noticeable deterioration as laser energy increases. Improved sample preparation is important for the detection of single nucleotide polymorphisms (SNPs) using primer extension with a single nucleotide. During automatic data acquisition it is difficult to routinely detect heterozygous A/T mutations, which requires resolving a mass difference of 9 Da, unless a sugar is added during crystallization.

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.

Precise molecular weight determination of PCR products of the rRNA intergenic spacer region using electrospray quadrupole mass spectrometry for differentiation of B. subtilis and B. atrophaeus, closely related species of bacilli

Assessment of 16S-23S rRNA intergenic spacer region (ISR) sequence variability is an important supplement to 16S rRNA sequencing for differentiating closely related bacterial species. Species differentiation can also be achieved by determination of approximate size of PCR (polymerase chain reaction) products of ISRs, based on their relative electrophoretic mobility on agarose gels. Closely-related species can have ISR PCR products that are similar in size. More precise molecular weight (M.W.) determination of these products might allow improved discrimination of such species. Electrospray quadrupole mass spectrometry (ESI-Q-MS) has the potential to provide such precision. For ESI-Q-MS analysis, size limitation of PCR products is currently limited to around 130 base pairs (bp). Bacillus subtilis and Bacillus atrophaeus are two closely related species with few distinguishing phenotypic characteristics. B. subtilis has recently been sub-divided into two subgroups, W23 (type strain, W23) and 168 (type strain, 168). PCR products amplified from the ISR including the 5' terminal end of the 23S rRNA and a conserved portion of the ISR were analyzed by ESI-Q-MS. A 119 or 120 bp PCR product was produced for B. atrophaeus strains. However, strains of B. subtilis subgroups W23 and 168 each produced 114 bp products. In summary, a mass spectrometry method was developed for differentiation of B. subtilis and B. atrophaeus. Also, the genetic similarity of B. subtilis subgroups W23 and 168 was confirmed. Accurate determination of the molecular weight of PCR products from the 16S-23S rRNA intergenic spacer region using electrospray quadrupole mass spectrometry has great potential as a general technique for characterizing closely related bacterial species.

A novel procedure for efficient genotyping of single nucleotide polymorphisms

Due to the surge in interest in using single nucleotide polymorphisms (SNPs) for genotyping a facile and affordable method for this is an absolute necessity. Here we introduce a procedure that combines an easily automatable single tube sample preparation with an efficient high throughput mass spectrometric analysis technique. Known point mutations or single nucleotide polymorphisms are easily analysed by this procedure. It starts with PCR amplification of a short stretch of genomic DNA, for example an exon of a gene containing a SNP. By shrimp alkaline phosphatase digest residual dNTPs are destroyed. Allele-specific products are generated using a special primer, a conditioned set of alpha-S-dNTPs and alpha-S-ddNTPs and a fresh DNA polymerase in a primer extension reaction. Unmodified DNA is removed by 5'-phospho-diesterase digestion and the modified products are alkylated to increase the detection sensitivity in the mass spectrometric analysis. All steps of the preparation are simple additions of solutions and incubations. The procedure operates at the lowest practical sample volumes and in contrast to other genotyping protocols with mass spectrometric detection requires no purification. This reduces the cost and makes it easy to implement. Here it is demonstrated in a version using positive ion detection on described mutations in exon 17 of the amyloid precursor protein gene and in a version using negative ion detection on three SNPs of the granulocyte-macrophage colony stimulating factor gene. Preparation and analysis of SNPs is shown separately and simultaneously, thus demonstrating the multiplexibility of this genotyping procedure. The preparation protocol for genotyping is adapted to the conditions used for the SNP discovery method by denaturing HPLC, thus demonstrating a facile link between protocols for SNP discovery and SNP genotyping. Results corresponded unanimously with the control sequencing. The procedure is useful for high throughput genotyping as it is required for gene identification and pharmacogenomics where large numbers of DNA samples have to be analysed. We have named this procedure the 'GOOD Assay' for SNP analysis.

Analysis of single nucleotide polymorphisms by primer extension and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

A method for typing single nucleotide polymorphisms (SNPs) by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS) is described, in which a mass-tagged dideoxynucleoside triphosphate is employed in a primer extension reaction in place of an unmodified dideoxynucleoside triphosphate (ddNTP). The increased mass difference due to the presence of the mass-tag greatly facilitates the accurate identification of the added nucleotide, and is particularly useful for typing heterozygous samples. Twenty commercially available mass-tagged dideoxynucleoside triphosphates were screened for amenability to incorporation by AmpliTaq FS and ThermoSequenase DNA polymerases in single nucleotide primer extension (SNuPE) reactions. Several sample preparation and purification methods were also examined and compared. Float dialysis was found to be a simple, versatile, and effective method for purification of the extension products. High specificity and sensitivity were obtained, and all six possible biallelic SNP heterozygotes were determined accurately using a 44-mer synthetic oligonucleotide target DNA as a model system. Further validation of the method was demonstrated in the analysis of five single-base mutations in exon IV of the human tyrosinase gene. Single nucleotide variations within 182-bp PCR amplicons amplified from three plasmid and three human genomic DNA samples were genotyped at five variable positions, with results in 100% concordance with conventional sequencing. Genotypes were determined accurately at five sequence-tagged sites (STSs).

Measurement of polymorphic trinucleotide repeats in the androgen receptor gene by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

Trinucleotide repeats are polymorphic in normal individuals. CAG repeats in the X-linked androgen receptor gene were counted by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI/TOF-MS). A region of approximately two hundred base-pairs containing the repeats was amplified by polymerase chain reaction, then measured after a simple purification procedure. The single-charged molecular ion species was detected using 0.1 pmol of DNA sample and the number of repeats was determined from the molecular mass. The results indicated that MALDI/TOF-MS is a high-throughput alternative to polyacrylamide gel electrophoresis for precise determination of polymorphic trinucleotide repeats.

Electrospray quadrupole mass spectrometry analysis of model oligonucleotides and polymerase chain reaction products: determination of base substitutions, nucleotide additions/deletions, and chemical modifications

ESI FTICR mass spectrometry is the only technique currently used for accurate molecular weight analysis of PCR products above 100 bp in size. This is important in demonstrating the potential for MS in making major contributions in the molecular biology and genomics areas. In the near future, it is more likely that less expensive, more user friendly MS techniques will be used for high-throughput analyses (including MALDI TOF and ESI quadrupole). There have been numerous reports on the use of MALDI TOF. The current report is to the first to evaluate the use of ESI-quadrupole analysis of PCR products. Synthetic oligonucleotides (30 and 89 mers) and polymerase chain reaction products of varying molecular weight (62, 88, 89, and 114 bp) were analyzed by ESI using a quadrupole MS. The mass accuracy for nucleic acids in the 30-62 bp range was shown to allow determination of nucleotide substitutions and additions/deletions. For higher molecular weight PCR products (88-114 bp), the mass accuracy of ESI-MS distinguishes single or multiple nucleotide insertions/deletions. In addition, ESI quadrupole MS allows determination of molecular weight of both strands of higher molecular weight ds PCR products and can distinguish nucleotide modifications (e.g., with biotin). In conclusion, it is demonstrated that ESI-MS occupies an intermediate position (as compared to MALDI TOF and ESI FTICR) with regard to mass accuracy and resolution in analysis of nucleic acids.

Detection of trinucleotide expansion in neurodegenerative disease by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

Genotyping of the dentatorubral-pallidoluysian atrophy (DRPLA) locus in six patient samples, representing four normal individuals and two DRPLA patients, was successfully obtained using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS). DRPLA is a dominantly inherited neurodegenerative disorder associated with the expansion of an unstable trinucleotide (CAG) repeat. The accurate determination of repeat length utilizing MALDI supports the use of this methodology for the analysis of genes containing unstable CAG trinucleotide repeats.

Accurate characterization of the tyrosine hydroxylase forensic allele 9.3 through development of electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry

Accurate and precise determination of the number of repeats from a short tandem repeat (STR) sequence for a human gene locus is demonstrated for the first time by electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry (ESI-FTICR-MS). Specifically, the polymorphic human tyrosine hydroxylase (HUMTHO1) gene, a tetranucleotide STR forensic allele, was chosen as a model system to evaluate our approach for future characterization of both STRs and variable number of tandem repeats (VNTRs) by development of an ESI-FTICR-MS approach. The coding and noncoding strands from the HUMTHO1 9.3 allele are simultaneously resolved obtaining accurate (better than 70 ppm) average mass measurements of 25,783.23 and 24,754.55 Da for the coding and noncoding strands, respectively. The mass measurements are used to calculate the number of repeats for each strand, 'n', of 9.75169 and 9.75001 for the coding and noncoding strands, respectively. It will be shown how the value of 'n' can be used to directly determine the number of pure repeats and accurately determine the exact nature of the polymorphism within the repeat (if any). The single nucleotide deletion in the coding strand (adenine) and noncoding strand (thymine) were accurately identified using this approach. Interestingly, we observed the conversion of single-stranded to double-stranded DNA while the PCR product in the ESI buffer was being infused; the issues related to this observation will be presented. Previous results by other researchers investigating the HUMTHO1 9.3 allele using matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) are directly compared with our results. Our results indicate that ESI-FTICR-MS is a powerful approach to rapidly and accurately characterize tandem repeating sequences which will ultimately lead towards the understanding of a complex class of diseases and in human identity determination.

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.

Genotyping by mass spectrometric analysis of short DNA fragments

A method has been developed to produce small DNA fragments from PCR products for analysis of defined DNA variations by mass spectrometry. The genomic region to be analyzed is PCR-amplified with primers containing a sequence for the type IIS restriction endonuclease Bpml. Bpml digestion of the resultant PCR products yields fragments as small as seven bases, which are then analyzed by electrospray ionization mass spectrometry. The approach was validated using seven different variants within the APC tumor suppressor gene, in which a perfect correlation was obtained with DNA sequencing. Both the sense and antisense strands were analyzed independently, and several variants can be analyzed simultaneously. These results provide the basis for a generally applicable and highly accurate method that directly queries the mass of variant DNA sequences.

Heterogeneity in Bacillus cereus PCR products detected by ESI-FTICR mass spectrometry

PCR amplification of a segment of the 16/23S rDNA interspace region (ISR) from Bacillus cereus 6464 produced a mixture of products. An 89-bp product was predicted on the basis of the reported sequence. The ESI-FTICR analysis revealed three double-stranded products, differing in size by a single nucleotide corresponding to two homoduplexes of 89 and 88 base pairs and a heteroduplex of 89 and 88 nucleotide strands. These were produced from a single preparation of genomic DNA and a single primer pair. ESI-FTICR analysis of the single strands identified a deletion of a T in the coding strand and a corresponding loss of an A in the noncoding strand of this product. The ESI-FTICR analysis indicated the presence of an unreported sequence variation between rRNA operons in this organism. This report illustrates that PCR products amplified from templates differing by a single nucleotide can be resolved and identified using ESI-FTICR at the 89-bp level. Furthermore, the ESI-FTICR mass measurements provided the identity of the deletion, which is indicative of interoperon variability.

Application of nested PCR and mass spectrometry for DNA-based virus detection: HBV-DNA detected in the majority of isolated anti-HBc positive sera

DNA preparations from three different groups of serum samples were examined for HBV-DNA via a nested polymerase chain reaction assay (lower detection limit: 10 viral genomes in 100 microliters serum): Group I consisted of 11 uninfected control sera, group II consisted of sera obtained from 11 HBV infected patients and group III consisted of 21 isolated anti-HBc positive samples. The 21 samples from group III were HBV-DNA negative according to a conventional non-nested PCR assay and hybridization with a 32P-labelled probe. Using nested PCR and mass spectrometry, HBV-DNA was detected in none of group I and in all of group II samples. In 11 out of 21 (52%) of the isolated anti-HBc positive sera from group III, HBV-DNA was detected. No correlation was observed between HBV-DNA positivity and anti-HBc titers. Matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry provided a fast, sensitive and non-radioactive assay for the detection of PCR products without the need for gel electrophoresis or hybridization with labelled probes.

Discrimination of single-nucleotide polymorphisms in human DNA using peptide nucleic acid probes detected by MALDI-TOF mass spectrometry

Human genomic and mitochondrial DNA contain large numbers of single-nucleotide polymorphisms (SNPs), many of which are linked to known diseases. Rapid and accurate genetic screening for important SNPs requires a general methodology which is easily implemented. We present here an approach to SNP discrimination based on high-specificity hybridization of peptide nucleic acid (PNA) probes to PCR-amplified DNA. The assay is directly applied to polymorphisms located within hypervariable region 1 of the human mitochondrial genome and type 1 suballeles of the human leukocyte antigen DQ alpha gene. Captured, single-stranded DNA molecules prepared by PCR amplification are hybridized with PNA probes in an allele-specific fashion. Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS) is then used for rapid, precise, and unambiguous detection and identification of the hybridized PNA probes. Since PNA oligomers bind strongly to complementary DNA under minimal salt conditions, the use of PNA probes is compatible with MALDI-TOFMS. The unparalleled ability of MALDI-TOFMS analysis in terms of molecular weight resolution and accuracy, in conjunction with the highly specific PNA hybridization afforded by this method, offers promise for development into a multiplexed, high-throughput screening technique.

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.

Length and base composition of PCR-amplified nucleic acids using mass measurements from electrospray ionization mass spectrometry

A generally applicable algorithm has been developed to allow base composition of polymerase chain reaction (PCR) products to be determined from mass spectrometrically measured molecular weights and the complementary nature of DNA. Mass measurements of arbitrary precision for single-stranded DNA species are compatible with an increasingly large number of possible base compositions as molecular weight increases. For example, the number of base compositions that are consistent with a molecular weight of 35,000 is approximately 6000, based on a mass measurement precision of 0.01%. However, given the low misincorporation rate of standard DNA polymerases, mass measurement of both of the complementary single strands produced in the PCR reduces the number of possibilities to less than 100 at 0.01% mass precision, and base composition is uniquely defined at 0.001% mass precision. Taking into account the low misincorporation rate of standard DNA polymerases and the fact that the final PCR product also contains primers of known sequence (generally 15-20-mer in size, which flank the targeted region), this reduces the number of possible base combinations to only approximately 3 at MW = 35,000. In addition, the number of base pairs (i.e., length of the DNA molecule) is uniquely defined. We show that the use of modified bases in PCR or post-PCR modification chemistry allows unique solutions for the base composition of the PCR product with only modest mass measurement precision.

Laser desorption mass spectrometry for point mutation detection

A point mutation can be associated with the pathogenesis of inherited or acquired diseases. Laser desorption mass spectrometry coupled with allele specific polymerase chain reaction (PCR) was first used for point mutation detection. G551D is one of several mutations of the cystic fibrosis transmembrane conductance regulator (CFTR) gene present in 1-3% of the mutant CFTR alleles in most European populations. In this work, two different approaches were pursued to detect G551D point mutation in the cystic fibrosis gene. The strategy is to amplify the desired region of DNA template by PCR using two primers that overlap one base at the site of the point mutation and which vary in size. If the two primers based on the normal sequence match the target DNA sequence, a normal PCR product will be produced. However, if the alternately sized primers that match the mutant sequence recognize the target DNA, an abnormal PCR product will be produced. Thus, the mass spectrometer can be used to identify patients that are homozygous normal, heterozygous for a mutation or homozygous abnormal at a mutation site. Another approach to identify similar mutations is the use of sequence specific restriction enzymes which respond to changes in the DNA sequence. Mass spectrometry is used to detect the length of the restriction fragments generated by digestion of a PCR generated target fragment.

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.