Genotyping of simple and compound short tandem repeat loci using electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry.

The utility of electrospray ionization Fourier transform ion cyclotron resonance (ESI-FIICR) mass spectrometry as a new approach for genotyping short tandem repeats (STRs) is demonstrated. STRs are currently valued as a powerful source of genetic information with repeats that range in structure from simple to hypervariable. Two tetranucleotide STR loci were chosen to evaluate ESI-FTICR mass spectrometry as a tool for genotyping: HUM-TH01, a simple STR with nonconsensus alleles, and vWA, a compound STR with nonconsensus alleles. For HUM-TH01, the genotype (i.e., repeat number of each allele) was determined for each of 30 individuals using mass measurements of double-stranded amplicons. Low-intensity peaks observed in the spectra of amplicons derived from heterozygous individuals were identified by mass as heteroduplexes that had formed between nonhomologous strands. Mass measurement of the double-stranded vWA amplicon was not sufficient for determining whether the individual was homozygous for allele subtype 18 or 18' since the amplicons differ by only 0.99 Da. Therefore, single-stranded amplicons were generated by incorporating a phosphorylated primer, prepared using T4 polynucleotide kinase, into the PCR phase and subsequently digesting the bottom strand using lambda-exonuclease. Accurate mass measurements were obtained for the single-stranded amplicons using internal calibration and the addition of a correction factor to adjust for the natural variation of isotopic abundances, confirming that the individual is homozygous for allele 18. Our results clearly demonstrate that ESI-FTICR mass spectrometry is a powerful approach to characterize both simple and compound STRs beyond the capabilities of electrophoretic technologies.

Perspectives on the use of electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry for short tandem repeat genotyping in the post-genome era.

The recent completion of the first rough draft of the human genome has provided fundamental information regarding our genetic make-up; however, the post-genome era will certainly require a host of new technologies to address complex biological questions. In particular, a rapid and accurate approach to characterize genetic markers, including short tandem repeats (STRs) and single nucleotide polymorphisms (SNPs) is demanded. STRs are the most informative of the two polymorphisms owing to their remarkable variability and even dispersity throughout eukaryotic genomes. Mass spectrometry is rapidly becoming a significant method in DNA analysis and has high probability of revolutionizing the way in which scientists probe the human genome. It is our responsibility as biomolecular mass spectrometrists to understand the issues in genetic analysis and the capabilities of mass spectrometry so that we may fulfill our role in developing a rapid, reliable technology to answer specific biological questions. This perspective is intended to familiarize the mass spectrometry community with modern genomics and to report on the current state of mass spectrometry, specifically electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry, for characterization of STRs.

Preparation of single-stranded PCR products for electrospray ionization mass spectrometry using the DNA repair enzyme lambda exonuclease.

Electrospray ionization mass spectrometry (ESI-MS) has been utilized to obtain accurate mass measurements of intact PCR products; however, single-stranded PCR products are necessary to detect sequence modifications such as base substitutions, additions or deletions. The locations of these modifications can subsequently be determined using additional stages of mass spectrometry. The recombinant enzyme lambda exonuclease selectively digests one strand of a DNA duplex from a 5' phosphorylated end leaving the complementary strand intact. Using this rapid enzymatic step, we were able to produce single-stranded PCR products by digestion of an intact PCR product derived from the Human Tyrosine Hydroxylase (HUMTHO1) gene, which contains a tetrameric repeating motif. The non-template directed 3' adenylation common when using Taq polymerase resulted in three distinct species (blunt-ended, mono-adenylated and di-adenylated), which added complexity to the spectrum of the double-stranded product. The data from the single-stranded products shows that one strand is preferentially adenylated over the other, which cannot be determined from the mass spectrum of the double-stranded PCR product alone. The ESI-FTICR (Fourier transform ion cyclotron resonance) mass spectra of the lambda exonuclease treated PCR products exhibited less than expected signal-to-noise (S/N) ratios. This is attributed to inaccurate concentration calculations due to remaining double-stranded PCR product amplified with unphosphorylated primers, and to matrix effects contributed by the lambda exonuclease reaction buffer. To further test this hypothesis, we investigated and determined the limit of detection to be 0.27 microM using standard curve statistics for single acquisitions of a synthetic 75-mer. The concentrations of the noncoding and coding strands produced by lambda exonuclease digestion were calculated to be 0.29 and 0.37 microM, respectively, taking into account the presence of double-stranded product. The products were electrosprayed from concentrations at the limit of detection requiring the averaging of 5-10 acquisitions to produce a sufficient S/N ratio, indicating that product concentration, base composition and matrix effects play a combined, significant role in detection of lambda exonuclease treated PCR products. Although additional work will be required to further exploit this strategy, lambda exonuclease clearly provides mass spectrometrists with a method to generate single-stranded PCR products.