Identification and typing of Francisella tularensis with a highly automated genotyping assay.

A PCR assay was developed to genotypically characterize Francisella tularensis and F. novicida. An integrated and partially redundant set of markers was selected to provide positive identification of these species, identify subspecies of F. tularensis and genotype 14 variable number tandem repeat (VNTR) markers. Assay performance was evaluated with 117 Francisella samples. Sample DNA was amplified, and the masses of the PCR products were determined with electrospray ionization/time of flight mass spectrometry (ESI-MS). The base compositions of the PCR amplicons were derived from these high-accuracy mass measurements and contrasted with databased information associated with each of the 25 assay markers. Species and subspecies determinations for all samples were fully concordant with results from established typing methods, and VNTR markers provided additional discrimination among samples. Sequence variants were observed with a number of assay markers, but these did not interfere with sample characterization, and served to increase the genetic diversity detected by the assay.

Identification of bacterial plant pathogens using multilocus polymerase chain reaction/electrospray ionization-mass spectrometry.

Polymerase chain reaction/electrospray ionization-mass spectrometry (PCR/ESI-MS, previously known as "TIGER") utilizes PCR with broad-range primers to amplify products from a wide array of organisms within a taxonomic group, followed by analysis of PCR amplicons using mass spectrometry. Computer analysis of precise masses allows for calculations of base compositions for the broad-range PCR products, which can then be compared to a database for identification. PCR/ESI-MS has the benefits of PCR in sensitivity and high-throughput capacity, but also has the distinct advantage of being able to detect and identify organisms with no prior characterization or sequence data. Existing broad range PCR primers, designed with an emphasis on human pathogens, were tested for their ability to amplify DNA of well characterized phytobacterial strains, as well as to populate the existing PCR/ESI-MS bacterial database with base counts. In a blinded panel study, PCR/ESI-MS successfully identified 93% of unknown bacterial DNAs to the genus level and 73% to the species/subspecies level. Additionally, PCR/ESI-MS was capable of detecting and identifying multiple bacteria within the same sample. The sensitivity of PCR/ESI-MS was consistent with other PCR based assays, and the specificity varied depending on the bacterial species. Preliminary tests with real life samples demonstrate a high potential for using PCR/ESI-MS systems for agricultural diagnostic applications.

An efficient synthesis of mimetics of neamine for RNA recognition.

As mimetics of neamine, several 4-heterocyclic 2-deoxystreptamine derivatives were chemically synthesized for RNA recognition. Conversion of 4-methylthiomethyl-5,6-di-O-acetyl-diazido-2-deoxystreptamine to the 4-chloromethyl derivative followed by reactions with different nuclophilic reagents gave the 4-heterocyclic 2-deoxystreptamine derivatives in satisfactory yields.

Measuring dissociation constants of RNA and aminoglycoside antibiotics by electrospray ionization mass spectrometry.

Electrospray ionization mass spectrometry (ESI-MS) has been used to determine the dissociation constants (K(D)s) and binding stoichiometry for tobramycin and paromomycin with a 27-nucleotide RNA construct representing the A-site of the 16S ribosomal RNA. K(D) values determined by holding the ligand concentration fixed are compared with K(D) values derived by holding the RNA target concentration fixed. Additionally, the effect of solution conditions such as the amount of organic solvent present and the amount of salt present in the solution on the K(D) measurement is investigated. It is shown that the preferred method for determining dissociation constants using ESI-MS is holding the RNA target concentration fixed below the expected K(D) and titrating the ligand. K(D) measurements should also be carried out at as high as possible salt concentration to minimize nonspecific binding due primarily to electrostatic interactions. For tobramycin, two nonequivalent binding sites were found with K(D1) = 352 nM and K(D2) = 9 microM. For paromomycin, there is only one binding site with K(D) = 52 nM.

Characterization of multipole storage assisted dissociation: implications for electrospray ionization mass spectrometry characterization of biomolecules.

Ions accumulated in an rf-only multipole for extended periods of time prior to mass analysis can experience a significant degree of fragmentation and produce mass spectra which do not reflect the true nature of the intact analyte(s). This phenomenon, termed multipole storage assisted dissociation (MSAD), places constraints on the maximum number of ions which can be accumulated in the multipole storage device as a result of its finite space charge limit. This phenomenon can be exploited to produce dissociation spectra that are dominated by fragment ions providing important sequence/structure information. In this work we further explore MSAD and characterize parameters including accumulation time, source pressure, and the electrostatic configuration of the multipole storage device, which mediate the phenomenon. Operating parameters are identified that can either enhance or eliminate the phenomenon.

Enhanced gas-phase hydrogen-deuterium exchange of oligonucleotide and protein ions stored in an external multipole ion reservoir.

Rapid gas-phase hydrogen-deuterium (H-D) exchange from D(2)O and ND(3) into oligonucleotide and protein ions was achieved during storage in a hexapole ion reservoir. Deuterated gas is introduced through a capillary line that discharges directly into the low-pressure region of the reservoir. Following exchange, the degree of H-D exchange is determined using Fourier transform ion cyclotron resonance mass spectrometry. Gas-phase H-D exchange experiments can be conducted more than 100 times faster than observed using conventional in-cell exchange protocols that require lower gas pressures and additional pump-down periods. The short experimental times facilitate the quantitation of the number of labile hydrogens for less reactive proteins and structured oligonucleotides. For ubiquitin, we observe approximately 65 H-D exchanges after 20 s. Exchange rates of > 250 hydrogens s(-1) are observed for oligonucleotide ions when D(2)O or ND(3) is admitted directly into the external ion reservoir owing to the high local pressure in the hexapole. Partially deuterated oligonucleotide ions have been fragmented in the reservoir using infrared multiphoton dissociation (IRMPD). The resulting fragment ions show that exchange predominates at charged sites on the 5'- and 3'-ends of the oligonucleotide, whereas exchange is slower in the core. This hardware configuration is independent of the mass detector and should be compatible with other mass spectrometric platforms including quadrupole ion trap and time-of-flight mass spectrometers.

Mass spectrometry as a drug discovery platform against RNA targets.

Mass spectrometry continues to play an increasingly important role in the drug discovery arena. In many drug discovery and biotechnology environments, mass spectrometry constitutes an integral component of the entire drug discovery and development process, from lead identification to quality control of bulk drug substance. Prominent among emerging drug discovery strategies are those which target cellular RNAs. Antisense drugs elicit a therapeutic response by hybridizing a synthetic oligonucleotide to a single stranded region of a target RNA; alternatively, highly structured regions of RNA represent an interesting class of drug target as the complex structural elements often comprise regulatory or functional domains where small molecules can bind with high affinity and specificity. In this paper, we review work performed within the last few years where mass spectrometry has been used to identify and study molecules that bind to RNA drug targets.

A gated-beam electrospray ionization source with an external ion reservoir. A new tool for the characterization of biomolecules using electrospray ionization mass spectrometry.

In this work we describe a micro-electrospray ionization source equipped with an atmospheric pressure external ion shutter. The solenoid-activated shutter prevents the electrospray plume from entering the inlet capillary unless triggered to the 'open' position. When in the 'closed' position, a stable electrospray plume is maintained between the electrospray ionization (ESI) emitter and the electrically isolated face of the shutter. When the shutter is triggered, a 'slice' of ions is allowed to enter the inlet capillary and is subsequently accumulated in an external ion reservoir comprised of a radio frequency only (rf-only) hexapole and a pair of electrostatic elements. Following ion accumulation in the external ion reservoir, intact molecular ions of proteins, oligonucleotides, and noncovalent complexes can be stored for extended intervals (>30 minutes) prior to being transferred to the Fourier transform ion cyclotron resonance (FTICR) trapped ion cell for mass analysis. By introducing reactive gases directly into the external ion reservoir during the storage interval, ion-molecule reactions, such as H/D exchange, can be performed at high effective pressures. This scheme obviates the need for the long reaction times and delays associated with restoring base pressure in the trapped ion cell and allows H/D exchange reactions to be conducted in a fraction of the time required using conventional in-cell exchange approaches. The back face of the shutter arm contains an elastomeric material which can be positioned to seal the inlet to the mass spectrometer resulting in lower base pressure in the ion reservoir and the FTICR cell. Additionally, it is noted that blocking the ESI plume during non-accumulation events results in reduced fouling of the source electrodes and longer times between required source cleaning.

Determinants of aminoglycoside-binding specificity for rRNA by using mass spectrometry.

We have developed methods for studying the interactions between small molecules and RNA and have applied them to characterize the binding of three classes of aminoglycoside antibiotics to ribosomal RNA subdomains. High-resolution MS was used to quantitatively identify the noncovalent binding interactions between mixtures of aminoglycosides and multiple RNA targets simultaneously. Signal overlap among RNA targets was avoided by the addition of neutral mass tags that direct each RNA target to a unique region of the spectrum. In addition to determining binding affinities, the locations of the binding sites on the RNAs were identified from a protection pattern generated by fragmenting the aminoglycoside/RNA complex. Specific complexes were observed for the prokaryotic rRNA A-site subdomain with ribostamycin, paromomycin, and lividomycin, whereas apramycin preferentially formed a complex with the eukaryotic subdomain. We show that differences in binding between paromomycin and ribostamycin can be probed by using an MS-MS protection assay. We have introduced specific base substitutions in the RNA models and have measured their impact on binding affinity and selectivity. The binding of apramycin to the prokaryotic subdomain strongly depends on the identity of position 1408, as evidenced by the selective increase in affinity for an A1408G mutant. An A1409-G1491 mismatch pair in the prokaryotic subdomain enhanced the binding of tobramycin and bekanamycin. These observations demonstrate the power of MS-based methods to provide molecular insights into small molecule/RNA interactions useful in the design of selective new antimicrobial drugs.

Multiplexed screening of neutral mass-tagged RNA targets against ligand libraries with electrospray ionization FTICR MS: a paradigm for high-throughput affinity screening.

We demonstrate that binding of mixtures of aminoglycosides can be measured simultaneously against multiple RNA targets of identical length and similar (or identical) molecular weight. Addition of a neutral mass tag to one of the RNA targets shifts the detected peaks to a higher mass/charge ratio, where complexes with small molecules can be identified unambiguously. An appropriately placed neutral mass tag does not alter RNA--ligand binding. The utility of this strategy is demonstrated with model RNAs corresponding to the decoding region of the prokaryotic and eukaryotic rRNAs and a mixture of five aminoglycosides. Complexes are observed between the aminoglycoside library and the prokaryotic rRNA model, while no aminoglycoside was observed to bind to the mass-tagged eukaryotic rRNA model. The differential binding data is consistent with the eukaryotic A-site rRNA having a different conformation compared with the prokaryotic A-site that prevents entry and binding of neomycin-class aminoglycosides. Mass spectrometric analysis of neutral mass-tagged macromolecular targets represents a new high-throughput screening paradigm in which the interaction of multiple targets against a collection of small molecules can be evaluated in parallel.

Infrared multiphoton dissociation in an external ion reservoir.

In this work we present a novel scheme for performing infrared multiphoton dissociation (IRMPD) external to the mass analyzer in an external ion reservoir consisting of an rf-only multipole and a pair of electrostatic lens elements. Ions generated by electrospray ionization (ESI) are accumulated in an rf-only hexapole and dissociated by irradiation at 10.6 microns from a CW CO2 laser in the source region of the mass spectrometer. This scheme is unique from other IRMPD schemes as dissociation occurs in a spatially distinct region of the spectrometer and is independent of the mass spectrometry platform used to analyze the fragment ions. The effectiveness of the technique is demonstrated with ESI IRMPD FTICR mass spectrometry of a 20-mer phosphorothioate oligonucleotide. A comparison of the external IRMPD scheme with nozzle-skimmer dissociation and conventional in-cell IRMPD reveals a significant improvement in signal-to-noise ratio and fragment yield, particularly for larger, more highly charged fragment ions.

Characterization of microdialysis acidification for capillary isoelectric focusing-microelectrospray ionization mass spectrometry.

A microdialysis junction, based on a microdialysis membrane connecting a separation capillary and a short, sharply tapered microelectrospray emitter capillary, is demonstrated for on-line combination of capillary isoelectric focusing (CIEF) with electrospray ionization mass spectrometry (ESI-MS). The microdialysis junction provides the necessary electrical connection across the dialysis membrane for defining the electric fields needed for the CIEF separation and the electrospray process. Additionally, postseparation acidification of focused protein zones eluted from the CIEF capillary is achieved using the microdialysis junction while separation efficiency and resolution is maintained. A microelectrospray emitter produces a stable electrospray of protein analytes without the need for a makeup liquid flow and eliminates any subsequent sample dilution and reduction in MS sensitivity. The microdialysis junction is advantageous over the coaxial liquid sheath interface as evidenced by the simplicity in operation procedures, the enhancement in detection sensitivity, and the linear correlation between protein migration time and isoelectric point in CIEF-ESI-MS.

Multipole storage assisted dissociation, a novel in-source dissociation technique for electrospray ionization generated ions.

In this work we present a novel in-source dissociation scheme referred to as multipole storage assisted dissociation (MSAD) for electrospray ionization (ESI) generated ions in which dissociation is effected by employing extended ion accumulation intervals in a high pressure rf-only hexapole assembly prior to mass analysis. Following an extended ion accumulation interval in which ions are confined in the rf-only hexapole, ions are gated out of the hexapole, trapped, and mass analyzed in the trapped ion cell of a Fourier transform ion cyclotron resonance (FTICR) mass spectrometer. The accumulation region is comprised of an rf-only hexapole ion guide which separates two electrodes, a biased skimmer cone, and an auxiliary 'gate' electrode at the low pressure end of the hexapole. This technique should be applicable to other mass spectrometry platforms compatible with pulsed ionization sources including quadrupole ion traps, and time-of-flight mass analyzers. This concept is demonstrated with the dissociation of a small protein in which selective fragmentation is observed at labile amino acid linkages producing primarily y-type fragment ions.

Probing RegA/RNA interactions using electrospray ionization-fourier transform ion cyclotron resonance-mass spectrometry.

The interactions of bacteriophage T4 regA protein, a unique translational regulator, with RNAs of various size and sequence were studied using electrospray ionization-Fourier transform ion cyclotron resonance-mass spectrometry. Using very gentle interface conditions, regA/RNA complexes with a 1:1 binding stoichiometry were observed for all four target RNAs studied, consistent with solution binding studies. Competitive binding of target RNAs and their degradation products with regA demonstrated that the loss of a single nucleotide resulted in a dramatic change in binding affinity in some cases. Competitive binding of regA with four target RNAs revealed similar relative binding affinity order to that suggested by previous in vitro repression experiments. The use of sustained off-resonance irradiation for collisionally induced dissociation of a regA/RNA complex suggested the potential for directly obtaining information regarding the regA binding domain.

A microfabricated dialysis device for sample cleanup in electrospray ionization mass spectrometry.

A laser microfabricated device was constructed for rapid microdialysis cleanup of biological samples for analysis by electrospray ionization mass spectrometry (ESI-MS) in both off-line and on-line modes. A microdialysis membrane was sandwiched between two chips having micromachined serpentine channels. The total volume of the sample serpentine channel used for the microdialysis was 1 microL. Efficient desalting was demonstrated for both DNA and protein samples using ESI with an ion trap mass spectrometer after microdialysis against a counter flow of ESI-compatible buffer. Signal-to-noise ratios were also greatly enhanced compared to direct infusion of the original nondialyzed samples. Importantly, the microfabricated device allowed use of sample flow rates 1 order of magnitude smaller than previous designs based on a microdialysis fiber, allowing reduced sample utilization and improved sensitivity with ESI-MS. The effectiveness of the cleanup was attributed to the size difference between the sample channel and the buffer channel and the fact that the sample is continuously refreshed by the buffer counterflow. The results indicate substantial potential for construction of highly compact and rugged devices enabling field applications of ESI-MS.

On-line dual microdialysis with ESI-MS for direct analysis of complex biological samples and microorganism lysates.

A novel dual-microdialysis approach has been developed for fast and efficient fractionation and cleanup for ESI-MS and ESI MS/MS analyses of biological samples. A modified dynamic microdialyzer utilizing two mirror-image serpentine channels, which sandwich a regenerated cellulose membrane of selected molecular weight cutoff, serves as the first stage for the removal of high-molecular-weight components and cellular residue. The second stage employs a hollow microdialysis capillary to remove low-molecular-weight species (e.g., salts) which can degrade or preclude analysis ESI-MS. A protein mixture consisting of 30 microM bovine serum albumin (BSA), 4.0 microM cytochrome c, 2.3 microM ubiquitin, and 9.4 microM bradykinin in 0.5 M NaCl was used to evaluate the performance of this system. Essentially complete removal of both BSA and NaCl was achieved, resulting in high-quality mass spectra containing only the lower molecular weight proteins. After passing through the on-line dual-microdialysis system, a crude bacteria cell lysate yielded clean ESI-mass spectra in approximately 20 min. MS/MS of selected ions demonstrated abundant fragment ions and provided a second-dimension "fingerprint" of the complex cellular fraction. Preliminary application of this technique for direct characterization of microorganism lysates is presented.

Capillary isoelectric focusing-electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry for protein characterization.

On-line combination of capillary isoelectric focusing (CIEF) with electrospray ionization Fourier transform ion cyclotron resonance (ESI-FTICR) mass spectrometry is demonstrated for high-resolution analysis of model proteins, human hemoglobin variants, and Escherichia coli proteins. The acquisition of high-resolution mass spectra of hemoglobin beta chains allows direct identification of hemoglobin variants A and C, differing in molecular mass by 1 Da. Direct mass determination of cellular proteins separated in the CIEF capillary is achieved using their isotopic envelopes obtained from ESI-FTICR. The factors which dictate overall performance of CIEF-ESI-FTICR, including duty cycle, mass resolution, scan rate, and sensitivity, are discussed in the context of protein variants and cell lysates analyzed in this study.

Electrospray ionization-Fourier transform ion cyclotron resonance mass spectrometry at 11.5 tesla: instrument design and initial results.

Initial results obtained using a new electrospray ionization (ESI) Fourier transform ion cyclotron resonance (FTICR) mass spectrometer operated at a magnetic field 11.5 tesla are presented. The new instrument utilized an electrostatic ion guide between the ESI source and FTICR trap that provided up to 5% overall transmission efficiency for light ions and up to 30% efficiency for heavier biomolecules. The higher magnetic field in combination with an enlarged FTICR ion trap made it possible to substantially improve resolving power and operate in a more robust fashion for large biopolymers compared to lower field instruments. Mass resolution up to 10(6) has been achieved for intermediate size biopolymers such as bovine ubiquitin (8.6 kDa) and bovine cytochrome c (12.4 kDa) without the use of frequency drift correction methods. A mass resolution of 370,000 has been demonstrated for isotopically resolved molecular ions of bovine serum albumin (66.5 kDa). Comparative measurements were made with the same spectrometer using a lower field 3.5-tesla magnet allowing the performance gains to be more readily quantified. Further improvements in pumping capacity of the vacuum system and efficiency of ion transmission from the source are expected to lead to further substantial sensitivity gains.

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.