Using immobilized enzymes to reduce RNase contamination in RNase mapping of transfer RNAs by mass spectrometry.

RNase (ribonuclease) mapping by nucleobase-specific endonucleases combined with mass spectrometry (MS) is a powerful analytical method for characterizing ribonucleic acids such as transfer RNAs. Typical free solution enzymatic digestion of RNA samples results in a significant amount of RNase being present in the sample solution analyzed by MS. In some cases, the RNase can lead to contamination of the high performance liquid chromatography and MS instrumentation. Here we investigate and compare several different approaches for reducing or eliminating contaminating RNase from the digested RNA sample before LC-MS analysis. Approaches using immobilized RNases were found to be most effective, with no enzyme carryover into the digested sample detected. Among the various options for immobilized RNases, we show that carbodiimide-based reactions can be used to couple RNases to carboxylic acid-terminated magnetic beads. The immobilized enzymes retain biological activity, are re-usable, and do not interfere with subsequent LC-MS analysis of the expected RNase digestion products. The use of immobilized RNases provides a simple approach for eliminating enzyme contamination in mass spectrometry-based RNase mapping experiments.

Relative quantitation of transfer RNAs using liquid chromatography mass spectrometry and signature digestion products.

Transfer ribonucleic acids (tRNAs) are challenging to identify and quantify from unseparated mixtures. Our lab previously developed the signature digestion approach for identifying tRNAs without specific separation. Here we describe the combination of relative quantification via enzyme-mediated isotope labeling with this signature digestion approach for the relative quantification of tRNAs. These quantitative signature digestion products were characterized using liquid chromatography mass spectrometry (LC-MS), and we find that up to 5-fold changes in tRNA abundance can be quantified from sub-microgram amounts of total tRNA. Quantitative tRNA signature digestion products must (i) incorporate an isotopic label during enzymatic digestion; (ii) have no m/z interferences from other signature digestion products in the sample and (iii) yield a linear response during LC-MS analysis. Under these experimental conditions, the RNase T1, A and U2 signature digestion products that potentially could be used for the relative quantification of Escherichia coli tRNAs were identified, and the linearity and sequence identify of RNase T1 signature digestion products were experimentally confirmed. These RNase T1 quantitative signature digestion products were then used in proof-of-principle experiments to quantify changes arising due to different culturing media to 17 tRNA families. This method enables new experiments where information regarding tRNA identity and changes in abundance are desired.

Agmatidine, a modified cytidine in the anticodon of archaeal tRNA(Ile), base pairs with adenosine but not with guanosine.

Modification of the cytidine in the first anticodon position of the AUA decoding tRNA(Ile) (tRNA2(Ile)) of bacteria and archaea is essential for this tRNA to read the isoleucine codon AUA and to differentiate between AUA and the methionine codon AUG. To identify the modified cytidine in archaea, we have purified this tRNA species from Haloarcula marismortui, established its codon reading properties, used liquid chromatography-mass spectrometry (LC-MS) to map RNase A and T1 digestion products onto the tRNA, and used LC-MS/MS to sequence the oligonucleotides in RNase A digests. These analyses revealed that the modification of cytidine in the anticodon of tRNA2(Ile) adds 112 mass units to its molecular mass and makes the glycosidic bond unusually labile during mass spectral analyses. Accurate mass LC-MS and LC-MS/MS analysis of total nucleoside digests of the tRNA2(Ile) demonstrated the absence in the modified cytidine of the C2-oxo group and its replacement by agmatine (decarboxy-arginine) through a secondary amine linkage. We propose the name agmatidine, abbreviation C(+), for this modified cytidine. Agmatidine is also present in Methanococcus maripaludis tRNA2(Ile) and in Sulfolobus solfataricus total tRNA, indicating its probable occurrence in the AUA decoding tRNA(Ile) of euryarchaea and crenarchaea. The identification of agmatidine shows that bacteria and archaea have developed very similar strategies for reading the isoleucine codon AUA while discriminating against the methionine codon AUG.

Minimizing 18O/16O back-exchange in the relative quantification of ribonucleic acids.

The use of isotopically labeled endonuclease digestion products allows for the relative quantification of ribonucleic acids (RNAs). This approach utilizes ribonucleases such as RNase T1 to mediate the incorporation of 18O onto the 3'-terminus of the endonuclease digestion product from a solution containing heavy water (H2 18O). The accuracy and precision of relative quantification are dependent on the efficiency of isotope incorporation and minimizing any possible 18O to 16O back-exchange before or during mass spectral analysis. Here, we have investigated the stability of 18O-labeled endonuclease digestion products to back-exchange. In particular, the effects of pH, temperature and presence of RNase on the back-exchange process were examined using matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). We have found that back-exchange depends on the presence of the RNase--back-exchange was not observed once the enzyme was removed from the sample. With RNase present, at all pH values examined (from acidic to basic pH), back-exchange was detected at incubation above room temperature. The rates and extent of back-exchange were similar at all pH values. In contrast, back-exchange in the presence of RNase was found to be especially sensitive to incubation temperature--at temperatures below room temperature, minimal back-exchange was detected. However, back-exchange increased as the incubation temperature increased. Based on these findings, appropriate sample-handling and sample storage conditions for isotopically labeled endonuclease digestion products have been identified, and these conditions should improve the accuracy and precision of results from the relative quantification of RNAs obtained by this approach.

Electrospray ionization mass spectrometry of oligonucleotides.

Because of the high molecular weights and thermal lability of biomolecules such as nucleic acids and protein, they can be difficult to analyze by mass spectrometry. Such analyses require a "soft" ionization method that is capable of generating intact molecular ions. In addition, most mass analyzers have a limited upper mass range that is not sufficient for studying these large molecules. ESI-MS can be used to analyze molecules with a molecular weight that is larger than the mass-to-charge ratio limit of the analyzer. This unit describes how ESI allows for analysis of high-molecular-weight compounds through the generation of multiply charged ions in the gas phase. It discusses analyzer configurations and solvent selection, and gives protocols for sample preparation. For applications of ESI-MS, the unit discusses molecular weight determination, sequencing, and analysis of oligonucleotide mixtures by LC-MS.

Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry of oligonucleotides.

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.