Correlation between Sweet Spots of Glycopeptides and Polymorphism of the Matrix Crystal in MALDI Samples.

A standard dried-droplet preparation using 2,5-dihydroxybenzoic acid (2,5-DHBA) as the matrix results in a large variation in signal intensity and poor shot-to-shot reproducibility in matrix-assisted laser desorption/ionization (MALDI). We expected that the differences can be attributed to the nature of the crystal structures in the region of the "sweet spot" within the MALDI samples. 2,5-DHBA crystals with and without analytes on a target plate obtained by means of a dried-droplet preparation contain two polymorphs, which can be distinguished by Raman spectra. In comparing the Raman image with the MS image, a clear correlation between the signal distribution of glycopeptides and hydrophilic peptides and the specific crystal form of 2,5-DHBA could be made. The ionization of hydrophobic peptides appears to proceed in both types of polymorphic crystals. In addition, the derivatization of glycopeptides with a pyrene group enabled us to detect glycopeptides regardless the crystal form. As the result, the number of sweet spots increased and MS spectra with a high signal intensity were obtained. The results suggest that the introduction of a hydrophobic/aromatic moiety to glycopeptides results in a more successful MALDI analysis due to the effective incorporation of the analyte into matrix crystals.

Negative-ion MALDI-MS2 for discrimination of α2,3- and α2,6-sialylation on glycopeptides labeled with a pyrene derivative.

Here, we propose a novel method for the discrimination of α2,3- and α2,6-sialylation on glycopeptides. To stabilize the sialic acids, the carboxyl moiety on the sialic acid as well as the C-terminus and side chain of the peptide backbone were derivatized using 1-pyrenyldiazomethane (PDAM). The derivatization can be performed on the target plate for matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS), thereby avoiding complicated and time-consuming purification steps. After the on-plate PDAM derivatization, samples were subjected to negative-ion MALDI-MS using 3AQ-CHCA as a matrix. Deprotonated ions of the PDAM-derivatized form were detected as the predominant species without loss of sialic acid. The negative-ion collision-induced dissociation (CID) of PDAM-derivatized isomeric sialylglycopeptides, derived from hen egg yolk, showed characteristic spectral patterns. These data made it possible to discriminate α2,3- and α2,6-sialylation. In addition, sialyl isomers of a glycan with an asparagine could be discriminated based on their CID spectra. In brief, the negative-ion CID of PDAM-derivatized glycopeptides with α2,6-sialylation gave an abundant (0,2)A-type product ion, while that with α2,3-sialylation furnished a series of (2,4)A/Y-type product ions with loss of sialic acids. The unique fragmentation behavior appears to be derived from the difference of pyrene binding positions after ionization, depending on the type of sialylation. Thus, we show that on-plate PDAM derivatization followed by negative-ion MALDI-MS(2) is a simple and robust method for the discrimination of α2,3- and α2,6-sialylation on glycopeptides.

Derivatization with 1-pyrenyldiazomethane enhances ionization of glycopeptides but not peptides in matrix-assisted laser desorption/ionization mass spectrometry.

Glycoproteomics holds the promise of new advances in medical technology. However, mass spectrometry has limitations for the structural determination of glycosylated peptides because the hydrophilic nature of the oligosaccharide moiety in glycopeptides is disadvantageous for ionization, and glycopeptides ionize much less readily than nonglycosylated peptides. Therefore, conventional proteomics tools cannot detect altered glycosylation on proteins. Here, we describe an on-plate pyrene derivatization method using 1-pyrenyldiazomethane for highly sensitive matrix-assisted laser/desorption ionization-tandem mass spectrometry (MALDI-MS(n)) of glycopeptides in amounts of less than 100 fmol. This derivatization is unique, as the pyrene groups are easily released from glycopeptides during ionization when 2,5-dihydroxybenzoic acid is used as a matrix. As a result, most ions are observed as the underivatized form on the spectra. At the same time, pyrene derivatization dramatically reduces the ionization of peptides. Thus, for glycopeptides in a mixture of abundant peptides, we could obtain MS spectra in which the signals of glycopeptides were intense enough for subjection to MS(n) in order to determine the structures of both glycan and peptide. Finally, we show that the glycopeptides derived from as little as 1 ng of prostate specific antigen can be detected by this method.

In vitro selection of a photoresponsive RNA aptamer to hemin.

A photoresponsive RNA aptamer to hemin was selected in vitro from a random sequence library of RNAs with azobenzene residues. The aptamer bound to hemin under visible light irradiation and was released by ultraviolet light.

Rapid DNA chemical ligation for amplification of RNA and DNA signal.

Enzymatic ligation methods are useful in the diagnostic detection of DNA sequences. Here, we describe the investigation of nonenzymatic phosphorothioate--iodoacetyl DNA chemical ligation as a method for the detection and identification of RNA and DNA. The specificity of ligation on the DNA target is shown to allow the discrimination of a single point mutation with a drop in the ligation yield of up to 16.1-fold. Although enzymatic ligation has very low activity for RNA targets, this reaction is very efficient for RNA targets. The speed of the chemical ligation with an RNA target achieves a 70% yield in 5 s, which is equal to or better than that of ligase-enzyme-mediated ligation with a DNA target. The reaction also exhibits a significant level of signal amplification under thermal cycling in periods as short as 100-120 min, with the RNA or DNA target acting in a catalytic way to ligate multiple pairs of probes.

Multiple chemical ligation under thermal cycle.

Enzymatic ligation methods are useful in diagnostic detection of DNA sequence. Here we describe the investigation of nonezymatic phosphorothioate-iodoacetyl DNA chemical ligation as a method for detection and identification of RNA and DNA. Specificity of ligation on DNA target is shown to yield discrimination of single point mutation as a drop in two magnitude. Although enzymatic ligation shows very low activity for RNA target, this reaction is found to be very efficient on RNA target. This chemical ligation with RNA target completes 70% within a few seconds, which equal or overcome ligase enzyme-mediated ligation with DNA target. The reaction is also shown to exhibit a significant level of signal amplification under thermal cycle for short time. Further, we found recently that ligation fidelity changed in function of chemical reactivity of probe. This trend was systematically investigated.

Intermolecular transfer of aminoacylated adenosine towards chemical aminoacylation of tRNA.

We synthesized two oligonucleotides: one is DNA conjugated with adenosine derivative at 5' terminus as a donor, another RNA phosphorothioated at 3' terminus as an acceptor. By hybridization of the two oligonuleotides, the adenosine derivative was transferred from the donor DNA to the acceptor RNA. In this study, O, O'-isopropylidene-protected adenosine derivative and aminoacylated adenosine were successfully transferred from the donor to acceptor RNA. By use of tRNA instead of the acceptor RNA, the chemical aminoacylation of tRNA by unnatural amino acid is expected.

Inhibition of vertebrate telomerases by the triphosphate derivatives of some biologically active nucleosides.

In order to clarify the effect of the base moiety of nucleotide analogs on telomerase inhibition, triphosphate derivatives of biologically active nucleosides, 3'-azido-3'-deoxythymidine (AZT), 2'-deoxy-2'-fluoroarafuranosylthymine (FaraT), acycloguanosine (ACG) and their guanine or thymine counterparts (AZdG, FaraG and ACT, respectively) were investigated. In all of the present cases, guanine derivatives showed more potent inhibition than their thymine counterparts.

Telomerase-inhibitory effects of sugar-modified nucleotide analogs.

Telomerase is an endogenous reverse transcriptase that uses its internal RNA moiety as a template for the synthesis of telomere repeats, thus maintaining telomere length. To study the susceptibility of telomerase to sugar-modified nucleotide analogs, inhibition by arabinofuranosylguanine 5'-triphosphate (araGTP), 3'-azido-2',3'-dideoxyguanosine 5'-triphosphate (AZdGTP), 2',3'-dideoxy-2'-fluoroarabino-furanosylguanine 5'-triphosphate (FaraGTP), and their thymine counterparts was investigated. Among these compounds, all dGTP analogs showed potent inhibitory activity against human telomerase. Conversely, dTTP analogs showed moderate or weak inhibition. Partially purified telomerase from cherry salmon testis utilized ddGTP and AZdGTP as substrates into the 3'-terminus of DNA.