Synthesis of 2'-N-methylamino-2'-deoxyguanosine and 2'-N,N-dimethylamino-2'-deoxyguanosine and their incorporation into RNA by phosphoramidite chemistry.

The 2'-hydroxyl groups within RNA contribute in essential ways to RNA structure and function. Previously, we designed an atomic mutation cycle (AMC) that uses ribonucleoside analogues bearing different C-2'-substituents, including -OCH(3), -NH(2), -NHMe, and -NMe(2), to identify hydroxyl groups within RNA that donate functionally significant hydrogen bonds. To enable AMC analysis of the nucleophilic guanosine cofactor in the Tetrahymena ribozyme reaction and at other guanosines whose 2'-hydroxyl groups impart critical functional contributions, we describe here the syntheses of 2'-methylamino-2'-deoxyguanosine (G(NHMe)) and 2'-N,N-dimethylamino-2'-deoxyguanosine (G(NMe(2))) and their corresponding phosphoramidites. The key step in obtaining the nucleosides involved S(N)2 displacement of 2'-ß-triflate from an appropriate guanosine derivative by methylamine or dimethylamine. We readily obtained the G(NMe(2)) phosphoramidite and incorporated it into RNA. However, the G(NHMe) phosphoramidite posed a significantly greater challenge due to lack of a suitable -2'-NHMe protecting group. After testing several strategies, we established that allyloxycarbonyl (Alloc) provided suitable protection for 2'-N-methylamino group during the phosphoramidite synthesis and the subsequent RNA synthesis. This work enables AMC analysis of guanosine's 2'-hydroxyl group within RNA.

Quantification of isotope encoded proteins in 2-D gels using surface enhanced resonance Raman.

A strategy for quantification of multiple protein isoforms from a complex sample background is demonstrated, combining isotopomeric rhodamine 6G (R6G) labels and surface-enhanced Raman in polyacrylamide matrix. The procedure involves isotope-encoding by lysine-labeling with (R6G) active ester reagents, isoform separation by 2-DGE, fluorescence quantification using internal standardization to water, and silver nanoparticle deposition followed by surface-enhanced Raman detection. R6G sample encoding and standardization enabled the determination of total protein concentration and the distribution of specific isoforms using the combined detection approach of water-referenced fluorescence spectral imaging and ratiometric quantification. A detection limit of approximately 13.5 picomolar R6G-labeled protein was determined for the surface-enhanced Raman in a gel matrix (15-fold lower than fluorescence). High quantification accuracies for small differences in protein populations at low nanogram abundance were demonstrated for human GMP synthetase (hGMPS) either as purified protein samples in a single-point determination mode (3% relative standard deviation, RSD%) or as HCT116 human cancer cellular lysate in an imaging application (with 16% RSD%). These results represent a prototype for future applications of isotopic surface-enhanced resonance Raman scatter to quantification of protein distributions.

Accurate concentration measurements using surface-enhanced Raman and deuterium exchanged dye pairs.

Quantitative applications of surface-enhanced resonance Raman scattering (SERRS) are often limited by the reproducibility of SERRS intensities, given the difficulty of controlling analyte-substrate interactions and the associated local field enhancement. As demonstrated here, SERRS from dye molecules even within the same structural class that compete with similar substrates display distinct spectral intensities that are not proportional to analyte concentrations, which limits their use as internal standardization probes and/or for multiplex analysis. Recently, we demonstrated that isotopic variants of rhodamine 6G (R6G), namely R6G-d0 and R6G-d4, can be used for internal standards in SERRS experiments with a linear optical response from picomolar to micromolar concentrations (of total analytes). Here we extend these results by describing a straightforward method for obtaining isotopomeric pairs of other Raman active dyes by hydrogen-deuterium exchange conditions for substitution at electron rich aromatic heterocycles. Most of the known SERRS active probes can be converted into the corresponding isotopomeric molecule by this exchange method, which significantly expands the scope of the isotopic edited internal standard (IEIS) approach. The relative quantification using IEIS enables accurate, reproducible (residual standard deviation+/-2.2%) concentration measurements over a range of 200 pM to 2 microM. These studies enable easy access to a variety of isotopically substituted Raman active dyes and establish the generality of the methodology for quantitative SERRS measurements. For the first time, three rhodamine 6G isotopomers have been created and show distinct Raman spectra, demonstrating the principle of the approach for application as a multiplex technique in biomolecular detection/quantification.

Detection and relative quantification of proteins by surface enhanced Raman using isotopic labels.

Accurate quantification of protein content and composition has been achieved using isotope-edited surface enhanced resonance Raman spectroscopy. Synthesis of isotopomeric Rhodamine dye-linked bioconjugation reagents enabled direct labeling of surface lysines on a variety of proteins. When separated in polyacrylamide gels and stained with silver nanoparticles. The spectral signatures reflect the expected statistical distribution of isotopomeric labels on the labeled proteins in the gel matrix format without interference from protein features.

The 2'-hydroxyl group of the guanosine nucleophile donates a functionally important hydrogen bond in the tetrahymena ribozyme reaction.

In the first step of self-splicing, group I introns utilize an exogenous guanosine nucleophile to attack the 5'-splice site. Removal of the 2'-hydroxyl of this guanosine results in a 10 (6)-fold loss in activity, indicating that this functional group plays a critical role in catalysis. Biochemical and structural data have shown that this hydroxyl group provides a ligand for one of the catalytic metal ions at the active site. However, whether this hydroxyl group also engages in hydrogen-bonding interactions remains unclear, as attempts to elaborate its function further usually disrupt the interactions with the catalytic metal ion. To address the possibility that this 2'-hydroxyl contributes to catalysis by donating a hydrogen bond, we have used an atomic mutation cycle to probe the functional importance of the guanosine 2'-hydroxyl hydrogen atom. This analysis indicates that, beyond its role as a ligand for a catalytic metal ion, the guanosine 2'-hydroxyl group donates a hydrogen bond in both the ground state and the transition state, thereby contributing to cofactor recognition and catalysis by the intron. Our findings continue an emerging theme in group I intron catalysis: the oxygen atoms at the reaction center form multidentate interactions that function as a cooperative network. The ability to delineate such networks represents a key step in dissecting the complex relationship between RNA structure and catalysis.

Improved synthesis of 2'-amino-2'-deoxyguanosine and its phosphoramidite.

2'-Amino-2'-deoxynucleosides and oligonucleotides containing them have proven highly effective for an array of biochemical applications. The guanosine analogue and its phosphoramidite derivatives have been accessed previously from 2'-amino-2'-deoxyuridine by transglycosylation, but with limited overall efficiency and convenience. Using simple modifications of known reaction types, we have developed useful protocols to obtain 2'-amino-2'-deoxyguanosine and two of its phosphoramidite derivatives with greater convenience, fewer steps, and higher yields than reported previously. These phosphoramidites provide effective synthons for the incorporation of 2'-amino-2'-deoxyguanosine into oligonucleotides.

Isotope edited internal standard method for quantitative surface-enhanced Raman spectroscopy.

A new isotope edited internal standard (IEIS) method for quantitative surface-enhanced Raman spectroscopy (SERS) is demonstrated using rhodamine 6G (R6G-d0) and rhodamine 6G (R6G-d4) edited with deuterium. The reproducibility and accuracy of the IEIS method is investigated both under optical resonance (SERRS) and nonresonance (SERS) conditions. A batch-to-batch concentration measurement reproducibility of better than 3% is demonstrated over a concentration range of 200 pM-2 microM with up to a factor of 3 difference between the concentration of the analyte and its IEIS. The superior performance of the IEIS method is further illustrated by comparing results obtained using absolute SERS/SERRS intensity calibration (with no internal standard) or using adenine (rather than R6G-d4) as an internal standard for R6G concentration quantization. Potential biomedical gene expression and comparative proteomic applications of the IEIS method are discussed.

An atomic mutation cycle for exploring RNA's 2'-hydroxyl group.

The 2'-hydroxyl group fulfills numerous structural and functional roles in RNA, including those of hydrogen bond donor and acceptor. While loss of function upon 2'-deoxynucleotide substitution establishes the importance of specific 2'-hydroxyl groups within RNA, this approach provides no information about how these hydroxyl groups impart their functional contribution. We use an atomic mutation cycle to evaluate the functional importance of the 2'-hydroxyl group's hydrogen atom. Using the Tetrahymena ribozyme reaction, we challenge the cycle to expose the catalytic contribution of the cleavage site 2'-hydroxyl group and its associated hydrogen bond network. The results establish the viability of this cycle as an approach to reveal 2'-hydroxyl groups that donate functionally significant hydrogen bonds.

New strategies for exploring RNA's 2'-OH expose the importance of solvent during group II intron catalysis.

The 2'-hydroxyl group contributes inextricably to the functional behavior of many RNA molecules, fulfilling numerous essential chemical roles. To assess how hydroxyl groups impart functional behavior to RNA, we developed a series of experimental strategies using an array of nucleoside analogs. These strategies provide the means to investigate whether a hydroxyl group influences function directly (via hydrogen bonding or metal ion coordination), indirectly (via space-filling capacity, inductive effects, and sugar conformation), or through interactions with solvent. The nucleoside analogs span a broad range of chemical diversity, such that quantitative structure activity relationships (QSAR) now become possible in the exploration of RNA biology. We employed these strategies to investigate the spliced exons reopening (SER) reaction of the group II intron. Our results suggest that the cleavage site 2'-hydroxyl may mediate an interaction with a water molecule.