Probing alanine transaminase catalysis with hyperpolarized 13CD3-pyruvate.

Hyperpolarized metabolites offer a tremendous sensitivity advantage (>10(4) fold) when measuring flux and enzyme activity in living tissues by magnetic resonance methods. These sensitivity gains can also be applied to mechanistic studies that impose time and metabolite concentration limitations. Here we explore the use of hyperpolarization by dissolution dynamic nuclear polarization (DNP) in mechanistic studies of alanine transaminase (ALT), a well-established biomarker of liver disease and cancer that converts pyruvate to alanine using glutamate as a nitrogen donor. A specific deuterated, (13)C-enriched analog of pyruvic acid, (13)C3D(3)-pyruvic acid, is demonstrated to have advantages in terms of detection by both direct (13)C observation and indirect observation through methyl protons introduced by ALT-catalyzed H-D exchange. Exchange on injecting hyperpolarized (13)C3D(3)-pyruvate into ALT dissolved in buffered (1)H(2)O, combined with an experimental approach to measure proton incorporation, provided information on mechanistic details of transaminase action on a 1.5s timescale. ALT introduced, on average, 0.8 new protons into the methyl group of the alanine produced, indicating the presence of an off-pathway enamine intermediate. The opportunities for exploiting mechanism-dependent molecular signatures as well as indirect detection of hyperpolarized (13)C3-pyruvate and products in imaging applications are discussed.

Exchange facilitated indirect detection of hyperpolarized 15ND2-amido-glutamine.

Hyperpolarization greatly enhances opportunities to observe in vivo metabolic processes in real time. Accessible timescales are, however, limited by nuclear spin relaxation times, and sensitivity is limited by magnetogyric ratios of observed nuclei. The majority of applications to date have involved direct (13)C observation of metabolites with non-protonated carbons at sites of interest ((13)C enriched carbonyls, for example), a choice that extends relaxation times and yields moderate sensitivity. Interest in (15)N containing metabolites is equally high but non-protonated sites are rare and direct (15)N observation insensitive. Here an approach is demonstrated that extends applications to protonated (15)N sites with high sensitivity. The normally short relaxation times are lengthened by initially replacing protons (H) with deuterons (D) and low sensitivity detection of (15)N is avoided by indirect detection through protons reintroduced by H/D exchange. A pulse sequence is presented that periodically samples (15)N polarization at newly protonated sites by INEPT transfer to protons while returning (15)N magnetization of deuterated sites to the +Z axis to preserve polarization for subsequent samplings. Applications to (15)ND(2)-amido-glutamine are chosen for illustration. Glutamine is an important regulator and a direct donor of nitrogen in cellular metabolism. Potential application to in vivo observation is discussed.