Radiosynthesis of 11-[(18) F]fluoroundecyltriphenylphosphonium (MitoF) as a potential mitochondria-specific positron emission tomography radiotracer.

Changes in the magnitude of the mitochondrial membrane potential occur in a range of important pathologies. To assess changes in membrane potential in patients, we set out to develop an improved mitochondria-targeted positron emission tomography probe comprising a lipophilic triphenylphosphonium cation attached to a fluorine-18 radionuclide via an 11-carbon alkyl chain, which is well-established to effectively transport to and localise within mitochondria. Here, we describe the radiosynthesis of this probe, 11-[(18) F]fluoroundecyl-triphenylphosphonium (MitoF), from no-carrier-added [(18) F]fluoride and a fully automated synthetic protocol to prepare it in good radiochemical yields (2-3 GBq at end-of-synthesis) and radiochemical purity (97-99%).

A comparison of the counteracting effects of glycine betaine and TMAO on the activity of RNase A in aqueous urea solution.

Trimethylamine-N-oxide (TMAO) and glycine betaine are counteracting osmolytes found in cellular systems under osmotic stress, often in association with high urea concentrations. TMAO is a characteristic component of cartilaginous fish and marine molluscs, while glycine betaine is more widely distributed, occurring in plants, bacteria and the mammalian kidney. As part of a project to explain and understand the action of these methylamines, the RNase A-catalysed degradation of polyuridylic acid in the presence of urea and various osmolytes (0-1.0 M) was studied using (31)P Nuclear Magnetic Resonance spectroscopy. The decrease in reaction rate induced by urea could be fully recovered with 1 molar equivalent of trimethylamine-N-oxide or 1.4 molar equivalents of glycine betaine. These results indicate that the modification of RNase A activity induced by urea is not associated with gross irreversible structural changes and that both glycine betaine and trimethylamine-N-oxide have kinetically detectable counteracting effects.

Lipophilic triphenylphosphonium cations as tools in mitochondrial bioenergetics and free radical biology.

Lipophilic phosphonium cations were first used to investigate mitochondrial biology by Vladimir Skulachev and colleagues in the late 1960s. Since then, these molecules have become important tools for exploring mitochondrial bioenergetics and free radical biology. Here we review why these molecules are useful in mitochondrial research and outline some of the ways in which they are now being utilized.

Using mitochondria-targeted molecules to study mitochondrial radical production and its consequences.

The production of ROS (reactive oxygen species) by the mitochondrial respiratory chain contributes to a range of pathologies, including neurodegenerative diseases, ischaemia/reperfusion injury and aging. There are also indications that mitochondrial ROS production plays a role in damage response and signal transduction pathways. To unravel the role of mitochondrial ROS production in these processes, we have developed a range of mitochondria-targeted probe molecules. Covalent attachment of a lipophilic cation leads to their accumulation into mitochondria, driven by the membrane potential. Molecules developed so far include antioxidants designed to intercept mitochondrial ROS and reagents that specifically label mitochondrial thiol proteins. Here we outline how mitochondrial ROS formation and its consequences can be investigated using these probes.

Putative osmolytes in the kidney of the Australian brush-tailed possum, Trichosurus vulpecula.

The Australian brush-tailed possum, Trichosurus vulpecula, is capable of producing a moderately concentrated urine, at least up to 1300 mOsm l(-1). Kidneys of adult animals fed in captivity on a normal diet with ready access to water were analysed. The inner medullary regions were found to have moderately high concentrations of sodium (outer medulla, 367+/-37; inner medulla 975+/-93 mmol kg(-1) dry wt.), chloride (outer medulla 240+/-21; inner medulla 701+/-23 mmol kg(-1) dry wt.) and urea (outer medulla, 252+/-62; inner medulla, 714+/-69 mmol kg(-1) protein). When the animals were fed on a 'wet diet', amounts of these substances in the outer medulla and cortex were reduced, although with the exception of urea these changes were not significant. There were highly significant changes in amounts of Na(+), Cl(-) and urea in the inner medulla (Na(+), 566+/-7; Cl(-), 422+/-9 mmol kg(-1) dry wt.; urea 393+/-84 mmol kg(-1) protein). Likewise, the inner medulla of animals fed a 'dry diet' with limited access to water showed highly significant increases in the same substances (Na(+), 1213+/-167; Cl(-), 974+/-137 mmol kg(-1) dry wt.; urea, 1672+/-98 mmol kg(-1) protein). Inositol was found in the outer medulla (224+/-90 mmol kg(-1) protein) and inner medulla (282 mmol kg(-1) protein) as was sorbitol (outer medulla, 62+/-20; inner medulla, 274+/-72 mmol kg(-1) protein). Both these polyols were reduced in amount in renal tissue from 'wet diet' animals, and increased in 'dry diet' animals, but the changes were not statistically significant. The methylamines, betaine and glycerophosphorylcholine (GPC), showed a similar pattern, but both were significantly elevated in the inner medulla of 'dry diet' animals (betaine 154+/-57 to 315+/-29 mmol kg(-1) protein; GPC 35+/-7 to 47+/-10 mmol kg(-1) protein). It was concluded that in this marsupial the concentrating mechanism probably functions in a similar way to that in higher mammals, and that the mechanism of osmoprotection of the medulla of the kidney involves the same osmolytes. However, the high ratio of betaine to GPC in the inner medulla resembles the situation in the avian kidney.