Comparison of the circulating metabolite profile of PF-04991532, a hepatoselective glucokinase activator, across preclinical species and humans: potential implications in metabolites in safety testing assessment.

A previous report from our laboratory disclosed the identification of PF-04991532 [(S)-6-(3-cyclopentyl-2-(4-trifluoromethyl)-1H-imidazol-1-yl)propanamido)nicotinic acid] as a hepatoselective glucokinase activator for the treatment of type 2 diabetes mellitus. Lack of in vitro metabolic turnover in microsomes and hepatocytes from preclinical species and humans suggested that metabolism would be inconsequential as a clearance mechanism of PF-04991532 in vivo. Qualitative examination of human circulating metabolites using plasma samples from a 14-day multiple ascending dose clinical study, however, revealed a glucuronide (M1) and monohydroxylation products (M2a and M2b/M2c) whose abundances (based on UV integration) were greater than 10% of the total drug-related material. Based on this preliminary observation, mass balance/excretion studies were triggered in animals, which revealed that the majority of circulating radioactivity following the oral administration of [¹4C]PF-04991532 was attributed to an unchanged parent (>70% in rats and dogs). In contrast with the human circulatory metabolite profile, the monohydroxylated metabolites were not detected in circulation in either rats or dogs. Available mass spectral evidence suggested that M2a and M2b/M2c were diastereomers derived from cyclopentyl ring oxidation in PF-04991532. Because cyclopentyl ring hydroxylation on the C-2 and C-3 positions can generate eight possible diastereomers, it was possible that additional diastereomers may have also formed and would need to be resolved from the M2a and M2b/M2c peaks observed in the current chromatography conditions. In conclusion, the human metabolite scouting study in tandem with the animal mass balance study allowed early identification of PF-04991532 oxidative metabolites, which were not predicted by in vitro methods and may require additional scrutiny in the development phase of PF-04991532.

Preparation of the cerebroside sulfate activator (CSAct or saposin B) from human urine.

The purification of cerebroside sulfate activator (CSAct) or saposin B from pooled human urine is described. Urinary proteins are concentrated by ammonium sulfate precipitation. A suspension of the precipitate is heat-treated and the heat-stable proteins are fractionated through a series of chromatographic steps. An initial concanavalin A column retains little of the CSAct activity, but is important for subsequent purification. Passing the Con A effluent directly onto an octyl Sepharose column removes the protein of interest which is recovered by affinity elution with octyl glucoside. Subsequent ion-exchange and gel filtration chromatographies yield a protein of 80-90% purity, although it is sometimes necessary to repeat one or more steps. A small amount of CSAct can sometimes be recovered from the initial Con A Sepharose column by methyl mannoside elution and purified by a parallel chromatographic protocol. Mass spectral analysis suggests that the final material is a mixture of two major and several minor glycoforms of a 79 amino acid protein with the structure predicted from the human prosaposin cDNA by truncation of both N- and C-terminal regions. Sugar analysis revealed the presence of glucosamine, mannose, and fucose, consistent with the major isoforms bearing a five-sugar Man(2)GluNac(2)Fuc or a single GluNac substituent. The human urinary material is similar to the previously characterized pig kidney protein in most respects, but varies in some details.

Cerebroside sulfate activator protein (Saposin B): chromatographic and electrospray mass spectrometric properties.

Cerebroside sulfate activator protein is a small, heat-stable protein that is exceptionally resistant to proteolytic attack. This protein is essential for the catabolism of cerebroside sulfate and several other glycosphingolipids. Protein purified from pig kidney and human urine was extensively characterized by reversed-phase liquid chromatography and electrospray mass spectrometry. These two sources revealed 20 and 18 different molecular isoforms of the protein, respectively. Plausible explanations of the structures of the majority of these isoforms can be made on the basis of accurate molecular mass assignments. The reversed-phase chromatographic and electrospray mass spectrometric properties of enzymatically deglycosylated and disulfide-reduced protein were also compared. In addition to a demonstration of the power of electrospray ionization mass spectrometry for revealing a wealth of information on protein microheterogeneity and structural detail, the results also demonstrate the utility of this technique for monitoring spontaneous chemical and enzymatically mediated changes that occur as a result of metabolic processing and protein purification.