Expanding the use of fluorogenic enzyme reporter substrates to imaging metabolic flux changes: the activity measurement of 5α-steroid reductase in intact mammalian cells.

The study of dynamic properties of metabolic and signaling networks is hindered by the lack of methods for imaging metabolic fluxes in individual intact cells. We describe a novel optical approach for measuring the changes of metabolic fluxes in cells, based on a two-substrate competition between a physiological substrate and a fluorogenic reporter substrate. We have constructed a model cell system for a two-step metabolic pathway involved in the metabolism of testosterone. Potent androgen testosterone is converted by steroid 5α-reductase to DHT (5α-dihydrotestosterone), which is subsequently metabolized to 3α-diol (3α,17ß-androstanediol) by the reductase AKR1C2 (aldo-ketoreductase 1C2), for which we have previously developed the fluorogenic reporter substrate Coumberone. Despite the medicinal importance of 5α-reductase, there are presently no probes or methods for the continuous activity readout of this enzyme in cells. We show that the activity of 5α-R1 (5α-reductase type 1) can be measured in COS-1 cells via the changes of DHT flux. Our system enables a measurement of 5α-reductase activity in cells, via either fluorimetry or fluorescence microscopy, with a wide dynamic range of activities, and provides a continuous optical assay for evaluation of small molecule inhibitors for this important enzyme. Furthermore, this paper demonstrates a novel optical approach to measuring metabolic flux changes in living cells and expands the utility of fluorogenic enzyme reporter substrates: optical reporters can measure not only the activity of the target enzyme but also the activity of other enzymes upstream in the pathway, for which there are no probes available.

Imaging induction of cytoprotective enzymes in intact human cells: coumberone, a metabolic reporter for human AKR1C enzymes reveals activation by panaxytriol, an active component of red ginseng.

We here present an optical method for monitoring the activity of the inducible aldo-keto reductases AKR1C2 and AKR1C3 in living human cells. The induction of these enzymes is regulated by the antioxidant response element (ARE), as demonstrated in recent literature, which in turn is dependent on the transcription factor Nrf2. The activation of ARE leads to the transcription of a coalition of cytoprotective enzymes and thus represents an important target for the development of new therapies in the area of neurodegenerative diseases and cancer. Through the use of Coumberone, a metabolic fluorogenic probe, and isoform-selective inhibitors, the upregulation of cellular stress markers AKR1C2 and AKR1C3 can be quantitatively measured in the presence of ARE activator compounds, via either a fluorimetric assay or fluorescence microscopy imaging of intact cells. The method has both high sensitivity and broad dynamic range, as demonstrated by induction studies in three cell lines with dramatically different metabolic capabilities (transfected monkey kidney COS-1 cells, human neuroblastoma IMR-32 cells, and human liver HepG2 cells). We applied the new method to examine a number of neurotrophic natural products (spirotenuipesine A, spirotenuipesine B, scabronine G-methylester, and panaxytriol), and discovered that panaxytriol, an active component of red ginseng extracts, is a potent ARE inducer. The upregulation of AKR1C enzymes, induced by chemically homogeneous panaxytriol, was partially dependent on PKC and PI3K kinases as demonstrated by the application of selective inhibitors. This cellular mechanism may account for panaxytriol's neurotrophic, neuroprotective, and anticancer properties. The protective effects of ARE inducers against tumorgenesis and neurodegeneration fuel the growing interest in this area of research and the method described here will greatly enable these endeavors.

Fluorogenic metabolic probes for direct activity readout of redox enzymes: Selective measurement of human AKR1C2 in living cells.

The current arsenal of tools and methods for the continuous monitoring and imaging of redox metabolic pathways in the context of intact cells is limited. Fluorogenic substrates allow for direct measurement of enzyme activity in situ; however, in contrast to proteases and exo-glycosidases, there are no simple guidelines for the design of selective probes for redox metabolic enzymes. Here, we introduce redox probe 1 and demonstrate its high selectivity in living cells for human hydroxysteroid dehydrogenases (HSDs) of the aldo-keto reductase (AKR) superfamily. AKR1C isoforms perform multiple functions among which the metabolism of potent steroid hormones is well documented. Moreover, expression of these enzymes is responsive to cellular stress and pathogenesis, including cancer. Our probe design is based on redox-sensitive optical switches, which couple a ketone-alcohol redox event to a profound change in fluorescence. The high selectivity of phenyl ketone 1 for AKR1C2 over the many endogenous reductases present in mammalian cells was established by a quantitative comparison of the metabolic rates between null control cells (COS-1) and AKR1C2-transfected cells. Phenyl ketone 1 is a cell-permeable fluorogenic probe that permits a direct, real-time, and operationally simple readout of AKR1C2 enzyme activity in intact mammalian cells. Furthermore, it was demonstrated that probe 1 enables the quantitative examination of physiological substrate 5alpha-dihydrotestosterone ("dark substrate") in situ by means of a two-substrate competitive assay. Similarly, inhibitor potency of physiological (ursodeoxycholate) and synthetic inhibitors (flufenamic acid, ibuprofen, and naproxen) was also readily evaluated.

Design of optical switches as metabolic indicators: new fluorogenic probes for monoamine oxidases (MAO A and B).

This study describes the design of sensitive, selective, and fluorogenic reporter substrates for monoamine oxidase (MAO) enzymes. This was achieved by an iterative effort, guided by PET and TICT photophysical concepts, which led to the development of irreversible redox switches based on a facile oxidation-cyclization reporting mechanism. Specifically, enzymatic oxidation of the ethylamino group in probe 9 proceeded via a putative aldehyde intermediate, which subsequently underwent spontaneous and intramolecular condensation with the aniline amino group furnishing an indole product in an irreversible fashion. This overall change resulted in a significant change in the emission intensity. When expressed in terms of brightness, the origins of this emission switch may be rationalized by the changes in quantum yield and absorbance strength. The fluorescence readout directly correlated with the kinetics of the oxidative step (i.e., reporting mechanism was fast, the intermediate aldehyde was not detected). Probe 9 is a good substrate for MAO B (Km = 510 +/- 40 muM, kcat = 21 min-1) with the kinetic parameters comparable to physiological substrates. This probe not only allows for direct and continuous measurement of MAO activity in mitochondria and tissue homogenates, but more importantly sets the stage for future studies in intact cells and organs.

New tools for molecular imaging of redox metabolism: development of a fluorogenic probe for 3 alpha-hydroxysteroid dehydrogenases.

A new fluorogenic substrate was developed for 3alpha-hydroxysteroid dehydrogenases (3alpha-HSD), including the human enzymes implicated in important physiological functions (androgen deactivation, neurosteroid activation). While ketone 5 is nonfluorescent, the corresponding alcohol exhibits high fluorescence with emission maximum at 510 nm, thus constituting a redox optical switch. This study began with a chemical concept of a ketone-alcohol optical switch which guided the synthesis of a focused array of compounds. Subsequently, seven compounds were selected (1-7) on the basis of their optical and chemical (stability) properties and were submitted to a screen against a panel of dehydrogenase enzymes. Probe 5 was found to be highly selective for bacterial, rat, and human 3alpha-HSD enzymes. The kinetic parameters were obtained for human 3alpha-HSD enzyme (type 2 isozyme, AKR 1C3; Km = 2.5 muM, kcat = 8.2 min-1). Remarkably, comparison to 5alpha-dihydrotestosterone (5alpha-DHT, Km = 26 muM, kcat = 0.25 min-1, Figure 4), a likely physiological substrate in prostate, revealed that synthetic probe 5 is in fact a far better substrate for this enzyme. Structure 5 represents an exciting lead for the development of a redox imaging probe.