Hydrogen sulfide (H(2)S) has recently been identified as a biological response modifier. Here, we report the design and synthesis of a novel fluorescence probe for H(2)S, HSip-1, utilizing azamacrocyclic copper(II) ion complex chemistry to control the fluorescence. HSip-1 showed high selectivity and high sensitivity for H(2)S, and its potential for biological applications was confirmed by employing it for fluorescence imaging of H(2)S in live cells.
Abstract We have established a coupled assay system targeting protein l ‐isoaspartyl methyltransferase (PIMT), a key enzyme in the metabolism of isoaspartyl peptides and proteins. The system utilizes a fluorogenic peptide probe containing an isoaspartyl residue at the P1′ position of the caspase‐3 recognition sequence. Following PIMT‐catalyzed methyl transfer reaction, the methylated probe is specifically cleaved by caspase‐3 to give fluorescence activation. High‐throughput screening of our chemical library with this assay system identified PIMT inhibitors that may be useful as leads in the design of chemical probes for controlling PIMT activity.
In this study, we present a live-cell-based fluorometric coupled assay system to identify the compounds that can regulate the targeted metabolic pathways in live cells. The assay is established through targeting specific metabolic pathways and using "input" and "output" metabolite pairs. The changes in the extracellular output that are generated and released into the extracellular media from the input are assessed as the activity of the pathway. The screening for the glycolytic pathway and amino acid metabolism reveals the activities of the present drugs, 6-BIO and regorafenib, that regulate the metabolic fate of tumor cells.
Abstract We adopted a spirocyclization‐based strategy to design γ‐glutamyl hydroxymethyl selenorhodamine green (gGlu‐HMSeR) as a photo‐inactive compound that would be specifically cleaved by the tumor‐associated enzyme γ‐glutamyltranspeptidase (GGT) to generate the potent photosensitizer HMSeR. gGlu‐HMSeR has a spirocyclic structure and is colorless and does not show marked phototoxicity toward low‐GGT‐expressing cells or normal tissues upon irradiation with visible light. In contrast, HMSeR predominantly takes an open structure, is colored, and generates reactive oxygen species upon irradiation. The γ‐glutamyl group thus serves as a tumor‐targeting moiety for photodynamic therapy (PDT), switching on tumor‐cell‐specific phototoxicity. To validate this system, we employed chick chorioallantoic membrane (CAM), a widely used model for preliminary evaluation of drug toxicity. Photoirradiation after gGlu‐HMSeR treatment resulted in selective ablation of implanted tumor spheroids without damage to healthy tissue.
Cellular homeostasis is maintained by a complex network of reactions catalyzed by enormous numbers of enzymatic activities (the enzymome), which serve to determine the phenotypes of cells. Here, we focused on the enzymomics of proteases and peptidases because these enzymes are an important class of disease-related proteins. We describe a system that (A) simultaneously evaluates metabolic activities of peptides using a series of exogenous peptide substrates and (B) identifies the enzymes that metabolize the specified peptide substrate with high throughput. We confirmed that the developed system was able to discover cell-type-specific and disease-related exo- and endopeptidase activities and identify the responsible enzymes. For example, we found that the activity of the endopeptidase neurolysin is highly elevated in human colorectal tumor tissue samples. This simple but powerful enzymomics platform should be widely applicable to uncover cell-type-specific reactions and altered enzymatic functions with potential value as biomarkers or drug targets in various disease states and to investigate the mechanisms of the underlying pathologies.
Abstract A sensitive bioluminogenic probe for highly reactive oxygen species (hROS), SO 3 H‐APL, was developed based on the concept of dual control of bioluminescence emission by means of bioluminescent enzyme‐induced electron transfer (BioLeT) and modulation of cell‐membrane permeability. This probe enables non‐invasive visualization of physiologically relevant amounts of hROS generated deep inside the body of living rats for the first time. It is expected to serve as a practical analytical tool for investigating a wide range of biological functions of hROS in vivo. The design concept should be applicable to other in vivo bioluminogenic probes.
In shallow waters, water motion is one of the most important environmental factors for marine organisms. This is particularly true in coral reefs, where the effect of flow is important for growth processes and spawning settlements of coral inhabiting the area. However, it is very difficult to measure the water motion in these areas with conventional current meters (propeller type and electromagnetic current meters etc.) due to the meter size and bottom topography. For sessile organisms such as coral and oysters, the maximum instantaneous current velocity rather than the intensity of the averaged flow is important. Therefore, to measure water motion in coral reefs, a plaster ball technique has been developed and used. However, plaster balls are usable for only 2 or 3 days. In the case of measuring with plaster balls, such as for spawning settlement and diffusion of coral larvae, it is necessary to examine a large number of points over a long time period. Previously, we presented a way to improve the material of the plaster balls to make them usable for longer periods. In this study, we examined measurements of water motion around coral reefs using a large number of normal plaster balls and improved plaster balls, including plaster for dentistry, cement, and other types. The results of our experiment in a patch reef in the Sekisei Lagoon (Okinawa Prefecture, Japan) clearly showed that the intensity of the flow varied with depth and position, and that a small vortex had been generated around the patch reef. We consider the effect of such differential water motion and small vortices on the growth processes and spawning settlement of coral.
Abstract Molecular assemblies that change photoluminescence color in response to thermal or mechanical stimulation without dissociation into the monomeric states in water are described herein. A dumbbell‐shaped amphiphilic compound forms micellar molecular assemblies in water and exhibits yellow photoluminescence derived from excimer formation of the luminescent core, which contains a 2,6‐diethynylanthracene moiety. Annealing of the aqueous solution induces a photoluminescence color change from yellow to green ( λ em, max =558→525 nm). The same photoluminescence color change is also achieved by rubbing the yellow‐photoluminescence‐emitting molecular assemblies adsorbed on glass substrates with cotton wool in water. The observed green photoluminescence is ascribed to micelles that are distinct from the yellow‐photoluminescence‐emitting micelles, on the basis of transmission electron microscopy observations, atomic force microscopy observations, and dynamic light scattering measurements. We examined the relationship between the structure of the molecular assemblies and the photophysical properties of the anthracene derivative in water before and after thermal or mechanical stimulation and concluded that thermal or mechanical stimuli‐induced slight changes of the molecular‐assembled structures in the micelles result in the change in the photoluminescence color from yellow to green in water.
