In vivo fluorescence imaging of biomaterial-associated inflammation and infection in a minimally invasive manner.

Implant-associated inflammation and bacterial infection severely limit the functional performance of medical devices and are a major cause of implant failure. Therefore, it is crucial to develop methodologies to monitor/image implant-associated aseptic inflammation and bacterial infection in a minimally invasive manner. Here, we exploited near-infrared fluorescence (NIRF) molecular probes injected locally at the implant site to perform minimally invasive, simultaneous imaging of inflammation, and infection associated with implanted polymer disks.

RegB kinase activity is repressed by oxidative formation of cysteine sulfenic acid.

RegB/RegA comprise a global redox-sensing signal transduction system utilized by a wide range of proteobacteria to sense environmental changes in oxygen tension. The conserved cysteine 265 in the sensor kinase RegB was previously reported to form an intermolecular disulfide bond under oxidizing conditions that converts RegB from an active dimer into an inactive tetramer. In this study, we demonstrate that a stable sulfenic acid (-SOH) derivative also forms at Cys-265 in vitro and in vivo when RegB is exposed to oxygen.

Redox-sensitive sulfenic acid modification regulates surface expression of the cardiovascular voltage-gated potassium channel Kv1.5.

Rationale: Kv1.5 (KCNA5) is expressed in the heart, where it underlies the I(Kur) current that controls atrial repolarization, and in the pulmonary vasculature, where it regulates vessel contractility in response to changes in oxygen tension. Atrial fibrillation and hypoxic pulmonary hypertension are characterized by downregulation of Kv1.

Activity of the tetrapyrrole regulator CrtJ is controlled by oxidation of a redox active cysteine located in the DNA binding domain.

CrtJ from Rhodobacter capsulatus is a regulator of genes involved in the biosynthesis of haem, bacteriochlorophyll, carotenoids as well as structural proteins of the light harvesting-II complex. Fluorescence anisotropy-based DNA-binding analysis demonstrates that oxidized CrtJ exhibits ~20-fold increase in binding affinity over that of reduced CrtJ. Liquid chromatography electrospray tandem ionization mass spectrometric analysis using DAz-2, a sulfenic acid (-SOH)-specific probe, demonstrates that exposure of CrtJ to oxygen or to hydrogen peroxide leads to significant accumulation of a sulfenic acid derivative of Cys420 which is located in the helix-turn-helix (HTH) motif.

Fluorescent coumarin thiols measure biological redox couples.

In this report we present a new chemical probe, 3-HTC, that can reversibly and ratiometrically measure the thiol-disulfide equilibrium of biological systems. 3-HTC is composed of a coumarin that has a thiolate directly conjugated to its extended aromatic π system while formation of a disulfide attenuates this conjugation. The fluorescence and absorption properties of 3-HTC are therefore very sensitive to the redox state of its thiol.

Mining the thiol proteome for sulfenic acid modifications reveals new targets for oxidation in cells.

Oxidation of cysteine to sulfenic acid has emerged as a biologically relevant post-translational modification with particular importance in redox-mediated signal transduction; however, the identity of modified proteins remains largely unknown. We recently reported DAz-1, a cell-permeable chemical probe capable of detecting sulfenic acid modified proteins directly in living cells. Here we describe DAz-2, an analogue of DAz-1 that exhibits significantly improved potency in vitro and in cells.

Substituent effects on the sensitivity of a quinoline photoremovable protecting group to one- and two-photon excitation.

Photoremovable protecting groups that can reveal biologically important functional groups through one- and two-photon excitation (1PE and 2PE, respectively) have promise in regulating physiological function in a temporally and spatially restricted manner. Only a few chromophores have sufficient sensitivity to 2PE suitable for use as "caging groups" in physiology experiments. It would be useful to develop structure-property relationships of chromophores, so that chromophores with high two-photon uncaging action cross-sections (delta(u)) can be designed.

Expanding the functional diversity of proteins through cysteine oxidation.

The polarizable sulfur atom in cysteine is subject to numerous post-translational oxidative modifications in the cellular milieu, which regulates a wide variety of biological phenomena such as catalysis, metal binding, protein turnover, and signal transduction. The application of chemical rationale to describe the features of different cysteine oxoforms affords a unique perspective on this rapidly expanding field. Moreover, a chemical framework broadens our understanding of the functional roles that specific cysteine oxidation states can play and facilitates the development of mechanistic proposals, which can be tested in both biochemical and cellular studies.

Inhibition of kinesin motor proteins by adociasulfate-2.

Kinesin motor proteins are involved in cell division and intracellular transport of vesicles and organelles, and as such, they play a role in neurological disease, cancer, and developmental disorders. Inhibitors of kinesin would be valuable as probes of cell physiology and as potential therapeutics. Adociasulfate-2 (AS-2) is the only known natural product inhibitor of kinesins, but its mechanism of action is unknown.