Diaminoterephthalates are fluorescent dyes and define scaffolds, which can be orthogonally functionalized at their two carboxylate residues with functional residues bearing task specific reactive groups. The synthesis of monofunctionalized dyes with thiol groups for surface binding, an azide for click chemistry, and a biotinoylated congener for streptavidin binding is reported. Two bifunctionalized dyes were prepared: One with an azide for click chemistry and a biotin for streptavidin binding, the other with a maleimide for reaction with thiol and a cyclooctyne moiety for ligation with copper-free click chemistry. In general, the compounds are red to orange, fluorescent materials with an absorption at about 450 nm and an emission at 560 nm with quantum yields between 2-41 %. Of particular interest is the maleimide-functionalized compound, which shows low fluorescence quantum yield (2 %) by itself. After addition of a thiol, the fluorescence is "turned on"; quantum yield 41 %.
Myristoylation of most neuronal calcium sensor proteins, a group of EF-hand calcium-binding proteins mainly expressed in neuronal tissue, can have a strong impact on protein dynamics and functional properties. Intracellular oscillations of the free Ca(2+) concentration can trigger conformational changes in Ca(2+) sensors. The position and possible movements of the myristoyl group in the photoreceptor cell-specific Ca(2+) sensor GCAP2 are not well-defined but appear to be different from those of the highly homologous cognate GCAP1. We designed and applied a new group of diaminoterephthalate-derived fluorescent probes to label GCAP2 at a covalently attached 12-azido-dodecanoic acid (a myristoyl substitute) and at cysteine residues in critical positions. Fluorescence emission of dye-labeled GCAP2 decreased when going from low (10(-9) M) to high [Ca(2+)] (10(-3) M), reaching a half-maximal effect of fluorescence emission at 0.44 ± 0.07 μM. The modified acyl group can therefore monitor changes in the protein conformation during binding and dissociation of Ca(2+) in the physiological range of free [Ca(2+)]. However, fluorescence quenching studies showed that the dye-acyl chain was shielded from the quencher by an adjacent polypeptide region. Further probing three cysteine positions (C35, C111, and C131) by dye labeling revealed that all positions were also sensitive to a change in [Ca(2+)], but only one (C131) was sensitive to a change in [Mg(2+)]. We suggest a scenario during illumination of the photoreceptor cell in which Ca(2+) dissociates first from low and medium affinity binding sites. These steps are sensed by dyes in cysteines at positions 35 and 111. Release of Ca(2+) from high affinity sites is sensed by regions adjacent to the dye-labeled fatty acid and involves the critical conformational change leading to activating guanylate cyclase.
The vitamin A derivative all- trans-retinoic acid (ATRA) is an important biologically active metabolite that regulates a variety of essential biological processes in particular via gene-regulatory mechanisms. In the retina, ATRA is a light-dependent byproduct of the phototransduction cascade. Here, ATRA is not only needed for proper retinal development, but it also acts as a neuromodulator on horizontal cells, second-order inhibitory neurons in the outer retina, which reveal morphological and physiological changes when the retina is treated with ATRA. There is evidence that gene-regulatory mechanisms may only be partially involved in these neuromodulatory processes and the underlying nontranscriptional mechanisms are still elusive. This is, among other things, due to the lack of appropriately labeled ATRA, which would allow the tracking of ATRA in cells or a given tissue. To overcome this obstacle, we designed, synthesized, and evaluated two conjugates of ATRA, one conjugated with biotin (biotin-ATRA) and one conjugated with diaminoterephthalate fluorophore (DAT-ATRA), as molecular tools for different fields of application. The biocompatibility of both compounds was demonstrated via cell viability assays in cultured N2a-cells. N2a-cells exposed to the compounds showed no significant changes in the viability rate. The functionality of synthesized ATRA-conjugates was verified using retinal tissue derived from adult carp. The binding of ATRA-conjugates to distinct retinal cells was assessed in primary cultures of carp retina. Hereby, horizontal and Müller cells have been identified as specific target cells of the new ATRA compounds. Electron microscopy further confirmed that the new substances are still able to induce synaptic plasticity at horizontal cell dendrites resulting in formation of spine synapses, as it is shown for native ATRA. Taken together, the novel ATRA-conjugates represent biocompatible and functional molecular tools, which may further provide the possibility to track ATRA in neuronal cells and study its modulatory effects in different cell systems.
How “Link” links two proteins with a fluorescent probe is shown in the Full Paper by J. Christoffers et al. on page 6535 ff. Diaminoterephthalates are functional fluorescent dyes which increase their quantum yield upon reaction with a molecular target. Such a “turn‐on probe” with maleimide and cyclooctyne reactive sites is used to link the retinal Ca2+ sensor recoverin with its target enzyme rhodopsin kinase. The Frontispiece graphic is inspired by the character “Link” in the fantasy game “The Legend of Zelda”.
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