尖吻蝮蛇毒抗凝血因子(ACF)含量和钙离子含量的定量测定及钙离子结合位点的初步研究

由紫外光谱法测定蛋白质浓度,用ICP测定Ca含量,从而确定一个ACF分子中含一个钙离子.ACF中分子中除一个高亲和性钙结合位点外,至少还有一个低亲和性钙结合位点,只有当过量钙离子存在时,才可能在低亲和性钙结合位点上进一步结合钙离子.Tb³⁺具有比Ca²⁺离子更强的键合ACF能力,能定量结合在ACF中的两个位点上,且能全部取代ACF中Ca²⁺.文中提及的金属离子对ACF的抗凝血活性没有显著的影响.     

Design and Synthesis of a Calcium‐Sensitive Photocage

Photolabile protecting groups (or “photocages”) enable precise spatiotemporal control of chemical functionality and facilitate advanced biological experiments. Extant photocages exhibit a simple input–output relationship, however, where application of light elicits a photochemical reaction irrespective of the environment. Herein, we refine and extend the concept of photolabile groups, synthesizing the first Ca²⁺‐sensitive photocage. This system functions as a chemical coincidence detector, releasing small molecules only in the presence of both light and elevated [Ca²⁺]. Caging a fluorophore with this ion‐sensitive moiety yields an “ion integrator” that permanently marks cells undergoing high Ca²⁺ flux during an illumination‐defined time period. Our general design concept demonstrates a new class of light‐sensitive material for cellular imaging, sensing, and targeted molecular delivery.     

Conformational Changes in Calcium‐Sensor Proteins under Molecular Crowding Conditions

Fundamental components of signaling pathways are switch modes in key proteins that control start, duration, and ending of diverse signal transduction events. A large group of switch proteins are Ca²⁺ sensors, which undergo conformational changes in response to oscillating intracellular Ca²⁺ concentrations. Here we use dynamic light scattering and a recently developed approach based on surface plasmon resonance to compare the protein dynamics of a diverse set of prototypical Ca²⁺‐binding proteins including calmodulin, troponin C, recoverin, and guanylate cyclase‐activating protein. Surface plasmon resonance biosensor technology allows monitoring conformational changes under molecular crowding conditions, yielding for each Ca²⁺‐sensor protein a fingerprint profile that reflects different hydrodynamic properties under changing Ca²⁺ conditions and is extremely sensitive to even fine alterations induced by point mutations. We see, for example, a correlation between surface plasmon resonance, dynamic light scattering, and size‐exclusion chromatography data. Thus, changes in protein conformation correlate not only with the hydrodynamic size, but also with a rearrangement of the protein hydration shell and a change of the dielectric constant of water or of the protein–water interface. Our study provides insight into how rather small signaling proteins that have very similar three‐dimensional folding patterns differ in their Ca²⁺‐occupied functional state under crowding conditions.     

New Calcium‐Selective Smart Contrast Agents for Magnetic Resonance Imaging

Calcium plays a vital role in the human body and especially in the central nervous system. Precise maintenance of Ca²⁺ levels is very crucial for normal cell physiology and health. The deregulation of calcium homeostasis can lead to neuronal cell death and brain damage. To study this functional role played by Ca²⁺ in the brain noninvasively by using magnetic resonance imaging, we have synthesized a new set of Ca²⁺‐sensitive smart contrast agents (CAs). The agents were found to be highly selective to Ca²⁺ in the presence of other competitive anions and cations in buffer and in physiological fluids. The structure of CAs comprises Gd³⁺‐DO3A (DO3A=1,4,7‐tris(carboxymethyl)‐1,4,7,10‐tetraazacyclododecane) coupled to a Ca²⁺ chelator o‐amino phenol‐N,N,O‐triacetate (APTRA). The agents are designed to sense Ca²⁺ present in extracellular fluid of the brain where its concentration is relatively high, that is, 1.2–0.8 mM . The determined dissociation constant of the CAs to Ca²⁺ falls in the range required to sense and report changes in extracellular Ca²⁺ levels followed by an increase in neural activity. In buffer, with the addition of Ca²⁺ the increase in relaxivity ranged from 100–157 %, the highest ever known for any T₁‐based Ca²⁺‐sensitive smart CA. The CAs were analyzed extensively by the measurement of luminescence lifetime measurement on Tb³⁺ analogues, nuclear magnetic relaxation dispersion (NMRD), and ¹⁷O NMR transverse relaxation and shift experiments. The results obtained confirmed that the large relaxivity enhancement observed upon Ca²⁺ addition is due to the increase of the hydration state of the complexes together with the slowing down of the molecular rotation and the retention of a significant contribution of the water molecules of the second sphere of hydration.     

Design and Synthesis of a Highly Sensitive Off–On Fluorescent Chemosensor for Zinc Ions Utilizing Internal Charge Transfer

Fluorescence imaging is a powerful tool for the visualization of biological molecules in living cells, tissue slices, and whole bodies, and is important for elucidating biological phenomena. Furthermore, zinc (Zn²⁺) is the second most abundant heavy metal ion in the human body after iron, and detection of chelatable Zn²⁺ in biological studies has attracted much attention. Herein, we present a novel, highly sensitive off–on fluorescent chemosensor for Zn²⁺ by using the internal charge transfer (ICT) mechanism. The rationale of our approach to highly sensitive sensor molecules is as follows. If fluorescence can be completely quenched in the absence of Zn²⁺, chemosensors would offer a better signal‐to‐noise ratio. However, it is difficult to quench the fluorescence completely before Zn²⁺ binding, and most sensor molecules still show very weak fluorescence in the absence of Zn²⁺. But even though the sensor shows a weak fluorescence in the absence of Zn²⁺, this fluorescence can be further suppressed by selecting an excitation wavelength that is barely absorbed by the Zn²⁺‐free sensor molecule. Focusing on careful control of ICT within the 4‐amino‐1,8‐naphthalimide dye platform, we designed and synthesized a new chemosensor ( 1 ) that shows a pronounced fluorescence enhancement with a blueshift in the absorption spectrum upon addition of Zn²⁺. The usefulness of 1 for monitoring Zn²⁺ changes was confirmed in living HeLa cells. There have been several reports on 4‐amino‐1,8‐naphthalimide‐based fluorescent sensor molecules. However, 1 is the first Zn²⁺‐sensitive off–on fluorescent sensor molecule that employs the ICT mechanism; most off–on sensor molecules for Zn²⁺ employ the photoinduced electron transfer (PeT) mechanism.     

Unraveling Ultrafast Photoinduced Proton Transfer Dynamics in a Fluorescent Protein Biosensor for Ca2+ Imaging

Imaging Ca²⁺ dynamics in living systems holds great potential to advance neuroscience and cellular biology. G‐GECO1.1 is an intensiometric fluorescent protein Ca²⁺ biosensor with a Thr‐Tyr‐Gly chromophore. The protonated chromophore emits green upon photoexcitation via excited‐state proton transfer (ESPT). Upon Ca²⁺ binding, a significant population of the chromophores becomes deprotonated. It remains elusive how the chromophore structurally evolves prior to and during ESPT, and how it is affected by Ca²⁺. We use femtosecond stimulated Raman spectroscopy to dissect ESPT in both the Ca²⁺‐free and bound states. The protein chromophores exhibit a sub‐200 fs vibrational frequency shift due to coherent small‐scale proton motions. After wavepackets move out of the Franck–Condon region, ESPT gets faster in the Ca²⁺‐bound protein, indicative of the formation of a more hydrophilic environment. These results reveal the governing structure–function relationship of Ca²⁺‐sensing protein biosensors.     

Dual‐Polarization Imaging of a Dual‐Fluorophore Ion Sensor: A Single‐Molecule Study

The fluorescence emission of the dual‐fluorophore Ca²⁺ ion sensor molecule, calcium‐green 2 (CG‐2), has been characterized using dual‐polarization imaging at the single‐molecule level. By comparing the fluorescence intensity of individual CG‐2 molecules in two mutually orthogonal polarization image channels, information about the relative orientation of the two constituent fluorophores in the molecule is obtained. Experimental results from polarization measurements are compared with those predicted from a geometric model based on coupled‐fluorophores that are randomly distributed in space. The results confirm previous optical spectroscopy‐based predictions of the orientation of CG‐2′s fluorophores, and the general applications of this dual‐polarization imaging approach for characterizing the optical properties of molecules containing multiple fluorophores is discussed.     

A Glycosylated Covalent Organic Framework Equipped with BODIPY and CaCO3 for Synergistic Tumor Therapy

Ca²⁺, a ubiquitous but nuanced modulator of cellular physiology, is meticulously controlled intracellularly. However, intracellular Ca²⁺ regulation, such as mitochondrial Ca²⁺ buffering capacity, can be disrupted by ¹O₂. Thus, the intracellular Ca²⁺ overload, which is recognized as one of the important cell pro‐death factors, can be logically achieved by the synergism of ¹O₂ with exogenous Ca²⁺ delivery. Reported herein is a nanoscale covalent organic framework (NCOF)‐based nanoagent, namely CaCO₃@COF‐BODIPY‐2I@GAG ( 4 ), which is embedded with CaCO₃ nanoparticle (NP) and surface‐decorated with BODIPY‐2I as photosensitizer (PS) and glycosaminoglycan (GAG) targeting agent for CD44 receptors on digestive tract tumor cells. Under illumination, the light‐triggered ¹O₂ not only kills the tumor cells directly, but also leads to their mitochondrial dysfunction and Ca²⁺ overload. An enhanced antitumor efficiency is achieved via photodynamic therapy (PDT) and Ca²⁺ overload synergistic therapy.     

Chirality Transfer in Propeller‐Shaped Cyclen?Calcium(II) Complexes: Metal‐Coordinating and Ion‐Pairing Anion Procedures

A series of quadruple‐stranded Na⁺ and Ca²⁺ complexes with octadentate cyclen ligands was synthesized to produce complexes that contained four different side‐arm combinations (one triazole? coumarin group and three pyridine groups ( 1 ), four pyridine groups ( 2 ), one triazole? coumarin group and three quinoline groups ( 3 ), and four quinoline groups ( 4 )). X‐ray crystallographic analysis revealed that no significant changes occurred in the stereostructure of these complexes upon replacing one pyridine group with a triazole? coumarin moiety, or by replacing Na⁺ ions with Ca²⁺ ions, although the coordination number of the complexes in the solid state decreased when pyridine groups were replaced by quinoline groups. In solution, all of the side arms were arranged in a propeller‐like pattern to yield an enantiomer pair of Δ and Λ forms in each metal complex. The addition of a tert‐butoxycarbonyl (Boc)‐protected amino acid anion, that is, a coordinative chiral carboxylate anion, to the cyclen? Ca²⁺ complex induced circular dichroism (CD) signals in the aromatic region by forming a 1:1 mixture of diastereomeric ternary complexes with opposite complex chirality, whilst the corresponding Na⁺ complexes rarely showed any response. In complexes 1 ‐Ca²⁺ and 3 ‐Ca²⁺, this chirality‐transfer process was efficiently followed by considering the induction of the CD signals at two different wavelengths, that is, the coumarin‐chromophore region and the aza‐aromatic region. The sign and intensity of the CD signal were significantly dependent on both the nature of the aza‐aromatic moiety and the enantiomeric purity of the external anion. These Ca²⁺ complexes worked as effective probes for the determination of the enantiomeric excess of the chiral anion. The cyclen? Ca²⁺ complexes also interacted with the non‐coordinative Δ‐TRISPHAT anion through an ion‐pairing mechanism to achieve chirality transfer from the anion to the metal complex; both complexes 1 ‐Ca²⁺ and 3 ‐Ca²⁺ clearly showed induced CD signals in the coumarin‐chromophore region, owing to ion‐paring interactions with the Δ‐TRISPHAT anion. Thus, the proper combination of an octadentate cyclen ligand and a metal center demonstrated effective chirality transfer.     

一种新型胞内钙离子指示剂的合成、表征及生物性能研究

本文通过在钙离子的螯合母体的结构上引入一个甲基，合成了一种新型钙离子荧光指示剂 Fluo-3M AM，并通过核磁共振氢谱、红外光谱、气相色谱-质谱及飞行时间质谱对其结构进行了充分的表征。同时，还对其荧光光谱及生物活性进行了研究。结果表明：这种新型荧光指示剂对钙离子有较高的亲和性，并且可以获得较强的荧光信号，这对进一步研究生物系统中钙离子的影响将起到非常重要的作用。     

A Synthetic Fluorescent Mitochondria‐Targeted Sensor for Ratiometric Imaging of Calcium in Live Cells

Ca²⁺ handling by mitochondria is crucial for cell life and the direct measure of mitochondrial Ca²⁺ concentration in living cells is of pivotal interest. Genetically‐encoded indicators greatly facilitated this task, however they require demanding delivery procedures. On the other hand, existing mitochondria‐targeted synthetic Ca²⁺ indicators are plagued by several drawbacks, for example, non‐specific localization, leakage, toxicity. Here we report the synthesis and characterization of a new fluorescent Ca²⁺ sensor, named mt‐fura‐2, obtained by coupling two triphenylphosphonium cations to the molecular backbone of the ratiometric Ca²⁺ indicator fura‐2. Mt‐fura‐2 binds Ca²⁺ with a dissociation constant of ≈1.5 μm in vitro. When loaded in different cell types as acetoxymethyl ester, the probe shows proper mitochondrial localization and accurately measures matrix [Ca²⁺] variations, proving its superiority over available dyes. We describe the synthesis, characterization and application of mt‐fura‐2 to cell types where the delivery of genetically‐encoded indicators is troublesome.     

Double Metal Ions Competitively Control the Guest‐Sensing Process: A Facile Approach to Stimuli‐Responsive Supramolecular Gels

A facile approach to the design of stimuli‐responsive supramolecular gels (SRSGs) termed double‐metal‐ion competitive coordination control is reported. By this means, the fluorescence signals and guest‐selective responsiveness of the SRSGs are controlled by the competitive coordination of two different metal ions with the gelators and the target guest. To demonstrate this approach, a gelator G2 based on multiple self‐assembly driving forces was synthesized. G2 could form Ca²⁺‐coordinated metallogel CaG with strong aggregation‐induced emission (AIE). Doping of CaG with Cu²⁺ results in AIE quenching of CaG and formation of Ca²⁺‐ and Cu²⁺‐based metallogel CaCuG. CaCuG could fluorescently detect CN^? with specific selectivity through the competitive coordination of CN^? with the Cu²⁺ and the coordination of Ca²⁺ with G2 again. This approach may open up routes to novel stimuli‐responsive supramolecular materials.     

Solvation of Calcium–Phosphate Headgroup Complexes at the DPPC/Aqueous Interface

The effects of sodium (Na⁺) and calcium (Ca²⁺) cations on model zwitterionic dipalmitoylphosphatidylcholine (DPPC) monolayers spread on metal chloride salt solutions are investigated by means of vibrational sum frequency generation (VSFG) and heterodyne‐detected (HD)‐VSFG spectroscopy. VSFG and HD‐VSFG spectra in the OH stretching region reveal cation‐specific effects on the interfacial water′s H‐bonding network, knowledge of which has been limited to date. It is found that low‐concentrated Ca²⁺ more strongly perturbs interfacial water organization relative to highly concentrated Na⁺. At higher Ca²⁺ concentrations, the water H‐bonding network at the DPPC/CaCl₂ interface reorganizes and the resulting spectrum closely follows that of the bare air/CaCl₂ interface up to ～3400 cm^?1. Most interesting is the appearance of a negative band at ～3450 cm^?1 in the DPPC/CaCl₂ Im χ_s⁽²⁾ spectra, likely arising from an asymmetric solvation of Ca²⁺–phosphate headgroup complexes. This gives rise to an electric field that orients the net OH transition moments of a subset of OH dipoles toward the bulk solution.     

A Highly Selective Potassium Sensor for the Detection of Potassium in Living Tissues

The development of highly selective sensors for potassium is of great interest in biology. Two new hydrosoluble potassium sensors (Calix‐COU‐Alkyne and Calix‐COU‐Am) based on a calix[4]arene bis(crown‐6) and an extended coumarin were synthesized and characterized. The photophysical properties and complexation studies of these compounds have been investigated and show high molar extinction coefficients and high fluorescence quantum yields. Upon complexation with potassium in the millimolar concentration range, an increase of one‐ and two‐photon fluorescence emission is detected. A twofold fluorescence enhancement is observed upon excitation at λ=405 nm. The ligands present excellent selectivity for potassium in the presence of various competitive cations in water and in a physiological medium. The photophysical properties are not affected by the presence of a large amount of competing cations (Na⁺, Ca²⁺, Mg²⁺, etc.). Ex vivo measurements on mouse hippocampal slices show that Calix‐COU‐Alkyne accumulates extracellularly and does not alter the neuronal activity. Furthermore, the sensor can be utilized to monitor slow extracellular K⁺ increase induced by inhibition of K⁺ entry into the cells.     

Optogenetic Control of Voltage‐Gated Calcium Channels

Voltage‐gated Ca²⁺ (Ca_V) channels mediate Ca²⁺ entry into excitable cells to regulate a myriad of cellular events following membrane depolarization. We report the engineering of RGK GTPases, a class of genetically encoded Ca_V channel modulators, to enable photo‐tunable modulation of Ca_V channel activity in excitable mammalian cells. This optogenetic tool (designated optoRGK) tailored for Ca_V channels could find broad applications in interrogating a wide range of Ca_V‐mediated physiological processes.     

Selective Detection of Mg2+ for Sensing Applications in Drinking Water

A new series of ligands containing the 2-(2-hydroxy-3- naphthyl)-4-methylbenzoxazole (HNBO) fluorophore showed selectivity for Mg²⁺ ions, without the interference of Ca²⁺. The most promising representative L3 resulted the best performing sensor for Mg²⁺ both in solution and embedded in an all-solid-state optode, especially towards real samples of drinkable water.     

Ca2+‐Induced Oxygen Generation by FeO42− at pH 9–10

Although FeO₄^2? (ferrate(IV)) is a very strong oxidant that readily oxidizes water in acidic medium, at pH 9–10 it is relatively stable (<2 % decomposition after 1 h at 298 K). However, FeO₄^2? is readily activated by Ca²⁺ at pH 9–10 to generate O₂. The reaction has the following rate law: d[O₂]/dt=k_Ca[Ca²⁺][FeO₄^2?]². ¹⁸O‐labeling experiments show that both O atoms in O₂ come from FeO₄^2?. These results together with DFT calculations suggest that the function of Ca²⁺ is to facilitate O–O coupling between two FeO₄^2‐ions by bridging them together. Similar activating effects are also observed with Mg²⁺ and Sr²⁺.     

Molecular dynamics simulation exploration of cooperative migration mechanism of calcium ions in sarcoplasmic reticulum Ca2+‐ATPase

Calcium ATPase is a member of the P‐type ATPase, and it pumps calcium ions from the cytoplasm into the reticulum against a concentration gradient. Several X‐ray structures of different conformations have been solved in recent years, providing basis for elucidating the active transport mechanism of Ca²⁺ ions. In this work, molecular dynamics (MD) simulations were performed at atomic level to investigate the dynamical process of calcium ions moving from the outer mouth of the protein to their binding sites. Five initial locations of Ca²⁺ ions were considered, and the simulations lasted for 2 or 6 ns, respectively. Specific pathways leading to the binding sites and large structural rearrangements around binding sites caused by uptake of calcium ions were identified. A cooperative binding mechanism was observed from our simulation. Firstly, the first Ca²⁺ ion binds to site I , and then, the second Ca²⁺ ion approaches. The interactions between the second Ca²⁺ and the residues around site I disturb the binding state of site I and weaken its binding ability for the first bound Ca²⁺. Because of the electrostatic repulsion of the second Ca²⁺ and the electrostatic attraction of site II , the first bound Ca²⁺ shifts from site I to site II . Concertedly, the second Ca²⁺ binds to site I , forming a binding state with two Ca²⁺ ions, one at site I and the other at site II . Both of Glu908 and Asp800 coordinate with the two Ca²⁺ ions simultaneously during the concerted binding process, which is believed to be the hinge to achieve the concerted binding. In our simulations, four amino acid residues that serve as the channel to link the outer mouth and the binding sites during the binding process were recognized, namely Tyr837, Tyr763, Asn911, and Ser767. The analyses regarding the activity of the proteins via mutations of some key residues also supported our cooperative mechanism. © 2009 Wiley Periodicals, Inc. J Comput Chem 2009     

Redox Stability Controls the Cellular Uptake and Activity of Ruthenium‐Based Inhibitors of the Mitochondrial Calcium Uniporter (MCU)

The mitochondrial calcium uniporter (MCU) is the ion channel that mediates Ca²⁺ uptake in mitochondria. Inhibitors of the MCU are valuable as potential therapeutic agents and tools to study mitochondrial Ca²⁺. The best‐known inhibitor of the MCU is the ruthenium compound Ru360. Although this compound is effective in permeabilized cells, it does not work in intact biological systems. We have recently reported the synthesis and characterization of Ru265, a complex that selectively inhibits the MCU in intact cells. Here, the physical and biological properties of Ru265 and Ru360 are described in detail. Using atomic absorption spectroscopy and X‐ray fluorescence imaging, we show that Ru265 is transported by organic cation transporter 3 (OCT3) and taken up more effectively than Ru360. As an explanation for the poor cell uptake of Ru360, we show that Ru360 is deactivated by biological reductants. These data highlight how structural modifications in metal complexes can have profound effects on their biological activities.     

Cyclic Adenosine 5′‐Diphosphoribose (cADPR) Mimics Used as Molecular Probes in Cell Signaling

Cyclic adenosine 5′‐diphosphate ribose (cADPR) is a second messenger in the Ca²⁺ signaling pathway. To elucidate its molecular mechanism in calcium release, a series of cADPR analogues with modification on ribose, nucleobase, and pyrophosphate have been investigated. Among them, the analogue with the modification of the northern ribose by ether linkage substitution (cIDPRE) exhibits membrane‐permeate Ca²⁺ agonistic activity in intact HeLa cells, human T cells, mouse cardiac myocytes and neurosecretory PC12 cell lines; thus, cIDPRE and coumarin‐caged cIDPRE are valuable probes to investigate the cADPR‐mediated Ca²⁺ signal pathway.