Decrease In Fluorescence Research Articles

Antifungal activity’s study of the of new derivatives of pyrrolo[3,4-c]pyrazol-3-ones and pyrazol-3- carboxamides in the biofilm model of Candida spp.

The search for new antifungal drugs is current interest due to the wide spread of fungal infections. To simulate the antifungal effect of new promising compounds with high antifungal activity in planktonic culture in clinical practice, it is necessary to study their effect on the biofilm of micromycetes.Aim: To study the antifungal activity of new promising representatives of silver salts of pyrazoles and their condensed systems under conditions of biofilm formation.Material and Methods. To study the antifungal activity of silver salts I and II, the micromethod of two-fold serial dilutions was used. Activity against a typical and 14 clinical highly virulent isolates of C. albicans was studied. The study of the antimycotic activity of substances under biofilm conditions was carried out using resazurin to quantify the degree of biofilm formation. The minimum inhibitory concentrations for biofilms were calculated (sMIC50 - the concentration of the antifungal substance at which a 50% decrease in fluorescence is observed compared to the positive control).Results and Discussion. It was shown that the antifungal effect of the studied compounds in biofilm culture of clinical strains of Candida spp. is significantly lower than in planktonic culture. High antifungal activity of the silver salt of pyrazole-3- carboxamide in planktonic and biofilm cultures of resistant strains of Candida albicans, exceeding the effect of the reference drug fluconazole by 2.8–11.2 times, was revealed.Conclusion. A promising pyrazole-3-carboxamide derivative has been identified that effectively inhibits the growth of Candida albicans biofilms, which can be recommended for further study.

Fluorescence labeling-based differential scanning fluorimetry, an effective method for protein thermal stability and protein-compound binding analysis

Differential scanning fluorimetry (DSF) is widely used to assess protein thermal stability and protein-ligand interaction. However, its utility is often limited by the presence of detergents, which can affect hydrophobic binding. To tackle this issue, we developed an effective fluorescence-labeled DSF (FL-DSF) technique that tracks protein denaturation by monitoring the labeling fluorescence decrease, thus overcoming challenges typically encountered with traditional DSF methods. In this research, FL-DSF was first validated using Peroxisome Proliferators-Activated Receptor γ (PPARγ), Retinoid X Receptor α (RXRα), and Lysozyme, confirming its accuracy in determining melting curves. Expectedly, FL-DSF also exhibited strong compatibility with detergents in our investigations. Besides this, a new calculation method was proposed to characterize the protein denaturation process and evaluate protein-ligand binding. This mathematical model goes beyond traditional approaches, which simply treated the melting temperature (TM) shift as a concentration-dependent variable. Instead, it comprehensively incorporates the influence of irreversible denaturation-induced native protein loss on the equilibrium of protein-ligand binding. This methodology was successfully applied into the evaluation of binding affinity for 2 classical binding systems of PPARγ-Rosiglitazone and RXRα-CD3254. It was also utilized for the following binding screening studies, leading to the discovery of promising ligands for PPARγ, RXRα, and Lysozyme.

Abstract A060: Dysregulation of PTEN expression in a subset of Cancer Associated Fibroblasts by Tumor Secreted Factors in PDAC

Abstract Pancreatic Ductal Adenocarcinoma (PDAC) is a deadly malignancy. Cancer associated fibroblasts (CAFs) play a complex role in the PDAC tumor microenvironment (TME), with a subset contributing significantly to tumor progression. Phosphatase and tensin homolog (PTEN) is a tumor suppressor and its loss is associated with increased tumor aggressiveness. Our group previously demonstrated PTEN loss in SMA+ positive CAFS correlated with worsened outcomes in patients and in mouse PDAC models. Our group previously demonstrated the loss of PTEN in CAFS led to activation of Stat3, resulting in an immunosuppressive microenvironment (Lefler et al, 2022 PMID: 35803738). However, little is known of the signals produced by tumor cells or other cell types in the TME that trigger loss of PTEN in CAFs. This study aims to to elucidate the molecular mechanisms underlying PTEN loss in CAFs in PDAC. To address this gap, we employed single cell RNA sequencing of tumors from a mouse PDAC model and identified a (PDRGFRa+Lys6+Stat3+Pten-low) CAF subpopulation. Comparing normal pancreas epithelial cells to tumor cells in this data set, we identified the IL6 family of cytokines, (IL6; Oncostatin-M, OSM; and Leukemia Inhibitory Factor, LIF) and Transforming Growth Factor beta 1 (TGFb1) as potential ligands that regulated PTEN, while myeloid cells were a source of the IL6 family member Oncostatin M (OSM). Treatment of isolated CAFs with these factors revealed no significant difference in PTEN mRNA expression. Thus, we developed an in vitro reporter system in which a PTEN-GFP fusion protein is expressed in CAFs. Treating these CAFs with IL6, OSM and TGFb1 (but not LIF) led to a significant decrease in GFP fluorescence. Analysis of endogenous PTEN by western blot confirmed these results. We posited that expression of PTEN E3 ligases might be increased by treatment with these factors, leading to destruction of PTEN. In support of this hypothesis, the expression of E3 ligases WWP1 and WWP2 was increased by treatment with IL6 and OSM. Additionally, preliminary data has revealed that PTEN is oxidized in isolated CAFs, which causes loss of PTEN activity and potentially increased protein turnover. Current experiments are aimed at testing these potential mechanisms. To conclude, PTEN is dysregulated post-transcriptionally in CAFs. The mechanism of PTEN dysregulation could be via increased expression of E3 ligases that target PTEN and/or PTEN oxidation. Future efforts will be aimed at testing whether inhibition of these pathways can restore PTEN expression in mouse PDAC models. These pathways and interactions could be further exploited for therapeutic benefit in curbing PDAC progression. Citation Format: Ivo N. Woogeng, Lu Han, Samaneh Saberi, Cameron Bumbleburg, Joseph Beaudet, Sudarshana Sharma, Michael Ostrowski. Dysregulation of PTEN expression in a subset of Cancer Associated Fibroblasts by Tumor Secreted Factors in PDAC [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr A060.

Zein spray-dried microparticles loaded with chemically modified curcumin for active wound healing

Wound healing is a delicate process comprising various phases, of which inflammation constitutes the most critical one, as some wounds fail to evolve from this state due to pre-existing pathologies or medical conditions, becoming chronic and causing pain and serious consequences for the patients. Given this context, innovative strategies able to support the body in the transition through the inflammatory and the proliferative phases are needed. Here, we propose to deliver to the wound zein microparticles (ZμP) loaded with chemically modified curcumin (mCUR), a novel bioactive molecule with strong antioxidant properties. Derived from the classic curcumin, mCUR chemical structure has been modified with an amino phenyl carbonyl group on C4 to overcome the poor bioavailability in the human body and to reach stronger inhibition of inflammatory markers thanks to a higher in vitro efficacy (lower IC50). ZμP were fabricated via spray drying starting from various zein/mCUR ratios. An exhaustive characterization of the physico-chemical properties of ZμP, either empty or loaded, has been carried out, alongside with bioactivity assessments via human keratinocytes and Escherichia coli cultures. All the formulations presented average diameters of 1 μm, resulted biocompatible, and led to an encapsulation efficiency in the range of 78.1–83.0 %. Finally, antioxidant properties of loaded microparticles were assessed via DCFH-DA assay, where a fluorescence decrease proportional to mCUR concentration was clearly visible (down to 41.7 %). These promising results highlight our formulations’ ability to reduce oxidative stress inside the cells, representing a promising strategy to address the problem of chronic wounds, supporting the body in overcoming the inflammatory stage.

Fluorogenic Monitoring of α-Amylase in Human Urine for Straightforward Diagnosis of Pancreatic Diseases.

In this study, we developed a sensitive method for monitoring α-amylase using a fluorogenic approach based on the host-guest complexation between an amphiphilic pyrenyl derivative (1) and γ-cyclodextrins (γ-CDs). The compound 1 self-assembles into nanofibrils in aqueous solutions. Upon the introduction of γ-CD, compound 1 forms an inclusion complex with it. This complex then participates in the formation of a 2 : 2 complex with another complex, leading to strong excimer fluorescence. Upon interaction with α-amylase, γ-CD undergoes hydrolysis, leading to the regeneration of nanofibrils, which is accompanied by a decrease in excimer fluorescence and an increase in monomeric fluorescence. This ratiometric fluorescence color change enables the sensitive detection of low levels of α-amylase in human urine, offering a practical approach for early screening of pancreatic-related diseases.

Fluorescence Turn-Off Ligand for Parallel G-Quadruplexes.

Parallel-stranded G-quadruplex structures are found to be common in the human promoter sequences. We tested highly fluorescent 9-methoxyluminarine ligand (9-MeLM) binding interactions with different parallel G-quadruplexes DNA by spectroscopic methods such as fluorescence and circular dichroism (CD) titration as well as UV melting profiles. The results showed that the studied 9-MeLM ligand interacted with the intramolecular parallel G-quadruplexes (G4s) with similar affinity. The binding constants of 9-methoxyluminarine with different parallel G4s were determined. The studies upon oligonucleotides with different flanking sequences on c-MYC G-quadruplex suggest that 9-methoxyluminarine may preferentially interact with 3'end of the c-MYC promoter. The high decrease in 9-MeLM ligand fluorescence upon binding to all tested G4s indicates that 9-methoxyluminarine molecule can be used as a selective fluorescence turn-off probe for parallel G-quadruplexes.

Unveiling Cellular Microenvironments with a Near-Infrared Fluorescent Sensor: A Dual-Edge Tool for Cancer Detection and Drug Screening.

Mitochondria and lysosomes are pivotal intracellular organelles, and the injury or dysfunction of these organelles can trigger a range of pathological processes. Early diagnosis and treatment of cancer are of paramount importance due to cancer's status as a leading health threat. This study introduces a novel fluorescent probe, BDHV, for detecting mitochondrial and lysosomal viscosity and pH abnormalities in tumors, facilitating early cancer detection and screening of anticancer drugs. Under acidic conditions, the red fluorescence of the probe gradually increases with increasing viscosity. Conversely, in alkaline environments, an increase in viscosity leads to a decrease in green fluorescence and an increase in red fluorescence. The inclusion of a benzothiazole group endows BDHV with strong dual-targeting capability for mitochondria and lysosomes and without being affected by the mitochondrial membrane potential. Most notably, BDHV has potential applications for early cancer diagnosis and in effectively assessing the efficacy of various anticancer drugs.

Light green leaf sectors of variegated Dracaena fragrans plants show similar rates of oxygenic photosynthesis tо that of normal, dark green leaf sectors

Adaptation and functional significance of chlorophyll deficit in the light green leaf sectors of variegated plants are little known. Efficiency of photosystem II for dark and light adapted states (Fv/Fm and ΔF/Fm’) and fluorescence decrease rates (Rfd) of light green leaf sectors of Dracaena fragrans L. were studied by methods of PAM-fluorometry and video registration. In addition, white light reflectance and transmittance of these leaf sectors were measured using an integrating sphere. Absorption was calculated from reflectance and transmittance. Net CO2 assimilation rates (PN) were measured using a flow chamber and photolytic O2 evolution rates (PAYO2) were studied by a novel method of Fourier photoacoustics which is insensitive to respiration, photorespiration and other processes of O2 uptake. All the photosynthetic parameters (Fv/Fm, ΔF/Fm’, PN and PAYO2) were found to be very close between light green and normal green leaf sectors, whereas chlorophyll content and light absorption were 7.5-fold and 1.47-fold different respectively. Contradiction between low chlorophyll absorption and high (as in normal green sectors) rate of oxygenic photosynthesis in light-green sectors was proposed to be a consequence of different contribution of cyclic electron transport around PSII (CET-PSII) and/or around PSI (CET-PSI) in the total photosynthesis occurring in these sectors. Particularly, it cannot be excluded, that some part of CET activity occurring in normal green leaf sectors may be lost in the light green sectors retaining the same linear (non-cyclic) electron transport (LET) activity as in normal green sectors.

Impact of Different Inoculum Levels of Cereal Cyst Nematode (Heterodera avenae) on the Physiological Traits of Wheat (Triticum aestivum)

This study aimed to examine the effects of various inoculum levels of H. avenae on wheat physiology. The experiments were conducted in the screenhouse at the Department of Nematology, CCSHAU, Hisar, with inoculum levels set at 5, 10, and 15 eggs and juveniles per gram of soil. Observations on physiological parameters were made 30 days post-sowing. It was found that increasing inoculum levels led to significant decreases in total chlorophyll, carotenoid content, chlorophyll fluorescence, photosynthetic rate, transpiration rate, and stomatal conductance. The highest inoculum level showed the most pronounced reductions, with respective decreases of 39.71%, 30.55%, 7.90%, 39.75%, 51.58%, and 64.86%. Highest nematode inoculum level also resulted in the highest reduction in gaseous exchange parameters, biomass and leaf pigments concentrations and maximum increment in nematode population density.

PH-Sensitive Fluorescent Marker Based on Rhodamine 6G Conjugate with Its FRET/PeT Pair in "Smart" Polymeric Micelles for Selective Imaging of Cancer Cells.

Cancer cells are known to create an acidic microenvironment (the Warburg effect). At the same time, fluorescent dyes can be sensitive to pH, showing a sharp increase or decrease in fluorescence depending on pH. However, modern applications, such as confocal laser scanning microscopy (CLSM), set additional requirements for such fluorescent markers to be of practical use, namely, high quantum yield, low bleaching, minimal quenching in the cell environment, and minimal overlap with auto-fluorophores. R6G could be the perfect match for these requirements, but its fluorescence is not pH-dependent. We have attempted to develop an R6G conjugate with its FRET or PeT pair that would grant it pH sensitivity in the desired range (5.5-7.5) and enable the selective targeting of tumor cells, thus improving CLSM imaging. Covalent conjugation of R6G with NBD using a spermidine (spd) linker produced a pH-sensitive FRET effect but within the pH range of 7.0-9.0. Shifting this effect to the target pH range of 5.5-7.5 appeared possible by incorporating the R6G-spd-NBD conjugate within a "smart" polymeric micelle based on chitosan grafted with lipoic acid. In our previous studies, one could conclude that the polycationic properties of chitosan could make this pH shift possible. As a result, the micellar form of the NBD-spd-R6G fluorophore demonstrates a sharp ignition of fluorescence by 40%per1 pH unit in the pH range from 7.5 to 5. Additionally, "smart" polymeric micelles based on chitosan allow the label to selectively target tumor cells. Due to the pH sensitivity of the fluorophore NBD-spd-R6G and the selective targeting of cancer cells, the efficient visualization of A875 and K562 cells was achieved. CLSM imaging showed that the dye actively penetrates cancer cells (A875 and K562), while minimal accumulation and low fluorophore emission are observed in normal cells (HEK293T). It is noteworthy that by using "smart" polymeric micelles based on polyelectrolytes of different charges and structures, we create the possibility of regulating the pH dependence of the fluorescence in the desired interval, which means that these "smart" polymeric micelles can be applied to the visualization of a variety of cell types, organelles, and other structures.

Near-infrared fluorescent probe for ultrasensitive detection of organophosphorus pesticides and visualization of their interaction with butyrylcholinesterase in living cells

The toxicity of organophosphorus pesticides (OPs) can catastrophically cause liver cell damage and inhibit the catalytic activity of cholinesterase. We designed and synthesized a near-infrared fluorescent probe HP-LZB with large Stokes shift which can specifically identify and detect butyrylcholinesterase (BChE) and visually explore the interaction between OPs and endogenous BChE in living cells. Fluorescence was turned on when HP-LZB was hydrolyzed into HP-LZ in the presence of BChE, and OPs could inhibit BChE's activity resulting in a decrease of fluorescence. Six OPs including three oxon pesticides (paraoxon, chlorpyrifos oxon and diazoxon) and their corresponding thion pesticides (parathion, chlorpyrifos and diazinon) were investigated. Both in vitro and cell experiments indicated that only oxon pesticides could inhibit BChE's activity. The limits of detection (LODs) of paraoxon, chlorpyrifos oxon and diazoxon were as low as 0.295, 0.007 and 0.011 ng mL−1 respectively and the recovery of OPs residue in vegetable samples was satisfactory. Thion pesticides themselves could hardly inhibit the activity of BChE and are only toxic when they are converted to their corresponding oxon form in the metabolic process. However, in this work, thion pesticides were found not be oxidized into their oxon forms in living HepG2 cells due to the lack of cytochrome P450 in hepatoma HepG2 cell lines. Therefore, this probe has great application potential in effectively monitoring OPs in real plant samples and visually exploring the interaction between OPs and BChE in living cells.

A new sol-gel fluorescent sensor to track carbonyl compounds

Carbonyl compounds are ubiquitous quality trackers that provide information about food product degradation as well as air and water pollution levels. In addition, they are used as biomarkers for medical diagnoses. With more user-friendly sensors, their fast detection and easy quantification are highly relevant. The synthesis, characterization, and performance assessment of a new sensor based on aniline fluorescence to monitor carbonyls in real time is reported. A cost-effective synthesis using a straightforward sol-gel process led to the construction of a nontoxic silica-based material with high porosity, which can be used with almost no sample preparation. The material exhibits a rapid (< 1 min) fluorescence decrease upon interaction with carbonyl groups. The limit of detection is as low as ca. 5 × 10−4 mol·L−1 for hexanal, while fluorescence extinction occurs at much higher concentrations (5 × 10−1·mol L−1), which enables the sensor to be used with a very broad range of detection. Real-time monitoring is possible since the fluorescence loss correlates with the concentration of carbonyl moieties. The performance was validated in simulating as well as in real media, making this sensor suitable for use in a wide range of applications.

Doxorubicin as a Drug Repurposing for Disruption of α-Chymotrypsinogen-A Aggregates.

Protein conformation is affected by interaction of several small molecules resulting either stabilization or disruption depending on the nature of the molecules. In our earlier communication, Hg2+ was known to disrupt the native structure of α-Cgn A leading to aggregation (Ansari, N.K., Rais, A. & Naeem, A. Methotrexate for Drug Repurposing as an Anti-Aggregatory Agent to Mercuric Treated α-Chymotrypsinogen-A. Protein J (2024). https://doi.org/10.1007/s10930-024-10187-z ). Accumulation of β-rich aggregates in the living system is found to be linked with copious number of disorders. Here, we have investigated the effect of varying concentration of doxorubicin (DOX) i.e. 0-100 µM on the preformed aggregates of α-Cgn A upon incubation with 120 µM Hg2+. The decrease in the intrinsic fluorescence and enzyme activity with respect to increase in the Hg2+ concentration substantiate the formation of aggregates. The DOX showed the dose dependent decrease in the ThT fluorescence, turbidity and RLS measurements endorsing the dissolution of aggregates which were consistent with red shift in ANS, confirming the breakdown of aggregates. The α-Cgn A has 30% α-helical content which decreases to 3% in presence of Hg2+. DOX increased the α-helicity to 28% confirming its anti-aggregatory potential. The SEM validates the formation of aggregates with Hg2+ and their dissolution upon incubation with the DOX. Hemolysis assay checked the cytotoxicity of α-Cgn A aggregates. Docking revealed that the DOX interacted Lys203, Cys201, Cys136, Ser159, Leu10, Trp207, Val137 and Thr134 of α-Cgn A through hydrophobic interactions and Gly133, Thr135 and Lys202 forms hydrogen bonds.

Benzothiazole-Quinoline-Based Fluorescent Probe for Fe3+ and its Applications in Environmental and Biological Samples.

Due to the its high abundance, iron ion contamination and toxicity is one of the most challenging issue for living beings. Although, iron is extremenly important for several body functions, excess amount of iron in the body can also be fatal. In last century, rapid industrialization, iron extraction and mismanagement of industrial waste disposal leads to iron contamination in water bodies. Therefore, versatile iron sensors needs to be develop which can be employed for detection in biological as well as real water samples. 8-hydroxyquinoline is well-known for its strong affinity towards transition metals including Fe3+. In this regard, we have synthesised benzothiazole-quinoline derived 1,2,3- triazole (4HBTHQTz), in which 4-(benzo[d]thiazol-2-yl)phenolic (4-HBT) group acts as a fluorophore. 4HBTHQTz showed high fluorescence and induced a selective decrease in fluorescence with Fe3+ at 380nm (λex. = 320nm). The detection limit of 4HBTHQTz with Fe3+ is calculated as 0.64μM, which is lower than the WHO recommended limit in drinking water. 4HBTHQTz works over the 5-8 pH range and has shown promising results for quantitative detection of Fe3+ in water samples collected from tap, river and seawater. 4HBTHQTz can also detect the Fe3+ in biological samples which is confirmed by fluorescence cell imaging using L929 mouse fibroblast cells. Overall, 4HBTHQTz showed advantages such as high selectivity, quick detection, and good limit of detection (LOD) for Fe3+.

Unraveling the enigma: Probing the unconventional binding site and binding mechanism of entrectinib with human serum albumin through spectroscopic, molecular docking, and dynamic simulation analyses

Entrectinib (ENB), a novel potent tyrosine kinase inhibitor, has demonstrated promising activity against specific genetic alterations in various solid tumors. Investigating the interaction of ENB with human serum albumin (HSA) provides valuable insights into its binding characteristics and pharmacological behavior. The interaction between ENB and HSA was investigated using various spectroscopic techniques, molecular docking, and simulations approaches. Fluorescence spectroscopy revealed a consistent decrease in the intrinsic fluorescence of HSA upon binding to ENB, indicating a static binding mechanism. The binding constant calculated from Stern Volmer and double-log equations (KSV) and (K) were determined to be 4.11 x104 M−1 and 4.38 x104 M−1, respectively at 298 K, indicating moderate binding affinity. Thermodynamic analysis demonstrated a spontaneous interaction (ΔG < 0) with an enthalpy change (ΔH) of −5.59 kJ mol−1 and an entropy change (ΔS) of + 70.36 J mol−1 K−1, indicating that the interaction is primarily driven by electrostatic forces with potential involvement of hydrogen bonding. Synchronous and 3D fluorescence analysis indicated no significant changes in the microenvironment surrounding Tyr and Trp residues upon ENB binding. Near and far UV spectrophotometric analyses confirmed the formation of the ENB-HSA complex and suggested no conformational changes in the protein structure. Fluorescence measurements and binding competition analysis using site markers revealed that ENB selectively binds to the HSA Sudlow sites I and III, displacing phenylbutazone at both sites. Molecular docking studies confirmed the binding of ENB to Sudlow sites I and III and identified critical residues involved in the interaction. Molecular dynamics simulations further validated the stability of the ENB-HSA complex at both sites, with more favorable binding at site III, and minimal fluctuations observed in the root mean square deviation, root mean square fluctuation, and radius of gyration. Hydrogen bond analysis and solvent accessible surface area calculations supported the strong binding and accessibility of ENB within the HSA structure. Overall, the experimental and computational results provided valuable insights into the ENB-HSA interaction, elucidating the binding mechanism and key residues involved.

Image Sensing of Gaseous Acetone Using Secondary Alcohol Dehydrogenase-Immobilized Mesh for Exhaled Air.

Human-borne acetone is a potent marker of lipid metabolism. Here, an enzyme immobilization method for secondary alcohol dehydrogenase (S-ADH), which is suitable for highly sensitive and selective biosensing of acetone, was developed, and then its applicability was demonstrated for spatiotemporal imaging of concentration distribution. After various investigations, S-ADH-immobilized meshes could be prepared with less than 5% variation by cross-linking S-ADH with glutaraldehyde on a cotton mesh at 40 °C for 15 min. Furthermore, high activity was obtained by adjusting the concentration of the coenzyme nicotinamide adenine dinucleotide (NADH) solution added to the S-ADH-immobilized mesh to 500 μM and the solvent to a potassium phosphate buffer solution at pH 6.5. The gas imaging system using the S-ADH-immobilized mesh was able to image the decrease in NADH fluorescence (ex 340 nm, fl 490 nm) caused by the catalytic reaction of S-ADH and the acetone distribution in the concentration range of 0.1-10 ppm-v, including the breath concentration of healthy people at rest. The exhaled breath of two healthy subjects at 6 h of fasting was quantified as 377 and 673 ppb-v, which were consistent with the values quantified by gas chromatography-mass spectrometry.

Design and synthesis of fluorescent BODIPY derivatives with D-A structure for cancer cell imaging

Boron-dipyrromethene (BODIPY) as a traditional fluorescent dye has received increasing attention because of its high molar extinction coefficient, easy modification, and good light stability. In this work, three BODIPY compounds (BDP-1, BDP-2 and BDP-3) were designed and synthesized by introducing PEG chains and a naphthalimide (NI) group onto the parent structure of BODIPY. Due to the electron-withdrawing properties of NI, the compounds of BDP-2 and BDP-3 formed a typical donor (D)-acceptor (A) structure, which led to the red-shifted absorption and fluorescence spectrum. The synthesized BODIPY exhibited intense green emission, with fluorescence quantum yield of 0.66, 0.29, and 0.19 for BDP-1, BDP-2 and BDP-3 respectively. The decrease in fluorescence of BDP-2 and BDP-3 was probably ascribed to the enhanced intramolecular charge transfer because of the introduction of the NI group. The good biocompatibility and low cytotoxicity of the synthesized BODIPY compounds were verified by the CCK-8 assay. The subcellular localization of the three compounds was further evaluated through a confocal laser scanning microscope. The results showed that these BODIPY derivatives were mainly localized in the lysosomes of cancer cells. Thus, the synthesized BODIPY fluorescent dyes show promising applications in tumor imaging benefiting from their good biocompatibility and strong fluorescence.

Enhanced aggregation induced emission by H-bond between the barbiturate molecules containing hydroxyl group

Barbiturates had been widely studied as a molecule with aggregation induced emission (AIE) phenomenon, but barbiturates as a group with multiple hydrogen bond donor and acceptor sites, the relationship between intermolecular hydrogen bond and AIE phenomenon has not been mainly studied. In this paper, a new barbiturate fluorescence molecule BNOH with hydroxyl group was designed and synthesized in order to analyze the relationship between hydrogen bond and molecular AIE phenomenon by increasing the functional group (–OH) that was easy to form hydrogen bond. By spectroscopic analysis, BNOH had structural torsion in aqueous mixed solution, which led to fluorescence decrease, while in aprotic mixed solvent, there was strong AIE phenomenon. DFT and TD-DFT calculations at the B3LYP/6-31G (d) were performed for a deeper understanding of optical transitions. In addition, in order to investigate the difference of its fluorescence phenomenon, two other barbiturate derivatives were synthesized and their spectra were compared with BNOH. The relationship between hydrogen bond and AIE phenomenon of barbiturates was proved, and the fluorescence mechanism of BNOH in organic solvent was proposed and determined. We believe that this study will not only increase the understanding of barbiturate AIE compounds, but also contribute to the study of the important role of hydrogen bonds in the fluorescence phenomenon of barbiturate AIE compounds.

Red-emitting ratiometric fluorescent metal-free CO-releasing molecule triggered by visible light for controllable and trackable CO delivery and efficient treatment of cutaneous wounds

CO is a highly toxic gas but also an important gasotransmitter in the human body that regulates cell functions and shows great therapeutic effects in clinical trials. Due to the unsafe nature of directly inhaling CO gas, the controllable and trackable release and delivery of CO are currently the key and main challenges in achieving CO therapy. In this work, we developed a novel red-emitting fluorescent metal-free CO-releasing molecule (CORM) named COR-FC that can be used to release CO under visible light irradiation and deliver CO in cells safely, accompanied by ratiometric fluorescence changes. COR-FC combines coumarin and 3-hydroxy flavonoid fluorophores and shows low cytotoxicity. Under the light irradiation of 460 nm, COR-FC undergoes rapid photolysis to release CO, accompanied by a decrease in fluorescence at 630 nm and a significant enhancement in fluorescence at 520 nm. More importantly, COR-FC can release CO in cells and tissues under visible light illumination, which provides a new metal-free CORM achieving precise control with self-fluorescence tracking. The released CO showed good anti-inflammatory effects and was successfully used to promote wound healing, indicating that COR-FC has the potential to be further applied in the biomedical field.

Isolation of a persistently quiescent muscle satellite cell population.

Although studies have identified characteristics of quiescent satellite cells (SCs), their isolation has been hampered by the fact that the isolation procedures result in the activation of these cells into their rapidly proliferating progeny (myoblasts). Thus, the use of myoblasts for therapeutic (regenerative medicine) or industrial applications (cellular agriculture) has been impeded by the limited proliferative and differentiative capacity of these myogenic progenitors. Here we identify a subpopulation of satellite cells isolated from mouse skeletal muscle using flow cytometry that is highly Pax7-positive, exhibit a very slow proliferation rate (7.7 ± 1.2 days/doubling), and are capable of being maintained in culture for at least 3 mo without a change in phenotype. These cells can be activated from quiescence using a p38 inhibitor or by exposure to freeze-thaw cycles. Once activated, these cells proliferate rapidly (22.7 ± 0.2 h/doubling), have reduced Pax7 expression (threefold decrease in Pax7 fluorescence vs. quiescence), and differentiate into myotubes with a high efficiency. Furthermore, these cells withstand freeze-thawing readily without a significant loss of viability (83.1 ± 2.1% live). The results presented here provide researchers with a method to isolate quiescent satellite cells, allowing for more detailed examinations of the factors affecting satellite cell quiescence/activation and providing a cell source that has a unique potential in the regenerative medicine and cellular agriculture fields.NEW & NOTEWORTHY We provide a method to isolate quiescent satellite cells from skeletal muscle. These cells are highly Pax7-positive, exhibit a very slow proliferation rate, and are capable of being maintained in culture for months without a change in phenotype. The use of these cells by muscle researchers will allow for more detailed examinations of the factors affecting satellite cell quiescence/activation and provide a novel cell source for the regenerative medicine and cellular agriculture fields.