Real-time imaging of alkaline phosphatase activity of diabetes in mice via a near-infrared fluorescent probe.

A novel water-soluble near-infrared fluorescent probe named QX-P with simple synthesis is developed. QX-P has high sensitivity and selectivity to ALP. Moreover, the probe can not only visualize ALP activity in four cell lines, but also real-time image ALP activity during the diagnosis and treatment of diabetes in mice.

A mitochondria-targeting nitroreductase fluorescent probe with large Stokes shift and long-wavelength emission for imaging hypoxic status in tumor cells.

Development of a mitochondria-targeting fluorescent probe with large Stokes shift and long-wavelength emission was benefit for accurate detection of hypoxic status, which was known as a major factor of the tumor physiology and influence important pathological processes. However, an efficient optical approach for simultaneously achieving such merits was still lacking. In this work, a turn-on fluorescence probe (HBT-NP) was designed to assess the hypoxic condition of tumor cells by detecting nitroreductase (NTR). Probe HBT-NP was constructed by conjugating 4-nitrobenzyl moiety as reaction site for NTR to 2-(benzo[d]thiazol-2-yl)-4-methylphenol derived fluorescent dye HBT-Py which demonstrated large Stokes shift (Δλ = 243 nm) and long wavelength emission (λem = 640 nm) due to intrinsic mechanism of ESIPT together with ICT process. Upon incubated with NTR, HBT-NP could successively undergo nitro reduction reaction and then release HBT-Py. The reaction mechanism was further confirmed by mass spectra and HPLC analysis, and the docking calculation also indicated that the binding mode and docking affinity of probe HBT-NP with NTR play an important role in catalytic reduction reaction process. As a result, HBT-NP displayed a wide linear range (0.1-1.5 µg/mL) and low detection limit (2.8 ng/mL) response to NTR, and could be used to evaluate hypoxic condition of cancer cells with precise mitochondria-targeting.

Simultaneous imaging of mitochondrial viscosity and hydrogen peroxide in Alzheimer's disease by a single near-infrared fluorescent probe with a large Stokes shift.

It has been speculated that both the intracellular viscosity and H2O2 level in Alzheimer's disease (AD) brains are higher than that in healthy brains, but direct evidence from living beings is scarce. Herein, we report a NIR emissive fluorescent probe with a large Stokes shift for the associated detection of mitochondrial viscosity and H2O2 in live rat brains with AD for the first time.

A fluorescent probe based on aggregation-induced emission for hydrogen sulfide-specific assaying in food and biological systems.

A fluorescent probe based on a triphenylamine benzopyridine platform for hydrogen sulfide (H2S) assaying has been designed and synthesized. As a result of the H2S-triggered cleavage reaction, the disappearance of the quenching effect of dinitrophenyl and the increased hydrophobicity in a poor solvent lead to the aggregation-induced emission (AIE) effect; consequently an obvious 'turn-on' fluorescence signal can be observed in this process. The probe TPANF features high selectivity towards H2S, low detection limit (0.17 µM), and good photostability and biocompatibility. Moreover, it has been successfully utilized to monitor H2S in food samples to distinguish the extent of food deterioration and to identify the H2S concentration variation in living cells. In addition, endogenous H2S in HCT-116 xenograft tumor tissues was imaged by using this probe. The approach could provide useful insight for the development of other activatable AIE-based probes that are potentially helpful for specific assaying in food chemistry and biological systems.

Dicyanoisophorone-Based Near-Infrared-Emission Fluorescent Probe for Detecting NAD(P)H in Living Cells and in Vivo.

NADH and NADPH are ubiquitous coenzymes in all living cells that play vital roles in numerous redox reactions in cellular energy metabolism. To accurately detect the distribution and dynamic changes of NAD(P)H under physiological conditions is essential for understanding their biological functions and pathological roles. In this work, we developed a near-infrared (NIR)-emission fluorescent small-molecule probe (DCI-MQ) composed of a dicyanoisophorone chromophore conjugated to a quinolinium moiety for in vivo NAD(P)H detection. DCI-MQ has the advantages of high water solubility, a rapid response, extraordinary selectivity, great sensitivity (a detection limit of 12 nM), low cytotoxicity, and NIR emission (660 nm) in response to NAD(P)H. Moreover, the probe DCI-MQ was successfully applied for the detection and imaging of endogenous NAD(P)H in both living cells and tumor-bearing mice, which provides an effective tool for the study of NAD(P)H-related physiological and pathological processes.

Cytotoxicity and genotoxicity of a trypanocidal drug quinapyramine sulfate loaded-sodium alginate nanoparticles in mammalian cells.

We synthesized quinapyramine sulfate loaded-sodium alginate nanoparticles (QS-NPs) to reduce undesirable toxic effects of QS against the parasite Trypanosoma evansi, a causative agent of trypanosomosis. To determine the safety of the formulated nanoparticles, biocompatibility of QS-NPs was determined using Vero, Hela cell lines and horse erythrocytes in a dose-dependent manner. Our experiments unveiled a concentration-dependent safety/cytotoxicity (metabolic activity), genotoxicity (DNA damage, chromosomal aberrations), production of reactive oxygen species and hemolysis in QS-NPs treated cells. Annexin-V propidium iodide (PI) staining showed no massive apoptosis or necrosis. However, at very high doses (more than 300 times than the effective doses), we observed more toxicity in QS-NPs treated cells as compared to QS treated cells. QS-NPs were safe at effective trypanocidal doses and even at doses several times higher than the effective dose.

Knockdown of the small conductance Ca(2+) -activated K(+) channels is potently cytotoxic in breast cancer cell lines.

BACKGROUND AND PURPOSE: Small conductance calcium-activated potassium (KCa 2.x) channels have a widely accepted canonical function in regulating cellular excitability. In this study, we address a potential non-canonical function of KCa 2.x channels in breast cancer cell survival, using in vitro models. EXPERIMENTAL APPROACH: The expression of all KCa 2.x channel isoforms was initially probed using RT-PCR, Western blotting and microarray analysis in five widely studied breast cancer cell lines. In order to assess the effect of pharmacological blockade and siRNA-mediated knockdown of KCa 2.x channels on these cell lines, we utilized MTS proliferation assays and also followed the corresponding expression of apoptotic markers. KEY RESULTS: All of the breast cancer cell lines, regardless of their lineage or endocrine responsiveness, were highly sensitive to KCa 2.x channel blockade. UCL1684 caused cytotoxicity, with LD50 values in the low nanomolar range, in all cell lines. The role of KCa 2.x channels was confirmed using pharmacological inhibition and siRNA-mediated knockdown. This reduced cell viability and also reduced expression of Bcl-2 but increased expression of active caspase-7 and caspase-9. Complementary to these results, a variety of cell lines can be protected from apoptosis induced by staurosporine using the KCa 2.x channel activator CyPPA. CONCLUSIONS AND IMPLICATIONS: In addition to a well-established role for KCa 2.x channels in migration, blockade of these channels was potently cytotoxic in breast cancer cell lines, pointing to modulation of KCa 2.x channels as a potential therapeutic approach to breast cancer.

Small Quaternary Inhibitors K298 and K524: Cholinesterases Inhibition, Absorption, Brain Distribution, and Toxicity.

UNLABELLED: Inhibitors of acetylcholinesterase (AChE) may be used in the treatment of various cholinergic deficits, among them being myasthenia gravis (MG). This paper describes the first in vivo data for promising small quaternary inhibitors (K298 and K524): acute toxicity study, cholinesterase inhibition, absorption, and blood-brain barrier penetration. The newly prepared AChE inhibitors (bis-quinolinium and quinolinium compounds) possess a positive charge in the molecule which ensures that anti-AChE action is restricted to peripheral effect. HPLC-MS was used for determination of real plasma and brain concentration in the pharmacokinetic part of the study, and standard non-compartmental analysis was performed. The maximum plasma concentrations were attained at 30 min (K298; 928.76 ± 115.20 ng/ml) and 39 min (K524; 812.40 ± 54.96 ng/ml) after i.m. APPLICATION: Both compounds are in fact able to target the central nervous system. It seems that the difference in the CNS distribution profile depends on an active efflux system. The K524 brain concentration was actively decreased to below an effective level; in contrast, K298 progressively accumulated in brain tissue. Peripheral AChE inhibitors are still first-line treatment in the mild forms of MG. Commonly prescribed carbamates have many severe side effects related to AChE carbamylation. The search for new treatment strategies is still important. Unlike carbamates, these new compounds target AChE via apparent π-π or π-cationic interaction aside at the AChE catalytic site.

6-Hydroxyquinolinium salts differing in the length of alkyl side-chain: synthesis and antimicrobial activity.

Quaternary ammonium salts substituted with a long alkyl chain exemplify a trustworthy group of medicinal compounds frequently employed as antifungal and antibacterial agents. A great asset of these surfactants underlying their widespread use is low local and system toxicity in humans. In this Letter, a series of novel quaternary 6-hydroxyquinolinium salts with varying length of N-alkyl chain (from C10 to C18) was synthesized and tested for in vitro activity against pathogenic bacterial and fungal strains. 6-Hydroxyquinolinium salt with C12 alkyl chain seems to be very interesting candidate due to a high antimicrobial efficacy and cytotoxic safety.

DNA alkylation with N-methylquinolinium quinone methide to N2-dG adducts resulting in extensive stops in primer extension with DNA polymerases and subsequent suppression of GFP expression in A549 cells.

Quinone methides (QMs) are involved in the metabolism of many drugs and carcinogens as reactive intermediates to form covalent nucleobase adducts in DNA that associate with high mutagenicity. Recently, a plethora of synthetic QM DNA alkylating agents have been developed to form various nucleobase adducts as potential antitumor agents. However, the mutagenic potential of these synthetic QM alkylating agents has not been fully investigated. In this report, N-methylquinolinium QM was developed as a synthetic model to study biological consequences of the formation of nucleobase adducts in a DNA target. N-Methylquinolinium QM was generated in situ via an elimination process from a bis-quaternary ammonium precursor that was synthesized from a quinoline derivative. Alkylation with N-methylquinolinium QM on a DNA target produced mostly a stable N(2)-dG adduct as revealed by gel electrophoresis and DNA digestion assays and confirmed by mass and NMR analyses. The formation of N(2)-dG adducts of a DNA target was found to cause extensive stops in the primer extension with high fidelity DNA polymerase T7 and even low fidelity error prone Dpo4. The direct biological impact of a prealkylated green fluorescence protein plasmid with N-methylquinolinium QM was demonstrated as significant suppression of protein expression in A549 cells. Overall, our results suggested that nucleobase-QM adducts could potentially block nucleobase mismatch/translesion in the error-prone process to reduce the mutagenic potential if designed carefully.

In vitro activity and preliminary toxicity of various diamidine compounds against Trypanosoma evansi.

Trypanosoma evansi is an animal pathogenic protozoan, causing a wasting disease called Surra, which is broadly distributed in a wide range of mammalian hosts. Chemotherapy is the most efficient control method, which depends on four drugs. Unfortunately, with the appearance of resistance to these drugs, their effective use is threatened, emphasising a need to find new drugs. Diamidines bind to the minor groove of DNA at AT-rich sites and exert their anti-trypanosomal activity by inhibiting one or more DNA dependent enzymes or by directly impeding the transcription process. In total, 67 novel diamidine compounds were tested in vitro to determine activity against an animal pathogenic Chinese kinetoplastic T. evansi strain. In comparison, a human pathogenic Trypanosoma brucei rhodesiense strain and a P2 transporter knock out of a Trypanosoma brucei brucei strain were also tested. All diamidine compounds tested in this study against T. evansi produced inhibitory concentration (IC(50)) values below 50 nM. The results demonstrate that these compounds are highly active against T. evansi in vitro. In addition, preliminary in vivo toxicity tests were performed on all 67 diamidines with 69% of the compounds showing no acute toxicity at an intra-peritoneal dose of 100mg/kg.

Biological properties of 4-methyl-2,7-diamino-5,10-diphenyl-4,9-diazapyrenium hydrogensulfate (ADAP).

OBJECTIVE: 4-Methyl-2,7-diamino-5,10-diphenyl-4,9-diazapyrenium hydrogensulfate (ADAP) is a potential antitumor compound because of its DNA and RNA intercalating ability. In this study, cellular uptake, intracellular distribution as well as mechanism of action, antitumor activity in vitro and toxicity in vivo of ADAP were investigated. METHODS: Based on the fluorescence properties of ADAP, its entry and distribution into live cells were analyzed by fluorescence microscopy. The in vitro antiproliferative activity was determined using MTT test. For screening of topoisomerase II-targeted effects of ADAP, the cell-free assay and immunoband depletion assay were used. Expression of the genes c-mos, c-N-ras, c-Ki-ras, c-H-ras, p53 and caspase 3 in Caco-2 cells treated with ADAP was examined by RT-PCR. Toxicity in vivo was determined using C3HHf/Bu Zgr/Hr mice treated by single or multiple doses of ADAP at a concentration of 25 mg/kg. RESULTS: ADAP in microM concentrations entered into MIAPaCa-2 cell's cytoplasm in 5 min and into nuclei in 60 min after administration. Intracellular distribution of ADAP depended on the period of treatment time. ADAP (0.1-100 microM) strongly inhibited the growth of both mouse (FsaR, SCCVII) and human tumor cells (HeLa, Caco-2, HT-29, MIAPaCa-2, HBL, HEp-2, SW620, MCF-7) compared to its weak cytotoxicity on controls and normal cells (WI38). Results of both topoisomerase II assays showed that ADAP is not a topoisomerase II poison. Expression of investigated genes was dependent on the incubation time, except for p53 and c-H-ras. Morphological changes in tissues and organs of mice were not observed. Results of patohistological analysis have been confirmed by hematological and clinical-chemical analysis of blood of treated and non-treated animals. CONCLUSION: ADAP is a strongly bioactive compound with antitumor potential in vitro. The antitumor potential in vivo remains to be identified.

(Q)SAR studies to design new human choline kinase inhibitors as antiproliferative drugs.

Most of the signal transduction pathways are mediated by protein kinases regulating every aspect of cell function. Mutations which deregulate their expression or their function or both result in cancers. Therefore, protein kinase inhibitors have become the focus of development of new therapies for cancer. A comprehensive review of Choline kinase (ChoK) was published by us in 2003. Since then, molecular information of ChoK inhibitors has been accumulated. In this review, we intend to summarize the new lines of evidence that will include the design of the most active antiproliferative agents so far described against ChoK. Studies have been aimed at the establishment of structure-activity relationships and the structural parameters that define ChoK inhibitory and antiproliferative activities of a set of twenty-five acyclic biscationic pyridophane and forty acyclic biscationic quinolinephane compounds. The corresponding QSAR equation was obtained for the whole set of bisquinolinium compounds for the antiproliferative activity, taking into consideration the electronic parameter sigma(R) of R(4), the molar refractivity (MR) of R(8), and the lipophilic parameters clog P and pi(linker). The most potent antiproliferative agent shows an IC(50) = 0.45 microM, predicted by the QSAR equation, whilst its experimental value is IC(50) = 0.20 microM. Finally, toxicity assays were performed for the most promising compounds because of their interesting antiproliferative activities [IC(50 HT-29) = 0.70, 0.80, 1.50 and 1.90 microM] and low toxicity [LD(50) = 16.7, 12.5, > 25 and > 20 mg/kg of mouse]. These biological activities justify further analysis for antitumoral assays under in vivo conditions.

Overexpression of Bcl-2 is associated with apoptotic resistance to the G-quadruplex ligand 12459 but is not sufficient to confer resistance to long-term senescence.

The triazine derivative 12459 is a potent G-quadruplex interacting agent that inhibits telomerase activity. This agent induces time- and dose-dependent telomere shortening, senescence-like growth arrest and apoptosis in the human A549 tumour cell line. We show here that 12459 induces a delayed apoptosis that activates the mitochondrial pathway. A549 cell lines selected for resistance to 12459 and previously characterized for an altered hTERT expression also showed Bcl-2 overexpression. Transfection of Bcl-2 into A549 cells induced a resistance to the short-term apoptotic effect triggered by 12459, suggesting that Bcl-2 is an important determinant for the activity of 12459. In sharp contrast, the Bcl-2 overexpression was not sufficient to confer resistance to the senescence-like growth arrest induced by prolonged treatment with 12459. We also show that 12459 provokes a rapid degradation of the telomeric G-overhang in conditions that paralleled the apoptosis induction. In contrast, the G-overhang degradation was not observed when apoptosis was induced by camptothecin. Bcl-2 overexpression did not modify the G-overhang degradation, suggesting that this event is an early process uncoupled from the final apoptotic pathway.

Fluorophore toxicity in mouse eggs and zygotes.

Ion-sensitive fluorophores are commonly used for quantitative measurements of intracellular ion concentrations. However, both the method of intracellular loading--which for many fluorophores involves endogenous esterase-mediated removal of hydrophobic groups such as acetoxymethyl esters (AM)--and fluorescence excitation of fluorophores in the cell, can produce toxic metabolites and reactive species. Techniques used to measure intracellular ion concentrations in mammalian eggs and embryos are being increasingly employed, yet little information is available about any detrimental effects of the use of fluorophores. We have therefore used in vitro fertilisation (IVF) to assess potential fluorophore toxicity in mouse eggs, and whole cell patch-clamp recordings to detect fluorophore-associated membrane damage in zygotes. Four fluorophores were examined: SNARF-1 and BCECF (pH indicators), Fura-2 (Ca2+) and MQAE (Cl-). Cleavage of AM groups alone had no effect either on the success of IVF or on membrane electrical properties of mouse zygotes. Intracellularly loaded BCECF, SNARF-1 and Fura-2 followed by fluorescence excitation were not cell-toxic under the conditions examined. In contrast, MQAE demonstrated significant toxicity both alone and in combination with fluorescence excitation.

DNA binding-independent anti-proliferative action of benzazolo[3,2-alpha]quinolinium DNA intercalators.

The proposed mechanism of action of the antineoplastic drug 3-nitrobenzothiazolo[3,2-alpha]quinolinium chloride (NBQ-2) involves its interaction with DNA by intercalation and inhibition of topoisomerase II activity by arresting the enzyme in a covalent cleavage complex. In an attempt to identify some structural determinants for activity and develop a molecular structure/cytotoxicity correlation, four new structural analogs of the antitumor NBQ-2 were prepared and their cytotoxic activity and DNA binding properties were investigated. The cytotoxic activity was evaluated against six different human tumor cell lines: U937, K-562, HL-60, HT-29, HeLa, and A431. The results showed that these new drugs elicit pronounced cytotoxic effects against U937, K-562, HL-60 and A431 while HeLa and HT-29 were less sensitive to the new drugs. This apparent selectivity was different to that of m-AMSA, a drug currently used for cancer treatment. Since the interaction of NBQ-2 to DNA by intercalation has been proposed as the initial step leading to its antineoplastic activity, DNA binding and changes in DNA contour length induced by the new NBQ-2 structural analogs were also investigated using calf thymus and human DNA. The drug, 7-(1-propenyl)-3-nitrobenzimidazolo[3,2-alpha]quinolinium chloride (NBQ-59) was the most cytotoxic agent of the analog series (IC50 = 16 microM for HL-60 cells), however, it demonstrated the weakest binding to DNA (Kint = 0.9 x 10[5] M-1 for calf thymus DNA). NBQ-59 was also found to be a poor intercalator into the DNA double helix. Therefore, our results suggest that DNA binding is not the primary mechanism of drug action for this family of compounds. In addition structural determinants important for cytotoxicity of the benzazolo quinolinium chlorides were suggested by our results. In particular, the nitro group in the 3 position does not seem to be necessary for bioactivity, while substitutions in the benzazolo moiety have striking effects on the biological activity of the drugs.

Trypanosoma evansi: measurement of pyruvate production as an indicator of the drug sensitivity of isolates in vitro.

In a previous study, three in vitro methods for the assessment of drug sensitivity among Trypanosoma evansi isolates were compared--a direct counting method, pyruvate production method and uptake of radiolabelled hypoxanthine. The pyruvate assay system, which measures the amount of pyruvate in the supernatant of growing populations of trypanosomes by a spectrophotometric method, was selected for further investigation with regard to its suitability for field studies. The effect of initial seeding density and incubation time on the growth of three stocks of T. evansi--TREU 1840 and TREU 1981 (suramin sensitive) and TREU 2136 (suramin resistant)--and drug sensitivities revealed by the pyruvate assay and direct counting were examined to optimise assay conditions. Maximum densities and pyruvate production achieved were not affected by varying the initial seeding densities in the range of 5 x 10(4)-5 x 10(5)/ml and had been reached after 48 hours incubation with one exception: Pyruvate levels continued to increase up to 72 hours in the suramin resistant stock. However, inhibition curves were affected by initial seeding density and incubation period. Results suggested that an initial seeding density of 1 x 10(5)/ml and an incubation time of 48 hours are optimal for the assay. Using these assay conditions, the isolates were screened against suramin, quinapyramine sulphate and Cymelarsan, the trypanocides used most commonly against T. evansi. This assay proved to be a relatively simple and cheap technique applicable to screening large numbers of isolates of differing sensitivities to trypanocidal drugs.

Cytotoxicity of dopamine-derived 6,7-dihydroxy-1,2,3,4-tetrahydroisoquinolines.

The in vivo effects of dopamine-derived alkaloids, 6,7-dihydroxy-1,2,3,4-tetrahydroisoquinolines, salsolinols, and their N-methylated derivatives on a dopaminergic cell model, clonal rat pheochromocytoma PC12h cells, were examined by culture in the presence of various concentrations of the agents. The effects were evaluated in comparison with those by 1,2,3,4-tetrahydroisoquinoline and its N-methylated derivatives. Among 1,2,3,4-tetrahydroisoquinolines, only N-methylisoquinolinium ion had cytotoxic effect on PC12h cells. In general, 6,7-dihydroxyisoquinolines had more potent cytotoxic effect than N-methylisoquinolinium ion, and they reduced protein amounts of PC12h cells at 100 microM and 1 mM concentration. The specific activity of tyrosine hydroxylase, the rate-limiting enzyme in dopamine biosynthesis, decreased with these isoquinolines at concentrations lower than those required to reduce the protein amount. The toxicity of N-methylated derivatives seems to be more potent than non-methylated isoquinolines. Salsolinols were proved to be accumulated in the mitochondrial fraction of the cells after 3 days in culture. N-methyl-1,2,3,4-tetrahydroisoquinoline depleted ATP from PC12h cells and it was prevented by preincubation with an inhibitor of type-A monoamine oxidase, clorgyline. These results indicate that N-methylated and oxidized derivatives of dopamine-derived alkaloids may be potent dopaminergic neurotoxins similar to 1-methyl-4-phenylpyridinium ion in the human brain and may induce Parkinson's disease after long years of accumulation.

Absence of mutagenicity of the antitumor drug 3-nitrobenzothiazolo[3,2-a]quinolinium chloride (NBQ) in the germ cells of Drosophila melanogaster males.

The antitumor drug, 3-nitrobenzothiazolo[3,2-a]quinolinium chloride (NBQ) was tested for genotoxicity with the sex-linked recessive lethal test by feeding Drosophila melanogaster males. Although toxic to adults, the drug tested negative at the concentrations studied.

Butyrylcholinesterase and acetylcholinesterase prophylaxis against soman poisoning in mice.

Human butyrylcholinesterase (BChE, EC 3.1.1.8) or acetylcholinesterase (AChE, EC 3.1.1.7) from fetal bovine serum (FBS), administered i.v. in mice, sequestered at approximately 1:1 stoichiometry the highly toxic anti-ChE organophosphate, 1,2,2-trimethylpropyl methyl-fluorophosphonate (soman). A quantitative linear correlation was demonstrated between blood-ChE levels and the protection conferred by exogeneously administered ChE. Results presented here demonstrate that either human BChE or FBS-AChE is an effective prophylactic measure sufficient to protect mice from multiple LD50S of soman without the administration of post-treatment supportive drugs.