Inhibition of macrophage metabolism by oxLDL

Intracellular oxidative stress is induced by oxidised low density lipoprotein (oxLDL) in macrophages. In the atherosclerotic lesions, this oxLDL dependent oxidative stress appears to cause macrophage cell death, a key process in the development of the necrotic core within the complex plaque. Macrophages are activated by γ-interferon to synthesise and release a potent antioxidant, 7,8-dihydroneopterin (7,8-NP), which has been previously shown to protect human monocyte-like U937 cells and human monocyte-derived macrophage (HMDM) cells from oxLDL cytotoxicity. This study examined whether oxLDL causes the loss of cellular metabolic function and whether 7,8-dihydroneopterin can prevent this loss of metabolic activity in U937 cells and HMDM cells. OxLDL prepared by copper oxidation caused cell death in both U937 and HMDM cells at concentrations of 0.5 and 2.0 mg/ml, respectively. Cell morphology showed the oxLDL caused a necrotic like death in both cells as indicated by cell swelling and lysis. The decrease in cell viability was only observed after the loss of intracellular glutathione (GSH) which occurred in the first 3 hours in U937 cells following oxLDL addition. The loss of GSH appeared to be due to the production of intracellular oxidants generated in response to the presence of the oxLDL. Within 3 hours of oxLDL addition to both cell types, there was a rapid and progressive shutdown of cell metabolism indicated by a significant decrease in the enzymatic activity of the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and a fall in lactate production and intracellular ATP levels. GAPDH activity was found to be inactivated rather than being lost from the cell. Gel electrophoresis with specific staining for oxidised proteins showed that the GAPDH had been oxidatively inactivated in the cells when oxLDL was present. Unlike GAPDH, lactate dehydrogenase (LDH) was not inactivated by the oxidation but was lost from the cells due to cell lysis. The observed rate of glycolysis failure was similar in both cell types except the HMDM cells did not lose lactate, LDH activity and cell viability until 6 hours compared to 3 hours with the U937 cells. The rate of oxygen consumption (VO2) was measured in U937 cells by taking cells at set time points and placing them in the respirometers to measure the VO2. U937 cells were found to increase their VO2 with incubation but this increase was inhibited in the presence of oxLDL within 3 hours. The addition of the 7,8 dihydroneopterin above 100 μM to both the U937 and HMDM cells significantly inhibited the oxLDL-induced loss of cell viability. GAPDH activity loss was also inhibited while lactate production was maintained. The 7,8-dihydroneopterin also prevented the decrease in the VO2 in oxLDL-treated U937 cells. OxLDL was labelled with fluorescent DiI to measure the uptake of oxLDL by HMDM cells. The incorporation of DiI into oxLDL was found to make it non-cytotoxic, possibly due to DiI’s antioxidant properties. Studies were therefore conducted using either a mixture of oxLDL and DiI labelled oxLDL (DiI-oxLDL) at non-protective concentrations or low concentration of DiI-oxLDL alone. These studies showed that 7,8-dihydroneopterin downregulated the oxLDL uptake in oxLDL-treated HMDM cells. Surprisingly the uptake rates also suggested that there was no relationship between oxLDL uptake and cell death assuming oxLDL and DiI-oxLDL are taken up by the same mechanism. This research showed that oxLDL-induced oxidative stress in macrophage cells causes a rapid oxidative loss of GAPDH activity which leads to the loss of glycolytic activity and a fall in ATP levels. The failure of cell metabolism appears to be a key event in the death mechanism triggered by the oxLDL. The radical scavenging activity of 7,8-dihydroneopterin appears to prevent the oxidative stress as indicated by the protection of the GSH pool. Without the oxidative stress, GAPDH remains functioning, glycolytic activity is maintained and both the U937 cells and HMDM cells did not die. This suggests that within the atherosclerotic plaque, 7,8-dihydroneopterin may act to stabilise the metabolism of macrophage cells in the presence of oxLDL and downregulate the oxLDL uptake

Synthesis, anticancer activity, and molecular docking of new pyrazolo[1,5-a]pyrimidine derivatives

The reaction of 3-aminopyrzoles with dimethylamino-acrylonitrile derivatives was utilized for the production of new functionalized pyrazolopyrimidine compounds 4a-c and 6a-c. The structures of the obtained pyrazolopyrimidines were characterized by the different spectroscopic measurements (IR, NMR, and mass analyses). The DFT quantum chemical calculations were applied to the determination of the HOMO-LUMO energies and Mulliken atomic charges. The investigated derivatives exhibited a low HOMO-LUMO energy gap, ranging from 2.70 to 2.34 eV, 4c and both 4b and 6b, respectively. Furthermore, the anticancer activities of the synthesized compounds have also been investigated against four cancer cells as well as normal cells (WI38). The investigated compounds demonstrated an impressive cytotoxic effect on MCF-7 and Hep-2 cells. On comparison with 5-fluorouracil, pyrazolopyrimidines 6a–c showed promising cytotoxic action against MCF-7 and Hep-2, with IC50 values of 18.31–26.51 and 24.15–27.16 μM, respectively. Molecular docking of the prepared pyrazolopyrimidines 4 and 6 with the crystal structure of the KDM5A protein, obtained from the PDB, revealed the types of the protein's binding sites

Synthesis, biological activity and assembly of pH-responsive alkyl-substituted naphthalene-type hydrazonotriazole organogelators

Hydrazones have been a significant group of materials with diverse pharmacological and industrial applications, such as treatment of cardiovascular diseases, parasitic infections, and viral disorders, as well as cosmetic and food additives. In this context, we present the synthesis and characterization of novel hydrazonotriazole analogues with different hydrophobic alkoxy units. The synthesized alkyl-substituted naphthalene-type hydrazonotriazoles were able to act as pH-sensitive and thermoreversible organogelators. They were prepared by a straightforward aldol condensation of 2-naphthalaldehyde with different adducts of 1-(5-methyl-1-(4-alkoxyphenyl)-1H-1,2,3-triazol-4-yl)ethan-1-one at room temperature in ethanolic solution and in the presence of sodium hydroxide as a catalytic agent. The provided compounds were exposed to condensation reaction with (2,4-dinitrophenyl)hydrazine in a refluxing acid ethanolic solution. Different spectroscopic methods were utilized to analyze and prove the chemical structures of the naphthalene-type hydrazonotriazoles, inclusing FT-IR, elemental analysis, and NMR spectra. The photophysical properties of the prepared hydrazonotriazoles were reported. The alkyl-substituted naphthalene-type hydrazonotriazole gelators were able to gelate a variety of solvents, displaying a sol–gel reversible response to pH changes together with colorimetric change from yellow to purple. The optimal gelation was monitored for nonyl-substituted hydrazone in a variety of solvents, demonstrating thermal stability up to 58 °C, and critical gelator concentration (CGC) of ∼ 1–11 mM. Several analytical methods were used to inspect the morphological properties of the hydrazonotriazole-based organogelators, displaying self-assembled nanofibers (7–15 nm). Both cytotoxic and antimicrobial activity of the alkyloxy-containing naphthalene-type hydrazonotriazole gelators was investigated

Systematic development of lectin conjugated microspheres for nose-to-brain delivery of rivastigmine for the treatment of Alzheimer’s disease

The current study focuses on development of nasal mucoadhesive microspheres for nose-to-brain delivery of rivastigmine for Alzheimer treatment. A systematic development was employed for optimization of the formulation and process parameters influential on the quality attributes of the microspheres. The risk assessment study revealed major influence of the polymer concentration (ethylcellulose: chitosan), the concentration of surfactant solution (polyvinyl alcohol), and stirring speed as the critical factors for optimization of the microspheres. These factors were systematically optimized using Box-Behnken design and microspheres were evaluated for the particle size, entrapment efficiency, and in vitro drug release as the response variables. The optimized microspheres containing 4.4% wt/vol polymers, 1% wt/vol surfactant, and stirring speed at 1500 rpm showed particle size of 19.9 µm, entrapment efficiency of 77.8%, and drug release parameters as T80% of 7.3 h. The surface modification of microspheres was performed with lectin by carbodiimide activation reaction and confirmed by difference in surface charge before and after chemical functionalization by zeta potential measurement which was found to be − 25.7 mV and 20.5 mV, respectively. Ex vivo study for bioadhesion strength evaluation on goat nasal mucosa indicated a significant difference (p < 0.001) between the plain (29%) and lectin functionalized microspheres (64%). In vivo behavioral and biochemical studies in the rats treated with lectin functionalized microspheres showed markedly better memory-retention vis-à-vis test and pure drug solution treated rats (p < 0.001). In a nutshell, the present studies showed successful development of nasal microspheres for enhanced brain delivery of rivastigmine for Alzheimer’s treatment