pH and Charge Effects Behind the Interaction of Artepillin C, the Major Component of Green Propolis, With Amphiphilic Aggregates: Optical Absorption and Fluorescence Spectroscopy Studies

Camuri, Isamara Julia; Costa, Adriano Batista; Ito, Amando Siuiti; Pazin, Wallance Moreira

doi:10.1111/php.13128

Cited by 5 publications

(4 citation statements)

References 36 publications

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“…The literature supports the notion that Artepillin C favors a neutral state as pH decreases [17]. Beyond 50 µM, molecules tend to aggregate due to their limited water solubility, augmenting interactions with lipophilic domains, such as the cell plasma membrane, and subsequently intensifying cytotoxic effects [18,22,34]. Notably, the decline in cellular viability observed at pH values of 6.8, 6.5, and 6.0 when cells were exposed to Artepillin C concentrations exceeding 50 µM, marked by significant differentiation from the respective pH controls, clearly underscores the pH-dependent effect.…”

Section: Cell Viability Studiesmentioning

confidence: 55%

“…Interestingly, this metabolic shift persists regardless of molecular oxygen levels in cancer cells, leading to a substantial elevation in lactate production-up to 40 times higher compared to healthy cells [21]. A previous study showed that models mimicking healthy and tumor cell membranes exhibit distinct responses based on lipid composition and media pH [18,22]. Under physiological conditions (pH 7.4), Artepillin C exhibits an affinity for the lipid assembly without perturbing the structural integrity of the lipid membrane.…”

Section: Introductionmentioning

confidence: 94%

“…The core structure primarily comprises a phenolic acid, wherein the carboxyl moiety's deprotonation is contingent upon the surrounding pH. Notably, the reported pKa value of Artepillin C is 4.65, with its lipophilicity varying in correspondence to its protonation state [17,18]. Within this context, it is pertinent to underscore the acidic attributes of the extracellular microenvironment in tumor cells.…”

Section: Introductionmentioning

confidence: 99%

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pH-Dependence Cytotoxicity Evaluation of Artepillin C against Tumor Cells

Pazin,

Miranda,

Toledo

et al. 2023

Life

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Brazilian green propolis is a well-known product that is consumed globally. Its major component, Artepillin C, showed potential as an antitumor product. This study explored the impact of Artepillin C on fibroblast and glioblastoma cell lines, used as healthy and very aggressive tumor cell lines, respectively. The focus of the study was to evaluate the pH-dependence of Artepillin C cytotoxicity, since tumor cells are known to have a more acidic extracellular microenvironment compared to healthy cells, and Artepillin C was shown to become more lipophilic at lower pH values. Investigations into the pH-dependency of Artepillin C (6.0–7.4), through viability assays and live cell imaging, revealed compelling insights. At pH 6.0, MTT assays showed the pronounced cytotoxic effects of Artepillin C, yielding a notable reduction in cell viability to less than 12% among glioblastoma cells following a 24 h exposure to 100 µM of Artepillin C. Concurrently, LDH assays indicated significant membrane damage, affecting approximately 50% of the total cells under the same conditions. Our Laurdan GP analysis suggests that Artepillin C induces autophagy, and notably, provokes a lipid membrane packing effect, contributing to cell death. These combined results affirm the selective cytotoxicity of Artepillin C within the acidic tumor microenvironment, emphasizing its potential as an effective antitumor agent. Furthermore, our findings suggest that Artepillin C holds promise for potential applications in the realm of anticancer therapies given its pH-dependence cytotoxicity.

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Section: Cell Viability Studiesmentioning

confidence: 55%

Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

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pH-Dependence Cytotoxicity Evaluation of Artepillin C against Tumor Cells

Pazin,

Miranda,

Toledo

et al. 2023

Life

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“…The optical absorption spectra represented the state of protonation dictated by the local pH on the surface of micelles and lipid vesicles (20). Useful data were obtained for the optimization of postharvest photochemical protocols for the valorization of cabbage waste using a nondestructive optical sensor (21).…”

Section: Introductionmentioning

confidence: 99%

Spectral Photoluminescent Parameters of Barley Seeds (Hordéum vulgáre) Infected with Fusarium ssp

Moskovsky

Yuri

Лавров

et al. 2022

Photochem & Photobiology

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We needed effective and sustainable technologies for better microbiological control of crops, including Fusarium. However, photoluminescent UV-Vis methods are potential for diagnosing plant diseases with Fusarium. It has not been sufficiently studied despite the application of these methods for other biological researches. The excitation spectrum of the seeds during infection shifts to the shorter wavelength and a new maximum appears in the region λ ≈ 232 nm. The photoluminescence of infected seeds increases with excitation by radiation of wavelengths λ e,1 = 232 nm, λ e,2 = 362 nm and λ e,3 = 424 nm by 1.33-3.14 times, and λ e,3 = 424 nm-decreases by 1.1 times. Statistical moments μ 3 and μ 4 , asymmetry and kurtosis change only with short-wave excitation. When analyzing the decomposition of the frequency spectrum into Gaussian curves, the most informative ratio is the ratio of right-handed and left-handed Gaussians under excitation λ e,2 = 362 nm and λ e,3 = 424 nm. The ratios of their maxima change during infection by 1.36-3.2 times, and for excitation by radiation λ e,2 , the frequency boundaries of Gaussians change. The results of measurements and calculations provide a basis for the development of a method and device for photoluminescence diagnostics of fusarium seeds in UV-Vis ranges.

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