Ylenia Miele scite author profile

Self-division is one of the most common phenomena in living systems and one of the most important properties of life driven by internal mechanisms of cells. Design and engineering of synthetic cells from abiotic components can recreate a life-like function thus contributing to the understanding of the origin of life. Existing methods to induce the self-division of vesicles require external and non-autonomous triggers (temperature change and the addition of membrane precursors). Here we show that pHresponsive giant unilamellar vesicles on the micrometer scale can undergo self-division triggered by an internal autonomous chemical stimulus driven by an enzymatic (urea-urease) reaction coupled to a cross-membrane transport of the substrate, urea. The bilayer of the artificial cells is composed of a mixture of phospholipids (POPC, 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylcholine) and oleic acid molecules. The enzymatic reaction increases the pH in the lumen of the vesicles, which concomitantly changes the protonation state of the oleic acid in the inner leaflet of the bilayer causing the removal of the membrane building blocks into the lumen of the vesicles thus decreasing the inner membrane area with respect to the outer one. This process coupled to the osmotic stress (responsible for the volume loss of the vesicles) leads to the division of a mother vesicle into two smaller daughter vesicles. These two processes must act in synergy; none of them alone can induce the division. Overall, our self-dividing system represents a step forward in the design and engineering of a complex autonomous model of synthetic cells. † Electronic supplementary information (ESI) available: Description of the chemical model for the conned urea-urease enzymatic reaction. Descriptions of molecular dynamics simulations and lm balance experiments. Description of videos (Videos S1-S3). Supporting Tables S1, S2 and Fig. S1-S8. See

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Microplastics in the Environment: Intake through the Food Web, Human Exposure and Toxicological Effects

Pironti

Ricciardi

Motta

et al. 2021

Toxics

183

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Recently, studies on microplastics (MPs) have increased rapidly due to the growing awareness of the potential health risks related to their occurrence. The first part of this review is devoted to MP occurrence, distribution, and quantification. MPs can be transferred from the environment to humans mainly through inhalation, secondly from ingestion, and, to a lesser extent, through dermal contact. As regards food web contamination, we discuss the microplastic presence not only in the most investigated sources, such as seafood, drinking water, and salts, but also in other foods such as honey, sugar, milk, fruit, and meat (chickens, cows, and pigs). All literature data suggest not-negligible human exposure to MPs through the above-mentioned routes. Consequently, several research efforts have been devoted to assessing potential human health risks. Initially, toxicological studies were conducted with aquatic organisms and then with experimental mammal animal models and human cell cultures. In the latter case, toxicological effects were observed at high concentrations of MPs (polystyrene is the most common MP benchmark) for a short time. Further studies must be performed to assess the real consequences of MP contamination at low concentrations and prolonged exposure.

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Microplastics in the Aquatic Environment: Occurrence, Persistence, Analysis, and Human Exposure

Ricciardi

Pironti

Motta

et al. 2021

Water

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Microplastics (MP) have recently been considered as emerging contaminants in the water environment. In the last number of years, the number of studies on MP has grown quickly due to the increasing consciousness of the potential risks for human health related to MP exposure. The present review article discusses scientific literature regarding MP occurrence and accumulation on the aquatic compartment (river, lake, wastewater, seafood), the analytical methods used to assess their concentration, their fate and transport to humans, and delineates the urgent areas for future research. To better analogize literature data regarding MP occurrence in the aquatic compartment we subdivided papers based on sampling, analytical methods, and concentration units with the aim to help the reader identify the similarities and differences of the considered research papers, thus making the comparison of literature data easier and the individuation of the most relevant articles for the reader’s interests faster. Furthermore, we argued about several ways for MP transport to humans, highlighting some gaps in analytical methods based on the reviewed publications. We suggest improving studies on developing standardized protocols to collect, process, and analyze samples.

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Shape changes and budding of giant vesicles induced by an internal chemical trigger: an interplay between osmosis and pH change

Holló

Miele²,

Rossi

et al. 2021

Phys. Chem. Chem. Phys.

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Engineering Enzyme-Driven Dynamic Behaviour in Lipid Vesicles

Miele

Bánsági

Taylor

et al. 2016

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Ylenia Miele

Self-division of giant vesicles driven by an internal enzymatic reaction

Microplastics in the Environment: Intake through the Food Web, Human Exposure and Toxicological Effects

Microplastics in the Aquatic Environment: Occurrence, Persistence, Analysis, and Human Exposure

Shape changes and budding of giant vesicles induced by an internal chemical trigger: an interplay between osmosis and pH change

Engineering Enzyme-Driven Dynamic Behaviour in Lipid Vesicles

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