Collective Behavior of Urease pH Clocks in Nano- and Microvesicles Controlled by Fast Ammonia Transport

Miele, Ylenia; Jones, Stephen J; Rossi, Federico; Beales, Paul A.; Taylor, Annette F.

doi:10.1021/acs.jpclett.2c00069

Cited by 14 publications

(16 citation statements)

References 55 publications

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“…Given the narrow parameter domain where stable oscillations exist, reliable predictions of the reaction kinetics are indispensible for the design of experiments that demonstrate the oscillatory behavior. Furthermore, a faithful model of a single pH oscillator is a crucial prerequisite for understanding communication of vesicles and synchronization of rhythms. ,− …”

Section: Discussionmentioning

confidence: 99%

“…The dynamical system in eq 10 can be interpreted as the reaction rate equations of the following effective system of involume reactions (Figure 1e): (11) amended by the exchange reactions in eq 5 of S and H + with the reservoir and the decay of P, see the first reaction in eq 6 (Figure 1d). Thus, the product P has two channels to escape from the vesicle: directly and after protonation with an effective rate.…”

Section: Model Reductionmentioning

confidence: 99%

See 1 more Smart Citation

Accurate Reduced Models for the pH Oscillations in the Urea–Urease Reaction Confined to Giant Lipid Vesicles

2023

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This theoretical study concerns a pH oscillator based on the urea–urease reaction confined to giant lipid vesicles. Under suitable conditions, differential transport of urea and hydrogen ion across the unilamellar vesicle membrane periodically resets the pH clock that switches the system from acid to basic, resulting in self-sustained oscillations. We analyze the structure of the phase flow and of the limit cycle, which controls the dynamics for giant vesicles and dominates the pronouncedly stochastic oscillations in small vesicles of submicrometer size. To this end, we derive reduced models, which are amenable to analytic treatments that are complemented by numerical solutions, and obtain the period and amplitude of the oscillations as well as the parameter domain, where oscillatory behavior persists. We show that the accuracy of these predictions is highly sensitive to the employed reduction scheme. In particular, we suggest an accurate two-variable model and show its equivalence to a three-variable model that admits an interpretation in terms of a chemical reaction network. The faithful modeling of a single pH oscillator appears crucial for rationalizing experiments and understanding communication of vesicles and synchronization of rhythms.

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Section: Discussionmentioning

confidence: 99%

Section: Model Reductionmentioning

confidence: 99%

Accurate Reduced Models for the pH Oscillations in the Urea–Urease Reaction Confined to Giant Lipid Vesicles

2023

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“…Within this framework, systems chemists generally adopt a bottom-up approach to design chemical systems (or protocells) able to self-assemble in highly ordered supramolecular structures and/or to produce self-organised behaviours that accomplish complex functions without replicating the complex biological environment typical of the living cells. In this way, distinctive processes that characterise modern cells were successfully reproduced: these include, but are not limited to, collective behaviour and communication [ 17 , 18 , 19 , 20 , 21 , 22 , 23 ], energy harvesting [ 24 , 25 , 26 ] and metabolism [ 27 , 28 ]. Another common natural mechanism that has been extensively studied and mimicked by using synthetic systems is self-reproduction or division, which is the subject of the next sections of this paper.…”

Section: Introductionmentioning

confidence: 99%

Shape Deformation, Budding and Division of Giant Vesicles and Artificial Cells: A Review

Miele

Holló

Lagzi

et al. 2022

Life

Self Cite

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The understanding of the shape-change dynamics leading to the budding and division of artificial cells has gained much attention in the past few decades due to an increased interest in designing stimuli-responsive synthetic systems and minimal models of biological self-reproduction. In this respect, membranes and their composition play a fundamental role in many aspects related to the stability of the vesicles: permeability, elasticity, rigidity, tunability and response to external changes. In this review, we summarise recent experimental and theoretical work dealing with shape deformation and division of (giant) vesicles made of phospholipids and/or fatty acids membranes. Following a classic approach, we divide the strategies used to destabilise the membranes into two different types, physical (osmotic stress, temperature and light) and chemical (addition of amphiphiles, the addition of reactive molecules and pH changes) even though they often act in synergy when leading to a complete division process. Finally, we review the most important theoretical methods employed to describe the equilibrium shapes of giant vesicles and how they provide ways to explain and control the morphological changes leading from one equilibrium structure to another.

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“…To date, various artificial bioreactors have been developed and utilized to understand a wide range of catalytic transformations under confinement. These include liposomes, , microemulsions, , polymersomes, , polymeric capsules, , metal–organic frameworks (MOFs), , covalent organic frameworks (COFs), , hydrogels, , and deoxyribonucleic acid (DNA) nanostructures. , These robust architectures not only stabilize the native conformations of enzymes and protect them from harmful external conditions such as acidic pH, temperature, protease digestion, and denaturation, but also enhance the enzymatic activity via stabilization of the active site, modulation of chemical activity, and enhanced mass transport. For example, Liang et al demonstrated enhanced activity of encapsulated catalase and urease inside the porous cavity of hydrophilic MOF, while negligible or no activity was observed inside hydrophobic MOF .…”

Section: Introductionmentioning

confidence: 99%

Synthetic Protocell as Efficient Bioreactor: Enzymatic Superactivity and Ultrasensitive Glucose Sensing in Urine

Saini

Mukherjee

2022

ACS Appl. Mater. Interfaces

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It is believed that membraneless cellular condensates play a critical role in accelerating various slow and thermodynamically unfavorable biochemical processes. However, the exact mechanisms behind the enhanced activity within biocondensates remain poorly understood. Here, we report the fabrication of a high-performance integrated cascade bioplatform based on synthetic droplets for ultrasensitive glucose sensing. Using a horseradish peroxidase (HRP) and glucose oxidase (GOx) cascade pair, we report an unprecedented enhancement in the catalytic activity of HRP inside the synthetic membraneless droplet. Liquidlike membraneless droplets have been prepared via multivalent electrostatic interactions between adenosine triphosphate (ATP) and poly(diallyldimethylammonium chloride) (PDAD-MAC) in an aqueous medium. Compartmentalized enzymes (GOx/HRP@Droplet) exhibit high encapsulation efficiency, low leakage, prolong retention of activity, and exceptional stability toward protease digestion. Using an HRP@Droplet composite, we have shown that the enzymatic reaction within the droplet follows the classical Michaelis−Menten model. Our findings reveal remarkable enhancement in the catalytic activity of up to 100-and 51fold for HRP@Droplet and GOx/HRP@Droplet, respectively. These enhanced activities have been explained on the basis of increased local concentrations of enzymes and substrates, along with altered conformations of sequestered enzymes. Furthermore, we have utilized highly efficient and recyclable GOx/HRP@Droplet composite to demonstrate ultrasensitive glucose sensing with a limit of detection of 228 nM. Finally, the composite platform has been exploited to detect glucose in spiked urine samples in solution and filter paper. Our present study illustrates the unprecedented activity of the compartmentalized enzymes and paves the way for next-generation composite bioreactors for a wide range of applications.

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Collective Behavior of Urease pH Clocks in Nano- and Microvesicles Controlled by Fast Ammonia Transport

Cited by 14 publications

References 55 publications

Accurate Reduced Models for the pH Oscillations in the Urea–Urease Reaction Confined to Giant Lipid Vesicles

Accurate Reduced Models for the pH Oscillations in the Urea–Urease Reaction Confined to Giant Lipid Vesicles

Shape Deformation, Budding and Division of Giant Vesicles and Artificial Cells: A Review

Synthetic Protocell as Efficient Bioreactor: Enzymatic Superactivity and Ultrasensitive Glucose Sensing in Urine

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