A Bacterial Photosynthetic Enzymatic Unit Modulating Organic Transistors with Light

Lauro, Michele Di; Gatta, Simona la; Bortolotti, Carlo Augusto; Beni, Valerio; Parkula, Vitaliy; Drakopoulou, Sofia; Giordani, Martina; Berto, Marcello; Milano, Francesco; Cramer, Tobias; Murgia, Mauro; Agostiano, Angela; Farinola, Gianluca M.; Trotta, Massimo; Biscarini, Fabio

doi:10.1002/aelm.201900888

Cited by 23 publications

(21 citation statements)

References 39 publications

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“…Organic electronic devices can be advantageous when applied in the biological milieu since organic electronic materials support sufficient electronic and ionic transport ( Paulsen et al, 2020 ), in a highly coupled manner, and thus enable efficient signal transduction. While the majority of efforts lie within the animal kingdom, applying bioelectronics to other biological organisms has emerged with successful demonstrations of sensing and actuation in bacteria ( He et al., 2012 ; Pitsalidis et al, 2018 ; Zajdel et al., 2018 ; Demuru et al., 2019 ; Di Lauro et al, 2020 ) and plants ( Stavrinidou et al., 2015 , 2017 ; Coppedè et al., 2017 ; Poxson et al., 2017 ; Bernacka-Wojcik et al, 2019 ; Janni et al, 2019 ; Kim et al., 2019 ; Vurro et al, 2019 ; Diacci et al, 2020 ). Recently, we presented an implantable organic electronic ion pump for in vivo delivery of abscisic acid, one of the main hormones involved in plant stress responses ( Bernacka-Wojcik et al, 2019 ), and subsequently the electronic control of physiology in intact plants.…”

Section: Introductionmentioning

confidence: 99%

Diurnal in vivo xylem sap glucose and sucrose monitoring using implantable organic electrochemical transistor sensors

et al. 2021

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Section: Introductionmentioning

confidence: 99%

Diurnal in vivo xylem sap glucose and sucrose monitoring using implantable organic electrochemical transistor sensors

et al. 2021

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“…Various approaches have been recently reviewed [1,25] and include: 1) layer-by-layer electrostatic adsorption of negatively charged RC onto polycationic modified electrodes; [26] 2) entrapment by physisorption of the protein in nanoporous materials [27,28] and sol-gel media [26] or directly onto the electrode via laser printing [29] or Langmuir-Blodgett techniques; [30,31] 3) covalent binding the RC to the electrode surface by suitable protein linkers or polyhistidine (polyHis) tag at the C-terminal of M subunit of genetically engineered RC; [32] 4) casting a layer of oxidized cyt onto an indium tin oxide (ITO) Gate, prior to RC deposition, to induce an orientation of the photoenzyme that enabled the construction of a novel Light-driven electrolytegated organic transistor. [33] An alternative attaching strategy based on the adhesive properties of polydopamine (PDA) uses a straightforward one-pot molecule encapsulation to produce firmly anchored films on the surface of a dipped electrode in aqueous aerated buffered solution. Dopamine (3,4-dihydroxyphenethylamine, DA) easily polymerizes in presence of oxidant in alkaline aqueous solutions, [34][35][36][37][38][39] forming a robust melanin-like underwater adhesive polymer, [40] the PDA, composed of 5,6-dihydroxy-indole repeating units and its derivatives.…”

Section: Q2mentioning

confidence: 99%

Photoelectrodes with Polydopamine Thin Films Incorporating a Bacterial Photoenzyme

Presti

Giangregorio

Ragni

et al. 2020

Adv Elect Materials

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A fabrication strategy of photoactive biohybrid electrodes based on the immobilization of the bacterial reaction center (RC) onto indium tin oxide (ITO) is proposed. The RC is an integral photoenzyme that converts photons into stable charge‐separated states with a quantum yield close to one. The photogenerated electron–hole pair can be eventually exploited, with suitable redox mediators, to produce photocurrents. To this purpose, RC must be effectively anchored on the electrode surface and simple strategies for its stable immobilization ensuring prolonged enzyme photoactivity are strongly desired. In this work, polydopamine (PDA), a polymer reminiscent of the natural melanin, is used to anchor the RC on the electrode surface. PDA is easily prepared in situ by spontaneous polymerization of dopamine in slightly alkaline aerated buffered RC solution. This reaction, carried out in the presence of an ITO substrate dipped into the solution, directly leads to a stable RC‐PDA/ITO photoelectrode with 20 nm film thickness and 50% of fully functional RC occupancy. Photocurrents densities recorded using this photoelectrode are comparable to those obtained with far more sophisticated immobilization techniques. The RC‐PDA films are fully characterized by visible–near‐infrared absorption spectroscopy, ellipsometry, atomic force, and scanning electron microscopies.

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“…In isolated proteins, instead, light absorption promotes the formation of an electron−hole couple with a conversion yield close to unity, making the RC a biological semiconductor [13]. Given the intense research of such kind of proteins in material science for energy conversion [1,14], synthetic biology [15], biosensing [16][17], and photocatalysis [18], it results interesting to study the behaviour of RCs once entrapped within the suspended PDA nanoaggregates. The RC photoactivity was studied as a function of the starting enzyme/dopamine starting ratio verifying its entrapment without loss of functionality.…”

Section: Introductionmentioning

confidence: 99%

Activity of photosynthetic Reaction Centers coated with polydopamine

et al. 2020

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Dilute aqueous solutions of dopamine buffered to an alkaline pH and in the presence of dissolved oxygen undergo to a series of autoxidation and rearrangement reactions that lead to the formation of a dark insoluble material called polydopamine (PDA) with melanin reminiscent properties. In this work we carried out this reaction in the presence of the photosynthetic reaction center (RC), a transmembrane pigment-protein complex responsible for the first light-induced reactions in the photosynthetic process. We have found that PDA grows in colloidal form around the RC and in the appropriate conditions the protein is entrapped in the PDA matrix without loss of functionality. The protein is still capable to perform its natural photocycle leading to the generation of photocurrents and the ubiquinone acceptor complex function is modulated by the PDA/RC ratio.

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A Bacterial Photosynthetic Enzymatic Unit Modulating Organic Transistors with Light

Cited by 23 publications

References 39 publications

Diurnal in vivo xylem sap glucose and sucrose monitoring using implantable organic electrochemical transistor sensors

Diurnal in vivo xylem sap glucose and sucrose monitoring using implantable organic electrochemical transistor sensors

Photoelectrodes with Polydopamine Thin Films Incorporating a Bacterial Photoenzyme

Activity of photosynthetic Reaction Centers coated with polydopamine

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