Your search keyword '"Marco Malferrari"' showing total 4 results

1. Autonomous use of electrical energy by an artificial molecular machine

Author

Andrea Secchi, Serena Silvi, Giulio Ragazzon, Stefania Rapino, Alberto Credi, Arturo Arduini, and Marco Malferrari

Subjects

Exploit, Relation (database), Computer science, Electric potential energy, Control engineering, Energy source, Molecular machine, Energy (signal processing), Efficient energy use

Abstract

The ability to exploit energy autonomously is one of the hallmarks of Life. Mastering such processes in artificial nanosystems can open unforeseen technological opportunities. In the last decades, light- and chemically-driven autonomous systems have been developed in relation to conformational motion and self-assembly. On the contrary, the autonomous exploitation of electrical energy remains essentially unexplored, despite being an attractive energy source. Herein we demonstrate the autonomous operation of an electrochemically-powered self-assembling nanomachine. Threading and dethreading motions of a pseudorotaxane take place autonomously in solution, between the electrodes of a scanning electrochemical microscope. This innovative actuation mode allows operating a molecular machine with an energy efficiency of 9%, unprecedented in autonomous systems. The strategy is general and can be applied to any redox-driven system, including molecular pumps that perform work repetitively. Ultimately, our study brings molecular nanoscience one step closer to everyday technology.

Published

2021

2. Protein Immobilization Capabilities of Sucrose and Trehalose Glasses: The Effect of Protein/Sugar Concentration Unraveled by High-Field EPR

Author

Marco Malferrari, Anton Savitsky, Klaus Möbius, Giovanni Venturoli, Wolfgang Lubitz, Malferrari, Marco, Savitsky, Anton, Lubitz, Wolfgang, Möbius, Klau, and Venturoli, Giovanni

Subjects

DYNAMICS, Photosynthetic reaction centre, STABILIZATION, Sucrose, Nitroxide mediated radical polymerization, Disaccharide, 02 engineering and technology, ELECTRON-TRANSFER KINETICS, 010402 general chemistry, 01 natural sciences, law.invention, chemistry.chemical_compound, SYSTEMS, law, Organic chemistry, CRYSTAL-STRUCTURE, General Materials Science, Physical and Theoretical Chemistry, Sugar, Electron paramagnetic resonance, SPECTROSCOPY, PHOTOSYNTHETIC REACTION CENTERS, Intermolecular force, Proteins, Trehalose, 021001 nanoscience & nanotechnology, STATE, 0104 chemical sciences, DIFFERENT HYDRATION LEVELS, ROOM-TEMPERATURE, chemistry, Biophysics, Sugars, 0210 nano-technology

Abstract

Disaccharide glasses are increasingly used to immobilize proteins at room temperature for structural/functional studies and long-term preservation. To unravel the molecular basis of protein immobilization, we studied the effect of sugar/protein concentration ratios in trehalose or sucrose matrixes, in which the bacterial photosynthetic reaction center (RC) was embedded as a model protein. The structural, dynamical, and H-bonding characteristics of the sugar-protein systems were probed by high-field W-band EPR of a matrix-dissolved nitroxide radical. We discovered that RC immobilization and thermal stabilization, being independent of the protein concentration in trehalose, occur in sucrose only at sufficiently low sugar/protein ratios. EPR reveals that only under such conditions does sucrose form a microscopically homogeneous matrix that immobilizes, via H-bonds, the nitroxide probe. We conclude that the protein immobilization capability depends critically on the propensity of the glass-forming sugar to create intermolecular H-bond networks, thus establishing long-range, homogeneous connectivity within the matrix.

Published

2016

3. Coupling between Electron Transfer and Protein–Solvent Dynamics: FTIR and Laser-Flash Spectroscopy Studies in Photosynthetic Reaction Center Films at Different Hydration Levels

Author

Marco Malferrari, Francesco Francia, Giovanni Venturoli, Malferrari M., Francia F., and Venturoli G.

Subjects

Photosynthetic reaction centre, Photosynthetic Reaction Center Complex Proteins, Kinetics, Analytical chemistry, Hydration shell, Charge recombination proce, Rhodobacter sphaeroides, Electron transfer, Electron Transport, Reaction rate constant, Phase (matter), Spectroscopy, Fourier Transform Infrared, Materials Chemistry, Physical and Theoretical Chemistry, Conformational dynamic, biology, Chemistry, Relaxation (NMR), Temperature, Water, Hydrogen Bonding, biology.organism_classification, Photosynthetic reaction center, Surfaces, Coatings and Films, FTIR spectroscopy, Solvation shell, Solvents, Thermodynamics

Abstract

We report on the relationship between electron transfer, conformational dynamics, and hydration in photosynthetic reaction centers (RCs) from Rhodobacter sphaeroides. The kinetics of electron transfer from the photoreduced quinone acceptor (Q(A)(-)) to the photo-oxidized primary donor (P(+)), a charge recombination process sensitive to the conformational dynamics of the RC, has been analyzed at room temperature in dehydrated RC-detergent films as a function of the residual water content under controlled relative humidity (r). The hydration level was evaluated by FTIR spectroscopy from the area of the combination band of water (5155 cm(-1)). Sorption isotherms fit the Hailwood and Horrobin model and indicate a significant contribution to hydration of the detergent belt surrounding the RC. Spectral analysis of the water combination and association (2130 cm(-1)) bands suggests strong rearrangements in the hydrogen-bonding organization upon depletion of the hydration shell of the complex. In parallel with these changes, following dehydration below a critical threshold (r approximately equal 40%), the kinetics of P(+)Q(A)(-) recombination become progressively faster and distributed in rate. When r is decreased from 40% to 10% the average rate constant (k) increases from 15 to 40 s(-1), mimicking the behavior of the hydrated system at cryogenic temperatures. We infer that extensive dehydration inhibits dramatically the relaxation from the dark- to the light-adapted conformation of the RC as well as interconversion among lower tier conformational substates. The RC dynamics probed by P(+)Q(A)(-) recombination appear therefore controlled by the thermal fluctuations of the hydration shell. At r < 10% an additional, much faster ((k) approximately equal 3000 s(-1)) kinetic phase of P(+)Q(A)(-) recombination is observed. We suggest such a fast recombination arises from removal of a pool of RC-bound water molecules which are essential to stabilize the primary charge-separated state at physiological conditions.

Published

2011

4. Charge Recombination Kinetics and Protein Dynamics in Wild Type and Carotenoid-less Bacterial Reaction Centers: Studies in Trehalose Glasses

Author

Sophie Sacquin-Mora, Francesco Francia, Giovanni Venturoli, Marco Malferrari, F. Francia, M. Malferrari, S. Sacquin-Mora, and G. Venturoli

Subjects

Models, Molecular, Protein Conformation, Photosynthetic Reaction Center Complex Proteins, Kinetics, Rhodobacter sphaeroides, macromolecular substances, Photochemistry, chemistry.chemical_compound, Electron transfer, Benzoquinones, Materials Chemistry, Physical and Theoretical Chemistry, biology, Strain (chemistry), Protein dynamics, Wild type, Trehalose, Water, biology.organism_classification, Carotenoids, Surfaces, Coatings and Films, chemistry, Mutation, Glass, Recombination

Abstract

The coupling between electron transfer and protein dynamics has been investigated in reaction centers (RCs) from the wild type (wt) and the carotenoid-less strain R26 of the photosynthetic bacterium Rhodobacter sphaeroides. Recombination kinetics between the primary photoreduced quinone acceptor (QA-) and photoxidized donor (P+) have been analyzed at room temperature in RCs incorporated into glassy trehalose matrices of different water/sugar ratios. As previously found in R26 RCs, also in the wt RC, upon matrix dehydration, P+QA- recombination accelerates and becomes broadly distributed, reflecting the inhibition of protein relaxation from the dark-adapted to the light-adapted conformation and the hindrance of interconversion between conformational substates. While in wet trehalose matrices (down to approximately one water per trehalose molecule) P+QA- recombination kinetics are essentially coincident in wt and R26 RCs, more extensive dehydration leads to two-times faster and more distributed kinetics in the carotenoid-containing RC, indicating a stronger inhibition of the internal protein dynamics in the wt RC. Coarse-grained Brownian dynamics simulations performed on the two RC structures reveal a markedly larger flexibility of the R26 RC, showing that a rigid core of residues, close to the quinone acceptors, is specifically softened in the absence of the carotenoid. These experimental and computational results concur to indicate that removal of the carotenoid molecule has long-range effects on protein dynamics and that the structural/dynamical coupling between the protein and the glassy matrix depends strongly upon the local mechanical properties of the protein interior. The data also suggest that the conformational change stabilizing P+QA- is localized around the QA binding pocket.

Published

2009