Abstract
The insertion of azobenzene moiety in complex molecular protein or peptide systems can lead to molecular switches to be used to determine kinetics of folding/unfolding properties of secondary structures, such as α-helix, β-turn, or β-hairpin. In fact, in azobenzene, absorption of light induces a reversible trans ↔ cis isomerization, which in turns generates a strain or a structure relaxation in the chain that causes peptide folding/unfolding. In particular azobenzene may permit reversible conformational control of hairpin formation. In the present work a synthetic photochromic azobenzene amino acid derivative was incorporated as a turn element to modify the synthetic peptide [Pro7,Asn8,Thr10]CSF114 previously designed to fold as a type I β-turn structure in biomimetic HFA/water solution. In particular, the P-N-H fragment at positions 7–9, involved in a β-hairpin, was replaced by an azobenzene amino acid derivative (synthesized ad hoc) to investigate if the electronic properties of the novel peptidomimetic analog could induce variations in the isomerization process. The absorption spectra of the azopeptidomimetic analog of the type I β-turn structure and of the azobenzene amino acid as control were measured as a function of the irradiation time exciting into the respective first ππ* and nπ* transition bands. Isomerization of the azopeptidomimetic results strongly favored by exciting into the ππ* transition. Moreover, conformational changes induced by the cis↔ trans azopeptidomimetic switch were investigated by NMR in different solvents.
Highlights
Azobenzene has been recognized as a potential molecular photoswitch in various fields, such as polymer science, material science, chemistry, and life sciences (Marchi et al, 2012; Goulet-Hanssens and Barrett, 2013; Dong et al, 2015; Bushuyev et al, 2018; Miniewicz et al, 2018)
In this work we designed, synthesized and studied the reversible cis ↔ trans photoisomerization of the [Pro7,Asn8,Thr10]CSF114 analog peptide 1, where from the original sequence the P-N-H tripeptide was replaced by the photoswitch (4-aminomethyl)phenylazobenzoic acid (AMPB)
The photoisomerization of the synthetic azopeptide 1 was explored and its reversibility was compared with more simple systems, the azobenzene amino acid 2 and the azobenzene 3
Summary
Azobenzene has been recognized as a potential molecular photoswitch in various fields, such as polymer science, material science, chemistry, and life sciences (Marchi et al, 2012; Goulet-Hanssens and Barrett, 2013; Dong et al, 2015; Bushuyev et al, 2018; Miniewicz et al, 2018). Absorption of light by azobenzene induces a reversible trans ↔ cis isomerization, which in turns generates a strain or a structure relaxation in the chain that causes peptide unfolding/folding. When a chromophore unit is integrated into a linear or cyclic peptide, the trans ↔ cis isomerization of an azobenzene derivative induced by UV/VIS photoirradiation, has been demonstrated to induce a reversible change in the peptide structure modulating its biological activity (Ali et al, 2015). Aim of the present work is the design and synthesis of a photocontrolled probe, based on AMPB azobenzene as a turn element in the central part of the amino acid sequence, to investigate if the electronic properties of the new molecule could induce variations in the isomerization process of the azobenzene unit and to study the effect of the photoswitch on its conformation
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