Chirality transmission in macromolecular domains

Pandey, Shankar; Mandal, Shankar; Danielsen, Mathias B; Brown, Asha; Hu, Changpeng�; Christensen, N. J.; Kulakova, Alina; Song, Shixi; Brown, Tom; Jensen, Knud J.; Wengel, Jesper; Lou, Chenguang; Mao, Hanbin

doi:10.1038/s41467-021-27708-4

Cited by 15 publications

(15 citation statements)

References 60 publications

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“…Two chiral azocontaining monomers (R-TBDPS-Azo-tBu and S-TBDPS-Azo-tBu) with two reactive groups, including the hydroxyl group protected by tert-butyldiphenylsilyl (TBDPS) group and the carboxyl group protected by tert-butyl ester (t-Bu) group, were pre-synthesized to provide precursors for these monodisperse oligomers (Scheme S1 and Figure 1a). The chemical structures of two monomers and their intermediates were confirmed by 1 H NMR spectroscopy (Figures S1-S3), showing e.e. values higher than 99 % (Figure S4).…”

Section: Resultsmentioning

confidence: 93%

“…[13b,18] Compared with chiral polymers containing azobenzene side-chains, there are fewer reports on the dynamic chiral assembly of polymers containing azobenzene in the backbone. This mainly due to three reasons: (1) the precise synthesis of well-defined main-chain azopolymers is relatively challenging; (2) the ordered chiral supramolecular stacking between the azobenzene structural units in the polymer backbone is difficult to occur due to the limited movement caused by the huge steric hindrance; (3) it is also difficult for the azobenzene bonds in the polymer backbone to undergo cis-trans isomerization. Furthermore, it is worth noting that the chiral assemblies obtained from main-chain azopolymers primarily arise from the axial chirality of the functional groups.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Unraveling Dynamic Helicity Inversion and Chirality Transfer through the Synthesis of Discrete Azobenzene Oligomers by an Iterative Exponential Growth Strategy

Wang,

Yu,

Huang

et al. 2023

Angew Chem Int Ed

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Unraveling the chirality transfer mechanism of polymer assemblies and controlling their handedness is beneficial for exploring the origin of hierarchical chirality and developing smart materials with desired chiroptical activities. However, polydisperse polymers often lead to an ambiguous or statistical evaluation of the structure–property relationship, and it remains unclear how the iterative number of repeating units function in the helicity inversion of polymer assemblies. Herein, we report the macroscopic helicity and dynamic manipulation of the chiroptical activity of supramolecular assemblies from discrete azobenzene‐containing oligomers (azooligomers), together with the helicity inversion and morphological transition achieved solely by changing the iterative chain lengths. The corresponding assemblies also differ from their polydisperse counterparts in terms of thermodynamic properties, chiroptical activities, and morphological control.

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Section: Resultsmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Unraveling Dynamic Helicity Inversion and Chirality Transfer through the Synthesis of Discrete Azobenzene Oligomers by an Iterative Exponential Growth Strategy

Wang,

Yu,

Huang

et al. 2023

Angew Chem Int Ed

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“…Such remarkable induced CD signature was attributed to increased π-π delocalization upon photopolymerization along with transfer of chirality from the amino acid moieties to the polydiacetylene chromophore as reported in other macromolecular systems with secondary structural domains showing long-range chiral transmission. [20] The difference in the CD signals for L-FF-PDA and D-FF-PDA could be attributed to the geometrical difference in conformation of the D-and L-peptide to facilitate larger helical transformation [21] (Figure 3B) and was corroborated with low pitch length to promote more ellipticity (Figure 2E). The linear dichroism (LD) spectra for the L-and D-FF-DA films suggested a minimum contribution of LD signal towards such supramolecular helicity (Figure S16A).…”

Section: Methodsmentioning

confidence: 90%

Stereoselective Plasmonic Interaction in Peptide‐tethered Photopolymerizable Diacetylenes Doped with Chiral Gold Nanoparticles

et al. 2023

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Designing polymeric systems with ultra‐high optical activity is instrumental in the pursuit of smart artificial chiroptical materials, including the fundamental understanding of structure/property relations. Herein, we report a diacetylene (DA) moiety flanked by chiral D‐ and L‐FF dipeptide methyl esters that exhibits efficient topochemical photopolymerization in the solid phase to furnish polydiacetylene (PDA) with desired control over the chiroptical properties. The doping of the achiral gold nanoparticles provides plasmonic interaction with the PDAs to render asymmetric shape to the circular dichroism bands. With the judicious design of the chiral amino acid ligand appended to the AuNPs, we demonstrate the first example of selective chiral amplification mediated by stereo‐structural matching of the polymer‐plasmonic AuNP hybrid pairs. Such ordered self‐assembly aided by topochemical polymerization in peptide‐tethered PDA provides a smart strategy to produce soft responsive materials for applications in chiral photonics.

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“…In this case, the close proximity to the large-area surface and/or between the consecutivelyconnected proteins of the tandem repeat can hinder membrane protein studies since the lipid bilayer mimetics such as bicelles or vesicles of ~100 nm or larger in diameter will not be properly accommodated in the narrow space 19,33 . On the other hand, single-molecule tweezers using hundreds-of-nm long molecular handles flanking a protein of interest still rely on the conventional noncovalent tethers of the dig-antidig and biotin-streptavidin [10][11][12][13][14][15]19 . The digantidig interaction is as very weak as τ off = ~1 sec at 25 pN (~0.1 sec at 50 pN) 24 , limiting the stable performance of experiments, data throughputs (tens of pulling on one molecule at most), and reliable statistical analyses.…”

Section: Introductionmentioning

confidence: 99%

“…To apply mechanical force to a target protein in magnetic or optical tweezers [4][5][6][7] , we tether two protein positions, e.g., the N-and C-termini, to solid supports of a micron-sized bead and the sample chamber surface (or another bead), respectively. Rapid noncovalent tethering has been widely used, such as the binding between digoxigenin (dig) and antidigoxigenin (antidig), 6xHis tag and Ni-NTA, and biotin and streptavidin [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22] . However, the noncovalent tethers are dissociated in tens-of-pN force ranges 23,24 , restricting the utilization of the tweezer methods.…”

Section: Introductionmentioning

confidence: 99%

Robust single membrane protein tweezers

Kim

Lee

Wijesinghe

et al. 2023

Preprint

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Single-molecule tweezers, such as magnetic tweezers, are powerful mechanical manipulation tools that can probe nm-scale structural changes in a single membrane protein under force. However, the weak molecular tethers used in the tweezers limit a long time, repetitive mechanical manipulation because of their force-induced bond breakage. Here, using the metal-free click chemistry of dibenzocyclooctyne (DBCO) cycloaddition and the rapid, strong binding of traptavidin to dual biotins (2xbiotin), we developed robust single-molecule tweezers that can perform thousands of force applications on a single membrane protein. By applying up to 50 pN for each cycle, which is sufficiently high for most biological processes, we were able to observe repetitive forced unfolding for a designer membrane protein up to approximately 1000 times on average. Monte Carlo simulations showed that the average error of the unfolding kinetic values rapidly decays to 1.8% at 200-time pulling, indicating that our method can quickly produce reliable statistics. The approach established here is also applicable to highly polar DNA molecules, permitting the nanomechanical manipulation of diverse biomolecular systems.

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Chirality transmission in macromolecular domains

Cited by 15 publications

References 60 publications

Unraveling Dynamic Helicity Inversion and Chirality Transfer through the Synthesis of Discrete Azobenzene Oligomers by an Iterative Exponential Growth Strategy

Unraveling Dynamic Helicity Inversion and Chirality Transfer through the Synthesis of Discrete Azobenzene Oligomers by an Iterative Exponential Growth Strategy

Stereoselective Plasmonic Interaction in Peptide‐tethered Photopolymerizable Diacetylenes Doped with Chiral Gold Nanoparticles

Robust single membrane protein tweezers

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