Exciton Delocalization in Indolenine Squaraine Aggregates Templated by DNA Holliday Junction Scaffolds

Mass, Olga A.; Wilson, Christopher; Roy, Simon K.; Barclay, Matthew S.; Patten, Lance K.; Terpetschnig, Ewald; Lee, Jeunghoon; Pensack, Ryan D.; Yurke, Bernard; Knowlton, William B.

doi:10.1021/acs.jpcb.0c06480

Cited by 46 publications

(125 citation statements)

References 122 publications

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“…In the case of our DNA-templated Cy5 aggregates, insights into dye separation can be gleaned by simulating the optical properties of the materials, namely, the absorbance and circular dichroism spectra, via an approach based on Kühn–Renger–May (KRM) theory. 47 , 49 , 58 Figure 9 displays the orientation of the TDMs that result from modeling the optical properties of the duplex dimer, the transverse dimer, and type 2 tetramer, highlighting the separation between TDMs in these aggregates.…”

Section: Discussionmentioning

confidence: 99%

“…The optical properties of selected DNA-dye constructs were modeled using in-house software based on the Kühn–Renger–May method (version 13.7). 47 , 49 , 58 The software simultaneously fits absorbance and circular dichroism data by constructing and diagonalizing a Holstein Hamiltonian 19 that includes a single dominant vibronic mode. The fitting procedure begins with a user input dye configuration and performs a stochastic search by randomly perturbing the dye configuration and checking the fit quality.…”

Section: Methodsmentioning

confidence: 99%

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Excited-State Lifetimes of DNA-Templated Cyanine Dimer, Trimer, and Tetramer Aggregates: The Role of Exciton Delocalization, Dye Separation, and DNA Heterogeneity

et al. 2021

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DNA-templated molecular (dye) aggregates are a novel class of materials that have garnered attention in a broad range of areas including light harvesting, sensing, and computing. Using DNA to template dye aggregation is attractive due to the relative ease with which DNA nanostructures can be assembled in solution, the diverse array of nanostructures that can be assembled, and the ability to precisely position dyes to within a few Angstroms of one another. These factors, combined with the programmability of DNA, raise the prospect of designer materials custom tailored for specific applications. Although considerable progress has been made in characterizing the optical properties and associated electronic structures of these materials, less is known about their excited-state dynamics. For example, little is known about how the excited-state lifetime, a parameter essential to many applications, is influenced by structural factors, such as the number of dyes within the aggregate and their spatial arrangement. In this work, we use a combination of transient absorption spectroscopy and global target analysis to measure excited-state lifetimes in a series of DNA-templated cyanine dye aggregates. Specifically, we investigate six distinct dimer, trimer, and tetramer aggregates—based on the ubiquitous cyanine dye Cy5—templated using both duplex and Holliday junction DNA nanostructures. We find that these DNA-templated Cy5 aggregates all exhibit significantly reduced excited-state lifetimes, some by more than 2 orders of magnitude, and observe considerable variation among the lifetimes. We attribute the reduced excited-state lifetimes to enhanced nonradiative decay and proceed to discuss various structural factors, including exciton delocalization, dye separation, and DNA heterogeneity, that may contribute to the observed reduction and variability of excited-state lifetimes. Guided by insights from structural modeling, we find that the reduced lifetimes and enhanced nonradiative decay are most strongly correlated with the distance between the dyes. These results inform potential tradeoffs between dye separation, excitonic coupling strength, and excited-state lifetime that motivate deeper mechanistic understanding, potentially via further dye and dye template design.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Excited-State Lifetimes of DNA-Templated Cyanine Dimer, Trimer, and Tetramer Aggregates: The Role of Exciton Delocalization, Dye Separation, and DNA Heterogeneity

et al. 2021

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“…DNA was found to negligibly affect the absorbance data of a monomer. 18,35 Atomic structures were optimized using a tight root mean square residual force of 1 Â (10) À5 Hartree/Bohr and an ultra-ne integration grid of 99 radial shells and 590 angular points per shell. The ground-state optimization of these molecules was veried by ground-state frequency calculations to ensure that no imaginary frequencies were present, because imaginary frequencies represent unstable geometry.…”

Section: Methodsmentioning

confidence: 99%

“…DNA is an attractive choice for dye templating due to its customization at the nanoscale and an ability to promote the exciton delocalization of dyes. [17][18][19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34] DNA has been shown to negligibly change the electronic properties of visible-light absorbing dye monomers. 35 As such, the electronic properties of the dye monomers can be evaluated as free-dyes to screen their potential utility as DNA-templated dyes.…”

Section: Introductionmentioning

confidence: 99%

“…52 The photophysical features and extensive structural tunability make squaraines well-suited candidates for the investigation of exciton delocalization when assembled. 18,24,28,55 Although the dipole-dipole coulombic coupling between dyes must be considered to accurately predict aggregate absorption spectra, monomer transition dipole moments provide estimates of the strength of exciton delocalization for various dye congurations via the extended dipole approximation, which can be used as a guide for exciton applications. 15,56 There is also a robust body of work demonstrating the customizability of squaraine dyes, offering opportunities for the tunability of dye properties through the engineering of functional groups to yield desired properties.…”

Section: Introductionmentioning

confidence: 99%

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First-principles studies of substituent effects on squaraine dyes

et al. 2021

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Tuning Exciton Coupling of Merocyanine Nucleoside Dimers by RNA, DNA and GNA Double Helix Conformations

et al. 2022

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Exciton coupling between two or more chromophores in a specific environment is a key mechanism associated with color tuning and modulation of absorption energies. This concept is well exemplified by natural photosynthetic proteins, and can also be achieved in synthetic nucleic acid nanostructures. Here we report the coupling of barbituric acid merocyanine (BAM) nucleoside analogues and show that exciton coupling can be tuned by the double helix conformation. BAM is a nucleobase mimic that was incorporated in the phosphodiester backbone of RNA, DNA and GNA oligonucleotides. Duplexes with different backbone constitutions and geometries afforded different mutual dye arrangements, leading to distinct optical signatures due to competing modes of chromophore organization via electrostatic, dipolar, π–π‐stacking and hydrogen‐bonding interactions. The realized supramolecular motifs include hydrogen‐bonded BAM–adenine base pairs and antiparallel as well as rotationally stacked BAM dimer aggregates with distinct absorption, CD and fluorescence properties.

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Exciton Delocalization in Indolenine Squaraine Aggregates Templated by DNA Holliday Junction Scaffolds

Cited by 46 publications

References 122 publications

Excited-State Lifetimes of DNA-Templated Cyanine Dimer, Trimer, and Tetramer Aggregates: The Role of Exciton Delocalization, Dye Separation, and DNA Heterogeneity

Excited-State Lifetimes of DNA-Templated Cyanine Dimer, Trimer, and Tetramer Aggregates: The Role of Exciton Delocalization, Dye Separation, and DNA Heterogeneity

First-principles studies of substituent effects on squaraine dyes

Tuning Exciton Coupling of Merocyanine Nucleoside Dimers by RNA, DNA and GNA Double Helix Conformations

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