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W2287470078 startingPage "2724" @default.
W2287470078 abstract "Light-harvesting complexes collect light energy and deliver it by a cascade of energy and electron transfer processes to the reaction center where charge separation leads to storage as chemical energy. The design of artificial light-harvesting assemblies faces enormous challenges because several antenna chromophores need to be kept in close proximity but self-quenching needs to be avoided. Double stranded DNA as a supramolecular scaffold plays a promising role due to its characteristic structural properties. Automated DNA synthesis allows incorporation of artificial chromophore-modified building blocks, and sequence design allows precise control of the distances and orientations between the chromophores. The helical twist between the chromophores, which is induced by the DNA framework, controls energy and electron transfer and thereby reduces the self-quenching that is typically observed in chromophore aggregates. This Account summarizes covalently multichromophore-modified DNA and describes how such multichromophore arrays were achieved by Watson-Crick-specific and DNA-templated self-assembly. The covalent DNA systems were prepared by incorporation of chromophores as DNA base substitutions (either as C-nucleosides or with acyclic linkers as substitutes for the 2'-deoxyribofuranoside) and as DNA base modifications. Studies with DNA base substitutions revealed that distances but more importantly relative orientations of the chromophores govern the energy transfer efficiencies and thereby the light-harvesting properties. With DNA base substitutions, duplex stabilization was faced and could be overcome, for instance, by zipper-like placement of the chromophores in both strands. For both principal structural approaches, DNA-based light-harvesting antenna could be realized. The major disadvantages, however, for covalent multichromophore DNA conjugates are the poor yields of synthesis and the solubility issues for oligonucleotides with more than 5-10 chromophore modifications in a row. A logical alternative approach is to leave out the phosphodiester bridges between the chromophores and let chromophore-nucleoside conjugates self-assemble specifically along single stranded DNA as template. The self-organization of chromophores along the DNA template based on canonical base pairing would be advantageous because sequence selective base pairing could provide a structural basis for programmed complexity within the chromophore assembly. The self-assembly is governed by two interactions. The chromophore-nucleoside conjugates as guest molecules are recognized via hydrogen bonds to the corresponding counter bases in the single stranded DNA template. Moreover, the π-π interactions between the stacked chromophores stabilize these self-assembled constructs with increasing length. Longer DNA templates are more attractive for self-assembled antenna. The helicity in the stack of porphyrins as guest molecules assembled on the DNA template can be switched by environmental changes, such as pH variations. DNA-templated stacks of ethynyl pyrene and nile red exhibit left-handed chirality, which stands in contrast to similar covalent multichromophore-DNA conjugates with enforced right-handed helicity. With ethynyl nile red, it is possible to occupy every available binding site on the templates. Mixed assemblies of ethynyl pyrene and nile red show energy transfer and thereby provide a proof-of-principle that simple light-harvesting antennae can be obtained in a noncovalent and self-assembled fashion. With respect to the next important step, chemical storage of the absorbed light energy, future research has to focus on the coupling of sophisticated DNA-based light-harvesting antenna to reaction centers." @default.
W2287470078 created "2016-06-24" @default.
W2287470078 creator A5045441828 @default.
W2287470078 creator A5064869630 @default.
W2287470078 date "2015-09-28" @default.
W2287470078 modified "2023-09-24" @default.
W2287470078 title "One-Dimensional Multichromophor Arrays Based on DNA: From Self-Assembly to Light-Harvesting" @default.
W2287470078 cites W1911808742 @default.
W2287470078 cites W1961449228 @default.
W2287470078 cites W1970710366 @default.
W2287470078 cites W1971434667 @default.
W2287470078 cites W1973250761 @default.
W2287470078 cites W1978807824 @default.
W2287470078 cites W1979238507 @default.
W2287470078 cites W1980433289 @default.
W2287470078 cites W1997079508 @default.
W2287470078 cites W2003473742 @default.
W2287470078 cites W2005240531 @default.
W2287470078 cites W2007189194 @default.
W2287470078 cites W2009771834 @default.
W2287470078 cites W2011399997 @default.
W2287470078 cites W2015994559 @default.
W2287470078 cites W2018357537 @default.
W2287470078 cites W2020333977 @default.
W2287470078 cites W2023232631 @default.
W2287470078 cites W2023544689 @default.
W2287470078 cites W2024156372 @default.
W2287470078 cites W2027677052 @default.
W2287470078 cites W2032763020 @default.
W2287470078 cites W2033020745 @default.
W2287470078 cites W2033442223 @default.
W2287470078 cites W2036743269 @default.
W2287470078 cites W2038956823 @default.
W2287470078 cites W2039750158 @default.
W2287470078 cites W2040461143 @default.
W2287470078 cites W2046295231 @default.
W2287470078 cites W2048067383 @default.
W2287470078 cites W2055819235 @default.
W2287470078 cites W2057213837 @default.
W2287470078 cites W2059449847 @default.
W2287470078 cites W2065018791 @default.
W2287470078 cites W2068269359 @default.
W2287470078 cites W2069560513 @default.
W2287470078 cites W2070504659 @default.
W2287470078 cites W2072369418 @default.
W2287470078 cites W2073538756 @default.
W2287470078 cites W2074898729 @default.
W2287470078 cites W2075134695 @default.
W2287470078 cites W2079960520 @default.
W2287470078 cites W2081383153 @default.
W2287470078 cites W2088949859 @default.
W2287470078 cites W2089947893 @default.
W2287470078 cites W2090157142 @default.
W2287470078 cites W2092026052 @default.
W2287470078 cites W2092899663 @default.
W2287470078 cites W2095668864 @default.
W2287470078 cites W2103479959 @default.
W2287470078 cites W2105546576 @default.
W2287470078 cites W2107838477 @default.
W2287470078 cites W2112007339 @default.
W2287470078 cites W2112943591 @default.
W2287470078 cites W2114865753 @default.
W2287470078 cites W2124008527 @default.
W2287470078 cites W2125657028 @default.
W2287470078 cites W2125752397 @default.
W2287470078 cites W2129712005 @default.
W2287470078 cites W2135532067 @default.
W2287470078 cites W2141958402 @default.
W2287470078 cites W2142335656 @default.
W2287470078 cites W2145325210 @default.
W2287470078 cites W2156363739 @default.
W2287470078 cites W2158221767 @default.
W2287470078 cites W2164257432 @default.
W2287470078 cites W2173280740 @default.
W2287470078 cites W2316149515 @default.
W2287470078 cites W2330622193 @default.
W2287470078 cites W2952568692 @default.
W2287470078 cites W4232341303 @default.
W2287470078 cites W4244911827 @default.
W2287470078 cites W4251854412 @default.
W2287470078 doi "https://doi.org/10.1021/acs.accounts.5b00314" @default.
W2287470078 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/26411920" @default.
W2287470078 hasPublicationYear "2015" @default.
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