Progress towards visualizing the controlled assembly of gold nanoparticles on DNA

Elmuccio, Michael L.

18 July 2011

Our laboratory has used the 1,4,5,8 Naphthalenetetracarboxylic diimine (NDI) unit to develop threading polyintercalators that bind DNA with the NDI units intercalated in between GpG steps and two different peptide linkers, which connect the NDI units, situated in either the major or minor grooves. The first generation bisintercalators, G₃K and [beta]Ala₃K, were shown to bind two different sequences of DNA, where the peptide linkers reside in the major and minor grooves respectively. These binding modules were then combined to generate threading polyintercalators that bound different DNA sequences with simultaneous occupation of both grooves. In particular, a cyclic bisintercalator was designed and DNAse I footprinting revealed a strong preference for the sequence 5'-GGTACC-3'. NMR structural studies of the complex with d(CGGTACCG)₂ verified a pseudocatenane structure in which the NDI units reside four base pairs apart, with one linker located in the minor groove and the other in the major groove. This was the first structurally well-characterized pseudocatenane complex between a sequence-specific cyclic bisintercalator and its preferred binding sequence. The ability to simultaneously occupy both groves of the same sequence is interesting for several reasons. Most significantly, it raises questions about a complex DNA intercalator's ability to locate its preferred sequence within a long strand of DNA. In order to directly assess this, the intercalator was modified (CBI-Cys) to incorporate a gold nanoparticle probe to allow for the direct visualization of the intercalator locating its preferred sequence within a long DNA strand. The appropriate protocols to visualize DNA using electron and atomic force microscopy were unsuccessful; however, the foundation has been set for future work to develop the appropriate method to determine the mechanism by which the cyclic bisintercalator locates its preferred sequence. Additionally, the bisintercalators developed in our laboratory offered a unique opportunity to exploit their sequence specificity for controlled nanoparticle assembly. Over the past decade, nanoparticles and DNA have been used to develop novel nanoparticle assembly systems with the goal of developing electronic devices and nanomaterials. The G₃K bisintercalator was synthetically modified to incorporate a gold nanoparticle probe. This intercalator-nanoparticle conjugate, BisKC·Au, maintained its binding specificity (5'-GGTACC-3') to a modified DNA fragment containing multiple G₃K binding sites. The atomic force microscope has become the most promising tool in visualizing individual DNA molecules. A modified procedure utilized APS to allow for the direct visualizing of plasmid DNA. The framework is now in place to confirm the controlled assembly of the gold nanoparticles. This protocol can then be used for the [beta]Ala₃K bisintercalator to lead to the development of a nanoparticle assembly system that can precisely control the organization of multiple types of nanoparticles. / text

Gold nanoparticles

Sequence-specific DNA intercalators

Controlled assembly

DNA

Foldamères peptidomimétiques à base d’urées : vers le développement de structures complexes mimes d’architectures biologiques / Peptidomimetic foldamers based on urea : towards the design of more complex structures mimicking biological architectures

Frémaux, Juliette

08 October 2013

La fonction d’une protéine dépend dans une large mesure de sa structure tridimensionnelle, c’est pourquoi de nombreux chercheurs se sont passionnés pour la synthèse des foldamères, molécules de synthèse, bioinspirées, capables d’adopter des structures repliées bien définies. Parmi les différentes classes de foldamères, les oligourées aliphatiques étudiées dans notre laboratoire s’organisent pour former des structures hélicoïdales voisines de l’hélice α des polypeptides naturels. Pour développer des hélices fonctionnelles mimes de structures biologiques, il est intéressant de mieux comprendre les règles de leur repliement, par exemple en modifiant la nature des unités monomériques. Au cours de cette thèse, nous avons donc testé la compatibilité de la géométrie de l’hélice d’oligourée avec des résidus comportant de fortes contraintes stériques comme des groupements gem-diméthyles et des cycles pyrrolidines. En utilisant les résidus pyrrolidine, nous avons ensuite développé une nouvelle stratégie de synthèse par condensation de segments permettant de concevoir des hélices de grande taille (jusqu’à 4 nm). Grâce à cette nouvelle stratégie de synthèse et aux informations obtenues sur la stabilité des hélices nous avons pu concevoir des architectures plus complexes (structures quaternaires) résultant de l’assemblage programmé d’hélices hydrosolubles. / The biological functions of proteins are mainly correlated to their tridimensional structure. For this reason a large number of chemists are interested in the synthesis of foldamers, which are bioinspired artificial molecules possessing well-defined folded conformations. In particular, in our laboratories we focused on the study of oligourea foldamers, which form well-defined and remarkably stable helical structures, analogous to the natural polypeptides α-helix. In order to develop artificial functional helices able to mimic biological structures, it is interesting to understand the rules governing their folding, for example by comparing different residues substitution patterns. During this thesis we have investigated the compatibility of the helix geometry with residues containing steric constraints, such as gem-dimethylated units or pyrrolidine cycle. We have developed a new segment condensation strategy based on these residues, which enabled the facile synthesis of long helical segments (up to 4 nm). The use of this novel approach, combined with the information acquired on helical stability allowed us to produce more complex architectures (quaternary structures) resulting from the controlled assembly of water soluble helices.

Foldamères

Oligourées hélicoïdales

Résidus gem-diméthyle

Cycle pyrrolidine

Assemblage controlé

Oligomères chimères

Foldamers

Helical oligoureas

Gem-dimethylated residues

Pyrrolidine ring

Controlled assembly

Chimeric oligomers

Řízení struktury polymerního nanokompozitu pomocí magnetického pole / Control of polymer nanocomposite structure via magnetic field

Netočný, Martin

January 2017

This work is dealing with usage of external magnetic field for controlled orientation of structures assembled from magnetic Fe3O4 nanoparticles in PMMA matrix processed via solvent casting method and further study of these created anisotropic structures and their influence on mechanical properties of composite material.