Multivalent Pattern Recognition Through Engineering of Spatial Tolerance in DNA-Based Nanomaterials

Strength in numbers, combining many weak interactions into an overall strong connection, is the fundamental principle of multivaleny. This concept has been exploiting for the engineering of super-selective cell-targeting materials, which generally display high number of flexible ligands to enhance the systems' avidity. Many biological processes, however, function through a temporal spatial organization of receptors in patterns, matching with a controlled number of ligands to create a specific interaction. In this low-valency regime, the mechanics e.g. rigidity of the ligand-presenting architecture plays a critical role in the selectivity of the multivalent complex. Exploiting the precision in spatial design inherent to DNA nanotechnology, we engineered a library of scaffolds to explore how valency, affinity, and rigidity control the balance of super-selective multivalent binding. Depending on the affinity between the ligand and receptor, a pattern-dependent binding behavior was achieved when spatial tolerance of ligands matches the spatial organization of the target. We label this new form of mechanics-controlled multivalent binding "multivalent pattern recognition" (MPR). The main parameter controlling MPR is the rigidity of the ligand, which controls the over spatial tolerance of binding. Our findings contribute to the rational design of selective targeting with nanomaterials.

Phage Selection of Photoswitchable Peptide Ligands

Silvia Bellotto, Shiyu Chen, Christian Heinis, Inmaculada Rentero Rebollo, Hermann A. Wegner

Photoswitchable ligands are powerful tools to control biological processes at high spatial and temporal resolution. Unfortunately, such ligands exist only for a limited number of proteins and their development by rational design is not trivial. We have developed an in vitro evolution strategy to generate light-activatable peptide ligands to targets of choice. In brief, random peptides were encoded by phage display, chemically cyclized with an azobenzene linker, exposed to UV light to switch the azobenzene into cis conformation, and panned against the model target streptavidin. Isolated peptides shared strong consensus sequences, indicating target-specific binding. Several peptides bound with high affinity when cyclized with the azobenzene linker, and their affinity could be modulated by UV light. The presented method is robust and can be applied for the in vitro evolution of photoswitchable ligands to virtually any target.

American Chemical Society2014

A facility to search for hidden particles at the CERN SPS: the SHiP physics case

Kyrylo Bondarenko, Alexey Boyarsky, Marco Drewes, Shintaro Eijima, Oleg Ruchayskiy, Lesya Shchutska, Anurag Tripathi

This paper describes the physics case for a new fixed target facility at CERN SPS. The SHiP (search for hidden particles) experiment is intended to hunt for new physics in the largely unexplored domain of very weakly interacting particles with masses below the Fermi scale, inaccessible to the LHC experiments, and to study tau neutrino physics. The same proton beam setup can be used later to look for decays of tau-leptons with lepton flavour number non-conservation, tau -> 3 mu and to search for weakly-interacting sub-GeV dark matter candidates. We discuss the evidence for physics beyond the standard model and describe interactions between new particles and four different portals-scalars, vectors, fermions or axion-like particles. We discuss motivations for different models, manifesting themselves via these interactions, and how they can be probed with the SHiP experiment and present several case studies. The prospects to search for relatively light SUSY and composite particles at SHiP are also discussed. We demonstrate that the SHiP experiment has a unique potential to discover new physics and can directly probe a number of solutions of beyond the standard model puzzles, such as neutrino masses, baryon asymmetry of the Universe, dark matter, and inflation.

Institute of Physics2016

DNA-based biomaterials for nanoscale controlled modulation of immune cells

Alice Comberlato

Recent advances in the field of nanomaterials demonstrated how their use for vaccination can drastically improve immune responses, mainly by enhancing delivery and uptake of vaccine components. However, our understanding of the connections between presentation of immune-modulatory agents on nanomaterials and cellular responses is still very limited. DNA-based nanostructures evolved as an ideal platform to display ligands with unprecedented nanoscale precision for the investigation and control of ligand-receptor interactions involved in cellular activation, being at the same time a carrier for these therapeutics. With this work, we aim to set the next steps for DNA nanoparticles to become functional structures in medicine and to develop DNA-based nanomaterials to study aspects of the complexity of our immune system.In Chapter 1, the latest developments and key features of immune-engineering nanomaterials for vaccination with nucleic acid adjuvants are summarized. Moreover, we report the importance of ligand spacing as new parameter in multivalent systems for immune modulation and how DNA-based nanomaterials demonstrated the significance of ligand patterns for regulated cellular responses.In Chapter 2, we developed a DNA origami disk-shaped nanoparticle with nanoscale control on ligand presentation, to be used as platform for cellular interaction studies at the single-molecule level. By DNA-PAINT super resolution microscopy, we verified spatial patterns on our nanoparticle, showing that our in silico design matches at the one-nanometer-level with experimental measurements. Additionally, we verified that the oligolysine-PEG protective coating does not hamper the accessibility of functional sites. In Chapter 3, we present a systematic analysis of the effects of surface parameters of DNA-based nanoparticles on cellular uptake. We demonstrated the influence of surface charge, stabilizing coating, fluorophore types, functionalization technique, and particle concentration on material uptake in three different cell models: tumor cells, macrophages, and dendritic cells. Additionally, we showed approaches to reduce the risk of data artifacts in vitro. In Chapter 4, we employed our DNA platform to demonstrate the importance of controlling the spacing of adjuvant presentation on nanoparticles for the activation of immune cells. Exploiting pre-existing crystallography data, we created DNA disk nanoparticles presenting CpG-motif adjuvants in rationally designed spatial patterns to activate Toll-like Receptor 9. We showed that stronger immune activation is achieved when CpG ligands are matching the distance of the binding sites of the active dimer form of the receptor, compared to random presentation or free form of CpG at equal dose. Moreover, we show how linkers for conjugating active molecules to nanomaterials alter the spatial tolerance of binding and cell activation levels. Taken together, our results show that proper receptor targeting and engineering surface parameters for uptake of nanomaterials would help to develop potent and specific immune therapies. The rationally designed and spatially controlled presentation of therapeutics would aid future vaccine strategies to manipulate the immune system at the nanoscale level and to improve dose sparing, limiting toxicity often associated with the use of high doses of drugs.

EPFL2022

DNA-based biomaterials for nanoscale controlled modulation of immune cells

Alice Comberlato

EPFL2022