Bio-orthogonal Coupling as a Means of Quantifying the Ligand Density on Hydrophilic Quantum Dots

We describe the synthesis of two metal-coordinating ligands that present one or two lipoic acid (LA) anchors, a hydrophilic polyethylene glycol (PEG) segment and a terminal reactive group made of an azide or an aldehyde, two functionalities with great utility in bio-orthogonal coupling techniques. These ligands were introduced onto the QD surfaces using a combination of photochemical ligation and mixed cap exchange strategy, where control over the fraction of azide and aldehyde groups per nanocrystal can be easily achieved: LA-PEG-CHO, LA-PEG-N₃, and bis­(LA)-PEG-CHO. We then demonstrate the application of two novel bio-orthogonal coupling strategies directly on luminescent quantum dot (QD) surfaces that use click chemistry and hydrazone ligation under catalyst-free conditions. We applied the highly efficient hydrazone ligation to couple 2-hydrozinopyridine (2-HP) to aldehyde-functionalized QDs, which produces a stable hydrazone chromophore with a well-defined optical signature. This unique optical feature has enabled us to extract a measure for the ligand density on the QDs for a few distinct sizes and for different ligand architectures, namely mono-LA-PEG and bis­(LA)-PEG. We found that the foot-print-area per ligand was unaffected by the nanocrystal size but strongly depended on the ligand coordination number. Additionally, we showed that when the two bio-orthogonal functionalities (aldehyde and azide) are combined on the same QD platform, the nanocrystal can be specifically reacted with two distinct targets and with great specificity. This design yields QD platforms with distinct chemoselectivities that are greatly promising for use as carriers for in vivo imaging and delivery

Multidentate Zwitterionic Ligands Provide Compact and Highly Biocompatible Quantum Dots

Hydrophilic functional semiconductor nanocrystals that are also compact provide greatly promising platforms for use in bioinspired applications and are thus highly needed. To address this, we designed a set of metal coordinating ligands where we combined two lipoic acid groups, bis­(LA)-ZW, (as a multicoordinating anchor) with a zwitterion group for water compatibility. We further combined this ligand design with a new photoligation strategy, which relies on optical means instead of chemical reduction of the lipoic acid, to promote the transfer of CdSe-ZnS QDs to buffer media. In particular, we found that the QDs photoligated with this zwitterion-terminated bis­(lipoic) acid exhibit great colloidal stability over a wide range of pHs, to an excess of electrolytes, and in the presence of growth media and reducing agents, in addition to preserving their optical and spectroscopic properties. These QDs are also stable at nanomolar concentrations and under ambient conditions (room temperature and white light exposure), a very promising property for fluorescent labeling in biology. In addition, the compact ligands permitted metal–histidine self-assembly between QDs photoligated with bis­(LA)-ZW and two different His-tagged proteins, maltose binding protein and fluorescent mCherry protein. The remarkable stability of QDs capped with these multicoordinating and compact ligands over a broad range of conditions and at very small concentrations, combined with the compatibility with metal–histidine conjugation, could be very useful for a variety of applications, ranging from protein tracking and ligand–receptor binding to intracellular sensing using energy transfer interactions

Understanding the Self-Assembly of Proteins onto Gold Nanoparticles and Quantum Dots Driven by Metal-Histidine Coordination

Coupling of polyhistidine-appended biomolecules to inorganic nanocrystals driven by metal-affinity interactions is a greatly promising strategy to form hybrid bioconjugates. It is simple to implement and can take advantage of the fact that polyhistidine-appended proteins and peptides are routinely prepared using well established molecular engineering techniques. A few groups have shown its effectiveness for coupling proteins onto Zn- or Cd-rich semiconductor quantum dots (QDs). Expanding this conjugation scheme to other metal-rich nanoparticles (NPs) such as AuNPs would be of great interest to researchers actively seeking effective means for interfacing nanostructured materials with biology. In this report, we investigated the metal-affinity driven self-assembly between AuNPs and two engineered proteins, a His₇-appended maltose binding protein (MBP-His) and a fluorescent His₆-terminated mCherry protein. In particular, we investigated the influence of the capping ligand affinity to the nanoparticle surface, its density, and its lateral extension on the AuNP-protein self-assembly. Affinity gel chromatography was used to test the AuNP-MPB-His₇ self-assembly, while NP-to-mCherry-His₆ binding was evaluated using fluorescence measurements. We also assessed the kinetics of the self-assembly between AuNPs and proteins in solution, using time-dependent changes in the energy transfer quenching of mCherry fluorescent proteins as they immobilize onto the AuNP surface. This allowed determination of the dissociation rate constant, <i>K</i>_d^–1 ∼ 1–5 nM. Furthermore, a close comparison of the protein self-assembly onto AuNPs or QDs provided additional insights into which parameters control the interactions between imidazoles and metal ions in these systems

Combining Ligand Design with Photoligation to Provide Compact, Colloidally Stable, and Easy to Conjugate Quantum Dots

We describe the design and synthesis of two compact multicoordinating (lipoic acid-appended) zwitterion ligands for the capping of luminescent quantum dots, QDs. This design is combined with a novel and easy to implement photoligation strategy to promote the in situ ligand exchange and transfer of the QDs to buffer media. This method involves the irradiation of the native hydrophobic nanocrystals in the presence of the ligands, which promotes in situ cap exchange and phase transfer of the QDs, eliminating the need for a chemical reduction of the dithiolane groups. Applied to the present LA-zwitterion ligands, this route has provided QDs with high photoluminescence yields and excellent colloidal stability over a broad range of conditions, including acidic and basic pH, in the presence of growth media and excess salt conditions. The small lateral extension of the capping layer allowed easy conjugation of the QDs to globular proteins expressing a terminal polyhistidine tag, where binding is promoted by metal-affinity interactions between the accessible Zn-rich surface and imidazoles in the terminal tag of the proteins. The ability to carry out conjugation in acidic as well as basic conditions opens up the possibility to use such self-assembled QD-protein conjugates in various biological applications

Growth of Highly Fluorescent Polyethylene Glycol- and Zwitterion-Functionalized Gold Nanoclusters

We have prepared and characterized a new set of highly fluorescent gold nanoclusters (AuNCs) using one-step aqueous reduction of a gold precursor in the presence of bidentate ligands made of lipoic acid anchoring groups, appended with either a poly(ethylene glycol) short chain or a zwitterion group. The AuNCs fluoresce in the red to near-infrared region of the optical spectrum with emission centered at ∼750 nm and a quantum yield of ∼10–14%, and they exhibit long fluorescence lifetimes (up to ∼300 ns). Dispersions of these AuNCs exhibit great long-term colloidal stability, over a wide range of pHs (2–13) and in the presence of high electrolyte concentrations, and a strong resistance to reducing agents such as glutathione. The growth strategy further permitted the controlled, <i>in situ</i> functionalization of the NCs with reactive groups (<i>e.g</i>., carboxylic acid or amine), making these nanoclusters compatible with common and simple-to-implement coupling strategies, such as carbodiimide chemistry. These properties combined make these fluorescent NCs greatly promising for use in various imaging and sensing applications where NIR and long-lived excitations are desired

Non-Invasive Characterization of the Organic Coating of Biocompatible Quantum Dots Using Nuclear Magnetic Resonance Spectroscopy

Colloidal quantum dots, made of semiconductor cores and surface coated with an organic shell, have generated much interest in areas ranging from spectroscopy to charge and energy transfer interactions to device design, and as probes in biology. Despite the remarkable progress in the growth of these materials, rather limited information about the molecular arrangements of the organic coating is available. Here, several nuclear magnetic resonance (NMR) spectroscopic techniques have been combined to characterize the surface ligand structure(s) on biocompatible CdSe-ZnS quantum dots (QDs). These materials have been prepared via a photoinduced ligand exchange method in which the native hydrophobic coating is substituted, in situ, with a series of polyethylene glycol-modified lipoic acid-based ligands. We first combined diffusion ordered spectroscopy with heteronuclear single-quantum coherence measurements to outline the conditions under which the detected proton signals emanate from only surface-bound ligands and identify changes in the proton shifts between free and QD-bound ligands in the sample. Quantification of the ligand density on different size QDs was implemented by comparing the sharp ¹H signature(s) of lateral groups in the ligands (e.g., the OCH₃ group) to an external standard. We found that both the molecular architecture of the ligand and the surface curvature of the QDs combined play important roles in the surface coverage. Given the non-invasive nature of NMR as an analytical technique, the extracted information about the ligand arrangements on the QD surfaces in hydrophilic media will be highly valuable; it has great implications for the use of QDs in targeting and bioconjugation, cellular imaging, and energy and charge transfer interactions

Controlling the Architecture, Coordination, and Reactivity of Nanoparticle Coating Utilizing an Amino Acid Central Scaffold

We have developed a versatile strategy to prepare a series of multicoordinating and multifunctional ligands optimized for the surface-functionalization of luminescent quantum dots (QDs) and gold nanoparticles (AuNPs) alike. Our chemical design relies on the modification of l-aspartic acid precursor to controllably combine, through simple peptide coupling chemistry, one or two lipoic acid (LA) groups and poly­(ethylene glycol) (PEG) moieties in the same ligand. This route has provided two sets of modular ligands: (i) bis­(LA)-PEG, which presents two lipoic acids (higher coordination) appended onto a single end-functionalized PEG, and (ii) LA-(PEG)₂ made of two PEG moieties (higher branching, with various end reactive groups) appended onto a single lipoic acid. These ligands are combined with a new photoligation strategy to yield hydrophilic and reactive QDs that are colloidally stable over a broad range of conditions, including storage at nanomolar concentration and under ambient conditions. AuNPs capped with these ligands exhibit excellent stability in various biological conditions and improved resistance against NaCN digestion. This route also provides compact nanocrystals with tunable surface reactivity. As such, we have covalently coupled QDs capped with bis­(LA)-PEG-COOH to transferrin to facilitate intracellular uptake. We have also characterized and quantified the coupling of dye-labeled peptides to QD surfaces using fluorescence resonance energy transfer interactions in QD–peptide–dye assemblies

Photoinduced Phase Transfer of Luminescent Quantum Dots to Polar and Aqueous Media

We report a new strategy for the photomediated phase transfer of luminescent quantum dots, QDs, and potentially other inorganic nanocrystals, from hydrophobic to polar and hydrophilic media. In particular, we demonstrate that UV-irradiation (λ < 400 nm) promotes the in situ ligand exchange on hydrophobic CdSe QDs with lipoic acid (LA)-based ligands and their facile QD transfer to polar solvents and to buffer media. This convenient method obviates the need to use highly reactive agents for chemical reduction of the dithiolane groups on the ligands. It maintains the optical and spectroscopic properties of the QDs, while providing high photoluminescence yield and robust colloidal stability in various biologically relevant conditions. Furthermore, development of this technique significantly simplifies the preparation and purification of QDs with sensitive functionalities. Application of these QDs to imaging the brain of live mice provides detailed information about the brain vasculature over the period of a few hours. This straightforward approach offers exciting possibilities for expanded functional compatibilities and reaction orthogonality on the surface of inorganic nanocrystals

Intracellular Delivery of Luminescent Quantum Dots Mediated by a Virus-Derived Lytic Peptide

We describe a new quantum dot (QD)-conjugate prepared with a lytic peptide, derived from a nonenveloped virus capsid protein, capable of bypassing the endocytotic pathways and delivering large amounts of QDs to living cells. The polypeptide, derived from the Nudaurelia capensis Omega virus, was fused onto the C-terminus of maltose binding protein that contained a hexa-HIS tag at its N-terminus, allowing spontaneous self-assembly of controlled numbers of the fusion protein per QD via metal–HIS interactions. We found that the efficacy of uptake by several mammalian cell lines was substantial even for small concentrations (10–100 nM). Upon internalization the QDs were primarily distributed outside the endosomes/lysosomes. Moreover, when cells were incubated with the conjugates at 4 °C, or in the presence of chemical endocytic inhibitors, significant intracellular uptake continued to occur. These findings indicate an entry mechanism that does not involve endocytosis, but rather the perforation of the cell membrane by the lytic peptide on the QD surfaces