Oligodimethylsiloxane-Oligoproline Block Co-Oligomers: the Interplay between Aggregation and Phase Segregation in Bulk and Solution.

Discrete block co-oligomers (BCOs) assemble into highly ordered nanostructures, which adopt a variety of morphologies depending on their environment. Here, we present a series of discrete oligodimethylsiloxane-oligoproline (oDMS-oPro) BCOs with varying oligomer lengths and proline end-groups, and study the nanostructures formed in both bulk and solution. The conjugation of oligoprolines to apolar siloxanes permits a study of the aggregation behavior of oligoproline moieties in a variety of solvents, including a highly apolar solvent like methylcyclohexane. The apolar solvent is more reminiscent of the polarity of the siloxane bulk, which gives insights into the supramolecular interactions that govern both bulk and solution assembly processes of the oligoproline. This extensive structural characterization allows the bridging of the gap between solution and bulk assembly. The interplay between the aggregation of the oligoproline block and the phase segregation induced by the siloxane drives the assembly. This gives rise to disordered, micellar microstructures in apolar solution and crystallization-driven lamellar nanostructures in the bulk. While most di- and triblock co-oligomers adopt predictable morphological features, one of them, oDMS15-oPro6-NH2, exhibits pathway complexity leading to gel formation. The pathway selection in the complex interplay between aggregation and phase segregation gives rise to interesting material properties.

Delivery of myo-Inositol Hexakisphosphate to the Cell Nucleus with a Proline-Based Cell-Penetrating Peptide.

Inositol hexakisphosphate (InsP6 ) is a central member of the inositol phosphate messengers in eukaryotic cells. Tools to manipulate the level of InsP6 , particularly with compartment selectivity, are needed to enable functional cellular studies. We present cationic octa-(4S)guanidiniumproline (Z8) for the delivery of InsP6 into the cell nucleus. CD spectroscopy, binding affinity, dynamic light scattering, and computational studies revealed that Z8 binds tightly to InsP6 and upon binding undergoes a conformational change from a PPII-helical structure to a structure that forms aggregates. The unique conformational features of the cationic oligoproline enable complex formation and cellular delivery of InsP6 with considerably greater efficacy than the flexible counterpart octaarginine.

Oligoprolines guide the self-assembly of quaterthiophenes.

Control over the molecular organization of π-conjugated oligothiophenes into different types of supramolecular assemblies is key to their use in organic electronics but difficult to achieve as these chromophores have a pronounced tendency to aggregate. Herein we show that oligoprolines, which do not self-assemble on their own, control the self-assembly of quaterthiophenes. Spectroscopic, microscopic, and diffraction studies with quaterthiophene-oligoproline conjugates revealed the formation of mono- or double-layered sheets or, alternatively, helically twisted ribbons - depending on the length of the oligoproline. The dimensions of the nanoscopic objects, which extend into the micrometer regime, correlate with the molecular dimensions of the quaterthiophene-oligoproline building blocks.

Organic Molecular Weaves.

Weaving of organic compounds on the molecular level is an intriguing challenge and promises to provide materials that combine high elasticity with strength and fracture toughness. Yet, the formation of crossing points between molecular threads in defined and regular distances to create an interwoven network is not trivial. To date, only a few examples of wholly organic weaves have been reported. Within this review we present the different strategies that enabled their formation and highlight the structural features of the obtained nanostructured materials. We expect these pioneering studies to pave the way to many more organic molecular weaves with more and more sophisticated topologies and exquisite mechanical properties.