Pathway Complexity in Nanotubular Supramolecular Polymerization: Metal-Organic Nanotubes with a Planar-Chiral Monomer.

Here, we report an anomalous pathway complexity in the supramolecular polymerization of a chiral monomer, which displays an unusual chiroptical feature that does not follow any of the known stereochemical rules such as "chiral self-sorting" and "majority rule". We newly developed a planar-chiral ferrocene-cored tetratopic pyridyl monomer FcL, which underwent AgBF4-mediated supramolecular polymerization to give nanotubes FcNTs composed of metal-organic nanorings FcNRs. Although FcNRs must be homochiral because of a strong geometrical constraint, FcNRs were formed even efficiently from racemic FcL and AgBF4. Detailed studies revealed the presence of two competing pathways for producing homochiral FcNRs as the constituents of FcNTs: (i) spontaneous cyclization of initially formed acyclic polymers -[FcL-Ag+]n- and (ii) template (FcNR)-assisted cyclization via a Ag+···Ag+ metallophilic interaction. The dominance of the two pathways changes depending on the %ee of chiral FcL. Namely, when the %ee of FcL is high, -[FcL-Ag+]n- must contain sufficiently long homochiral sequences that can be readily cyclized into FcNRs. Meanwhile, when the %ee of FcL is low, the homochiral sequences in -[FcL-Ag+]n- must be short and therefore are hardly eligible for spontaneous cyclization. Why were FcNRs formed? Even though the probability is very low, homochiral -[FcL-Ag+]n- can be statistically generated and undergo spontaneous cyclization to give FcNRs minutely. We found that FcNRs can be amplified by heterochirally templating their own synthesis using metallophilic interaction. Because of this stereochemical preference, the growth of FcNRs into FcNTs via the template-assisted mechanism occurs only when both (R,R)FcL and (S,S)FcL are present in the polymerization system.

Intracellular Photoactivation of Caspase-3 by Molecular Glues for Spatiotemporal Apoptosis Induction.

Caspase-3 (Casp-3) is an enzyme that efficiently induces apoptosis, a form of programmed cell death. We report a dendritic molecular glue PCGlue that enables intracellular delivery of Casp-3 and its photoactivation. PCGlue carrying multiple guanidinium (Gu+) ion pendants via photocleavable linkages can tightly adhere to Casp-3 and deliver it into the cytoplasm mainly by direct penetration through the plasma membrane. Casp-3, whose surface is covered by PCGlue, is unable to interact with its cellular substrates and can therefore not induce apoptosis. However, upon exposure to UV or two-photon near-infrared (NIR) light, PCGlue is cleaved off to liberate Casp-3, triggering the apoptotic signaling cascade. This intracellular photoactivation of Casp-3 allows spatiotemporal induction of apoptosis in irradiated cells.

Nitrobenzoxadiazole-Appended Cell Membrane Modifiers for Efficient Optoporation with Noncoherent Light.

FLNBD-BAMPEG2k, bearing a nitrobenzoxadiazole (NBD) unit and an oleyl terminus conjugated via a poly(ethylene glycol) (PEG) spacer ( Mn = 2,000), was designed to fluorescently label cell membranes by docking its hydrophobic oleyl terminus. During laser scanning microscopy in a minimal essential medium (MEM), human hepatocellular carcinoma Hep3B cells labeled with FLNBD-BAMPEG2k appeared to undergo optoporation at their plasma membrane. We confirmed this unprecedented possibility by a series of cellular uptake experiments using negatively charged and therefore membrane-impermeable quantum dots (QDs; Dh = 4.7 nm). Detailed studies indicated that the photoexcited NBD unit can generate singlet oxygen (1O2), which oxidizes the constituent phospholipids to transiently deteriorate the cell membrane. Reference membrane modifiers FLNBD-Oleyl and FLNBD-BAMPEG8k having shorter or longer hydrophilic spacers between the NBD and oleyl units showed a little or substantially no optoporation. For understanding these results, one must consider the following contradictory factors: (1) The photosensitized 1O2 generation efficiently occurs only when the NBD unit is in aqueous media, and (2) the lifetime of 1O2 in aqueous media is very short (3.0-3.5 µs). As supported experimentally and computationally, the hydrophilic spacer length of FLNBD-BAMPEG2k is optimal for compromising these factors. Further to note, the optoporation using FLNBD-BAMPEG2k is not accompanied by cytotoxicity.