Takuya Kanamori

The lipophilic CdSe quantum dot (QD) coated with trioctylphosphine oxide (TOPOQD) can be extracted from chloroform into water upon interaction with macrocyclic glycocluster amphiphile 1. The QD-conjugated and highly fluorescent sugar ball of a size of 15 nm (TOPOQD1) thus solubilized in water readily invades Hela cells via endocytosis. The endocytic activity of TOPOQD1 (15 nm), in light of those of the micellar homoaggregate of 1 (5 nm) and the virus-like 1-DNA conjugate (50 nm) as references, reveals a dramatic size effect (50 > 15 > 5) in the subviral size region. The optimal size at approximately 50 nm indicates that size complementarity which governs molecular recognition in small host-guest systems also plays key roles in the encapsulation of nanometric guest particles by the endocytic vesicles (</=100 nm) as a macrobiomolecular host. The work thus suggests an utmost importance of size control at the viral size when designing molecular (gene, drug, probe, etc.) delivery machines.

Number- and size-controlled macromolecular associations are common in biology with viruses as a typical example. We report here a novel example of artificial viruses, in which the double-helical DNA is coated with 4-nm sized neutral glycocluster nanoparticles (GNPs) with a coating stoichiometry of approximately 2 GNPs per helical pitch (10 base pairs), where GNP arises from micellization of a cone-shaped, quadruple-chain glycocluster amphiphile having eight saccharide moieties with beta-glucoside termini on the calix[4]resorcarene macrocycle. The resulting "glycoviruses" are compactly packed (54 nm in the case of 7040 base-pair plasmid pCMVluc), are well charge-shielded (zeta congruent with approximately 0 mV), and effectively transfect cell cultures without notable cytotoxicity. The use of artificial viral vectors thus allows a new (nonamine/noncationic/nonpolymeric) access to gene delivery, a potential but still tough subject which has been studied extensively over the last 15 years by using viral or amine-based cationic vectors. The remarkable adhesion-manipulation ability of saccharide clusters also provides a strategy of bottom-up construction of nanometric or mesoscopic sizes.

We here report a novel example of artificial glycoviral vectors constructed via number- and size-controlled gene (pCMVluc, 7040 bp) coating with micellar glycocluster nanoparticles (GNPs) of calix[4]resorcarene-based macrocyclic glycocluster amphiphiles having eight or five saccharide moieties with terminal alpha-glucose (alpha-Glc), beta-glucose (beta-Glc), or beta-galactose (beta-Gal) residues. The resulting glycoviruses are compactly packed (approximately 50 nm) and well charge-shielded (zeta approximately equal 0 mV), undergo saccharide-dependent (alpha-Glc > beta-Gal >> beta-Glc) self-aggregation, and transfect cell (Hela and HepG2) cultures as triggered by the pinocytic form of endocytosis. The semilogarithmic linear size-activity correlation suggests that size-restricted pinocytosis (<100 nm) is effective only for monomeric viruses. The activities of oligomeric and otherwise poorly active beta-Gal-functionalized viruses toward hepatic HepG2 cells are approximately 10(2)-times higher than expected on the size basis, owing to the receptor-mediated specific pathway involving the asialoglycoprotein receptors on the hepatic cell surfaces. The scope and prospect of artificial glycoviruses are discussed.

Macrocyclic glycocluster compounds 2n (n = 2-7) with four alkyl (undecyl) chains and eight oligosaccharide moieties on the opposite sides of the calix[4]resorcarene macrocycle are prepared from the reactions of the corresponding octaamine derivative with maltooligosaccharide lactones. Combined evidence from dynamic light scattering (DLS), gel permeation chromatography (GPC), and transmission electron microscopy (TEM) indicates that they form small micelle-like nanoparticles (d congruent with 3 nm) in water. In the presence of Na2HPO4/NaH2PO4, nanoparticles are agglutinated with phosphate ions as a glue to grow in size up to 60-100 nm, as revealed by DLS as well as microscopy (TEM and AFM). The phosphate-induced agglutination processes can be followed by surface plasmon resonance (SPR). Amphiphile 2n is readily immobilized on the hydrophobized sensor chip of SPR to give a closely packed monolayer with oligosaccharide moieties exposed to bulk water. While there is no further adsorption of 2n on the resulting monolayer, this does occur when the latter is pretreated with the phosphate salts, ultimately giving rise to a multilayer upon repeated treatment of the chip with 2n and Na2HPO4/NaH2PO4 in an alternate manner. Kinetic analyses show that the phosphate-mediated inter(saccharide) interactions in terms of rate and affinity are markedly dependent on the oligosaccharide chain lengths (n), becoming more favorable with increasing n's. The novel aggregation and agglutination behaviors observed are discussed in terms of immobilizable and irreversible micelles on the basis of the cone-shaped structure of quadruple-chain amphiphile 2n having a huge saccharide pool and the efficiency of multiple hydrogen bonding therein. The unique intermolecular binding properties of compound 22 and analogues so far reported are reviewed in light of the present finding.