Natures reliance on multivalency [1] as a means [2] of compensating for weak monovalent protein-ligand interactions is now a widely accepted phenomenon [3] which controls a panoply of biological events and whose delicate manipulations could have far-reaching therapeutic implications. In recent times, the physical basis of multivalency effects, based on a thermodynamic model combined with computational studies, has been explored rigorously [4] and a comprehensive thermodynamic investigation of the calcium-EDTA interactions has been reported.[5] Since thermodynamics seem, by and large, [6] to rule the roost as far as multivalency is concerned, it occurred to us that it should be the perfect phenomenon to probe using the concept of dynamic covalent chemistry.[7] Herein we describe a situation in which the concept works in the exclusive context of the phenomenon; that is, dynamic covalent chemistry can be achieved in a highly efficient manner using multivalent ligands, but fails altogether when no ligand or a monovalent counterpart is employed.As a part of some on-going research to probe multivalency in artificial systems [8] exhibiting molecular recognition, we have recently uncovered a compelling example [9] of multivalency between a tritopic receptor, in which three benzo [24]crown-8 rings are fused onto a triphenylene core, and a trifurcated trication, wherein three dibenzylammonium ions are linked 1,3,5 to a central benzenoid core: the outcome is an extremely stable (K a > 10 7 mol L À1 in CH 2 Cl 2 ) triply threaded, two-component superbundle. This observation led subsequently to the template-directed synthesis [10] of a prototype [11] of an artificial molecular machine, [12] namely, a mechanically interlocked, triply threaded, molecular bundle by kinetically controlled post-assembly covalent modification. The advent of dynamic covalent chemistry [7] has, however, opened up an attractive alternative route [13] to mechanically interlocked molecules which relies upon the thermodynamically controlled strict self-assembly of their covalently linked components proceeding in unison with mechanical bond formation under the guidance of the templation provided by noncovalent interactions. In particular, it has been shown that 1) the reversible ring-closing metathesis (RCM) reaction and 2) the ring-opening, ringclosing metathesis (RORCM) reaction, also operating under equilibrium control, are both mediated by functional-grouptolerant ruthenium-alkylidene catalysts [14] and can be used [15] in the thermodynamically controlled synthesis of catenanes and rotaxanes. [16] In the specific knowledge that [2]rotaxanes [17] and [3]catenanes, [18] where the supramolecular assistance [19] for their formation comes from the interaction [20] of CH 2 NH 2 + CH 2 ion centers, either by developing olefinic crown ether analogues containing 24-membered rings or with dibenzo [24]crown-8, we decided to explore the possibility that the multivalency effect can be exploited during RCM and RORCM. We demonstrate that it can be exploited in a c...
