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Abstract
A single glycan-lectin interaction is often weak and semi-specific. Multiple binding domains in a single lectin can bind with multiple glycan molecules simultaneously, making it difficult for the classic “lock-and-key” model to explain these interactions. We demonstrated that hetero-multivalency, a homo-oligomeric protein simultaneously binding to at least two types of ligands, influences LecA (a Pseudomonas aeruginosa adhesin)-glycolipid recognition. We also observed enhanced binding between P. aeruginosa and mixed glycolipid liposomes. Interestingly, strong ligands could activate weaker binding ligands leading to higher LecA binding capacity. This hetero-multivalency is probably mediated via a simple mechanism, Reduction of Dimensionality (RD). To understand the influence of RD, we also modeled LecA’s two-step binding process with membranes using a kinetic Monte Carlo simulation. The simulation identified the frequency of low-affinity ligand encounters with bound LecA and the bound LecA’s retention of the low-affinity ligand as essential parameters for triggering hetero-multivalent binding, agreeing with experimental observations. The hetero-multivalency can alter lectin binding properties, including avidities, capacities, and kinetics, and therefore, it likely occurs in various multivalent binding systems. Using hetero-multivalency concept, we also offered a new strategy to design high-affinity drug carriers for targeted drug delivery.
Highlights
In this article, we first focus on LecA, a homotetrameric lectin, where each monomer has a single glycan binding site[17]
To better show the data points at low concentrations, the same binding curves on a semi-log scale are shown in the supplementary information. Saturation binding curves of LecA binding to bilayers of common galactose terminated glycolipids. (c) Saturation binding curves of LecA binding to bilayers containing Gb3/LacCer mixtures. (d) φ values for 1 mol% of Gb3 mixed with different densities of LacCer
Reduction of Dimensionality (RD) is an intrinsic mechanism that seemingly occurs in all multivalent binding processes
Summary
We first focus on LecA, a homotetrameric lectin, where each monomer has a single glycan binding site[17]. Even a weak binding ligand can participate in the second or higher order binding events resulting in higher protein attachment. This intrinsic mechanism suggests that the binding of multivalent proteins is not controlled by a single type of ligand; instead, the cooperative actions between strong and weak ligands can greatly influence the overall attachment of proteins and bacteria. We hypothesized that the RD mechanism plays a key role in P. aeruginosa adhesion by influencing many different multivalent proteins, including LecA. We were excited to find that high-affinity ligands were able to activate weak binding ligands, leading to positive hetero-multivalent cooperativity. We designed a high-affinity liposome containing mixed ligands to target P. aeruginosa using the concept of the RD mechanism. Our study suggests that the inherent RD mechanism may play an essential role in various multivalent recognition systems
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