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Cooperative ligand binding is an important determinant of specificity and regulation in biomolecular complexes. Yet, its prevalence and mechanistic basis in glycan-binding proteins (GBPs) remain unclear. Here, we present the first quantitative analysis of the temperature dependence of cooperative glycan binding. Variable-temperature native mass spectrometry (VT-nMS) resolved sequential ligand binding to either the five primary or the five secondary sites of the cholera toxin B subunit homopentamer (CTB5). Stepwise apparent affinities for the primary sites reveal positive cooperativity that strengthens with both ligand occupancy and temperature. Van’t Hoff analysis shows that this temperature-enhanced cooperativity is predominantly entropy driven. Mechanistic insight from temperature replica exchange molecular dynamics simulations shows that ligand binding at one primary site restrains a loop on an adjacent subunit (counterclockwise), widening its binding site. This prestructuring progressively lowers the unfavorable conformational entropy penalty of binding, independent of the order of subunit occupancy. In contrast, sequential ligand binding at the secondary sites exhibits negligible cooperativity except at the highest temperatures, although the enthalpic and entropic contributions are comparable in magnitude to those for primary-site binding, suggesting a shared energetic framework. Together, these results provide detailed thermodynamic and structural insight into cooperative GBP–glycan interactions and establish an integrated VT-nMS and molecular dynamics framework for quantitatively probing cooperative ligand binding in complex biomolecular systems.

Many bacterial defense systems restrict phage infection by breaking the molecule NAD+ to its constituents, adenosine diphosphate ribose (ADPR) and nicotinamide (Nam). To counter NAD+ depletion-mediated defense, phages evolved NAD+ reconstitution pathway 1 (NARP1), which uses ADPR and Nam to rebuild NAD+. Here we report a bacterial defense system called aRES, involving RES-domain proteins that degrade NAD+ into Nam and ADPR-1″-phosphate (ADPR-1P). This molecule cannot serve as a substrate for NARP1, so that NAD+ depletion by aRES defends against phages even if they encode NARP1. We further discover that some phages evolved an extended NARP1 pathway capable of overcoming aRES defense. In these phages, the NARP1 operon also includes a specialized phosphatase, which dephosphorylates ADPR-1P to form ADPR, a substrate from which NARP1 then reconstitutes NAD+. Other phages encode inhibitors that directly bind aRES proteins and physically block their active sites. Our study describes new layers in the NAD+-centric arms race between bacteria and phages and highlights the centrality of the NAD+ pool in cellular battles between viruses and their hosts. ### Competing Interest Statement The authors have declared no competing interest. European Research Council, ERC-AdG GA 101018520 Israel Science Foundation, MAPATS grant 2720/22 Deutsche Forschungsgemeinschaft, SPP 2330, grant 464312965 Minerva Foundation with funding from the Federal German Ministry for Education and Research research grant from Magnus Konow in honor of his mother Olga Konow Rappaport Ministry of Aliyah and Immigrant Absorption, https://ror.org/05aycsg86 Clore Scholars Program