Träger, T. K.; Maity, S.; Kyrilis, F. L.; Tüting, C.; Hamdi, F.; Kafetzopoulos, G.; Brotzakis, Z. F.; Neuhaus, A.; Blanque, A.; Gatsogiannis, C.; Skretas, G.; Roos, W. H.; Kastritis, P. L.

The pyruvate dehydrogenase complex (PDHc)1 links glycolysis to the Krebs cycle by catalyzing the oxidative decarboxylation of pyruvate to acetyl-CoA and CO2, a process essential for life2,3. PDHc is formed by structural proteins (E3-binding protein, E3BP)4-7, enzymatic subunits (E1, E2, E3)4,6, and mobile lipoyl domains (LDs), the latter shuttling intermediates across active sites6,8. Although numerous details regarding pyruvate oxidation steps have been elucidated9, the precise organization of the entire PDHc remains unknown due to its large size and dynamic heterogeneity. Here, we employ in silico, in vitro, and in situ methods to propose a multi-scale model of PDHc that includes approximately one million atoms and to visualize multiple conformational states. This model reveals a ~40-50 nm nested shell structure, formed by flexible linkers that spatially coordinate the E1 and E3 enzyme complexes around the E2-E3BP core scaffold. This structure acts as a molecular sieve, selectively guiding lipoyl arms while maintaining enzyme positioning with sub-nm precision. During catalysis, the nested shell structure expands and adopts a mechanically reinforced state comparable in magnitude to viral assemblies10. Our findings provide structural context for the textbook "link reaction"11, building on decades of biochemical knowledge, are transferable to functional aspects of other -ketoacid dehydrogenase complexes, and, ultimately, expand our understanding of primary metabolism as a whole.