Annelid erythrocruorins are highly cooperative extracellular respiratory proteins with molecular masses on the order of 3.6 million Daltons. We report here the 3.5 A crystal structure of erythrocruorin from the earthworm Lumbricus terrestris. This structure reveals details of symmetrical and quasi-symmetrical interactions that dictate the self-limited assembly of 144 hemoglobin and 36 linker subunits. The linker subunits assemble into a core complex with D(6) symmetry onto which 12 hemoglobin dodecamers bind to form the entire complex. Although the three unique linker subunits share structural similarity, their interactions with each other and the hemoglobin subunits display striking diversity. The observed diversity includes design features that have been incorporated into the linker subunits and may be critical for efficient assembly of large quantities of this complex respiratory protein.

Erythrocruorins are highly cooperative giant extracellular respiratory complexes found in annelids, where they serve the same function as red blood cells. Our previous 5.5A resolution crystal structure of Lumbricus terrestris erythrocruorin revealed a hierarchical organization of 144 oxygen-binding hemoglobin chains that are assembled into 12 dodecamers arranged at the periphery of the complex around a central scaffold formed by 36 non-hemoglobin subunits. We present here the 2.6A resolution crystal structure of the Lumbricus hemoglobin dodecameric subassembly, which provides the first atomic models of the erythrocruorin allosteric core. The hemoglobin dodecamer has a molecular 3-fold axis of symmetry that relates three heterotetramers, each of which is composed of two tightly associated heterodimers. The structure reveals details of the interfaces, including key side-chain interactions likely to contribute to ligand-linked allosteric transitions, and shows the crowded nature of the ligand-binding pockets. Comparison of the Lumbricus dimeric assemblies with similar ones from mollusks and echinoderms suggests plausible pH-dependent quaternary transitions that may occur in response to proton binding and ligand release. Thus, these results provide the first step towards elucidating the structural basis for the strong allosteric properties of Lumbricus erythrocruorin.

Assembly of hemoglobin subunits into cooperative complexes produces a remarkable variety of architectures, ranging in oligomeric state from dimers to complexes containing 144 hemoglobin subunits. Diverse stereochemical mechanisms for modulating ligand affinity through intersubunit interactions have been revealed from studies of three distinct hemoglobin assemblages. This mechanistic diversity, which occurs between assemblies of subunits that have the same fold, provides insight into the range of regulatory strategies that are available to protein molecules.

Many annelids, including the earthworm Lumbricus terrestris, have giant cooperative respiratory proteins (molecular masses greater than 3.5 million Da) freely dissolved in the blood, rather than packaged in cells. These complexes, termed either erythrocruorins or hemoglobins, are assembled from many copies of both hemoglobin subunits and nonhemoglobin or "linker" subunits. In this paper, we present the crystal structure of Lumbricus erythrocruorin at 5.5-A resolution, which reveals a remarkable hierarchical organization of 144 oxygen-binding hemoglobin subunits and 36 nonhemoglobin linker subunits. The hemoglobin chains arrange in novel dodecameric substructures. Twelve trimeric linker complexes project triple-stranded helical coiled-coil "spokes" toward the center of the complex; interdigitation of these spokes appears crucial for stabilization. The resulting complex of linker chains forms a scaffold on which twelve hemoglobin dodecamers assemble. This structure specifies the unique, self-limited assemblage of a highly cooperative single molecule.