A 3D reconstruction of the hemoglobin (Hb) of the earthworm Lumbricus terrestris was carried out by the 3D projection alignment method from electron microscopy images of a frozen-hydrated specimen at 22 A resolution. The results were analyzed by a new approach taking into account the evolution of the 210 densities forming the 3D volume as a function of the threshold of surface representation. The whole oligomer with D6point-group symmetry is comprised of 12 hollow globular substructures (HGS) with local 3-fold symmetry tethered to a complex network of linking subunits (linker complex). The 12 globin subunits of each HGS are distributed around local 3-fold axis in four layers of three subunits. The first layer, the most external, contains monomeric globin chains 2A, 3A, and 5A. The three trimers corresponding to the nine remaining subunits have one subunit in each of the second (2B, 3B, 5B), third (1A, 4A, 6A), and fourth (1B, 4B, 6B) layer. The distances between the centers of the globin chains forming the trimers are in the ranges 20-32 A and 45-52 A. The linker complex is made up of two types of linking units. The first type forms three loops connecting globin chains of the second, third and fourth layers. The average molecular mass (Mm) of these subunits was 25 kDa. The second type forms the central structure, termed hexagonal toroid, and its 12 connections to the HGS. This structure corresponds to a hexamer of a single linking unit with a Mm (31.2 kDa), size and a shape different from those of the HGS loops. A careful study of 3D volume architecture shows that each toroid linking unit is bound to the three loops of a HGS pair located in the upper and lower hexagonal layers, respectively. As shown in a model of architecture, hexagonal bilayered (HBL) Hbs can be built very simply from 144 globin chains and 42 linker chains belonging to two different types. We also propose a simple assembly sequence for the construction of HBL Hbs based on the architecture model.
Copyright 1999 Academic Press.