Teruhisa Hirai

Structural determinants of water permeation through aquaporin-1.

Human red cell AQP1 is the first functionally defined member of the aquaporin family of membrane water channels. Here we describe an atomic model of AQP1 at 3.8 Å resolution from electron crystallographic data. Multiple highly conserved amino-acid residues stabilize the novel fold of AQP1. The aqueous pathway is lined with conserved hydrophobic residues that permit rapid water transport, whereas the water selectivity is due to a constriction of the pore diameter to about 3 Å over a span of one residue. The atomic model provides a possible molecular explanation to a longstanding puzzle in physiology—how membranes can be freely permeable to water but impermeable to protons.

The three-dimensional structure of aquaporin-1

The entry and exit of water from cells is a fundamental process of life. Recognition of the high water permeability of red blood cells led to the proposal that specialized water pores exist in the plasma membrane. Expression in Xenopus oocytes and functional studies of an erythrocyte integral membrane protein of relative molecular mass 28,000, identified it as the mercury-sensitive water channel, aquaporin-1 (AQP1). Many related proteins, all belonging to the major intrinsic protein (MIP) family, are found throughout nature. AQP1 is a homotetramer containing four independent aqueous channels. When reconstituted into lipid bilayers, the protein forms two-dimensional lattices with a unit cell containing two tetramers in opposite orientation. Here we present the three-dimensional structure of AQP1 determined at 6Å resolution by cryo-electron microscopy. Each AQP1 monomer has six tilted, bilayer-spanning α-helices which form a right-handed bundle surrounding a central density. These results, together with functional studies, provide a model that identifies the aqueous pore in the AQP1 molecule and indicates the organization of the tetrameric complex in the membrane.

Surface of bacteriorhodopsin revealed by high-resolution electron crystallography

Bacteriorhodopsin is a transmembrane protein that uses light energy, absorbed by its chromophore retinal, to pump protons from the cytoplasm of bacteria such as Halobacterium salinarium into the extracellular space,. It is made up of seven α-helices, and in the bacterium forms natural, two-dimensional crystals called purple membranes. We have analysed these crystals by electron cryo-microscopy to obtain images of bacteriorhodopsin at 3.0 å resolution. The structure covers nearly all 248 amino acids, including loops outside the membrane, and reveals the distribution of charged residues on both sides of the membrane surface. In addition, analysis of the electron-potential map produced by this method allows the determination of the charge status of these residues. On the extracellular side, four glutamate residues surround the entrance to the proton channel, whereas on the cytoplasmic side, four aspartic acids occur in a plane at the boundary of the hydrophobic–hydrophilic interface. The negative charges produced by these aspartate residues is encircled by areas of positive charge that may facilitate accumulation and lateral movement of protons on this surface.

Structure of the Membrane Domain of Human Erythrocyte Anion Exchanger 1 Revealed by Electron Crystallography

The membrane domain of human erythrocyte anion exchanger 1 (AE1) works as a Cl(-)/HCO(3)(-) antiporter. This exchange is a key step for CO(2)/O(2) circulation in the blood. In spite of their importance, structural information about AE1 and the AE (anion exchanger) family are still very limited. We used electron microscopy to solve the three-dimensional structure of the AE1 membrane domain, fixed in an outward-open conformation by cross-linking, at 7.5-A resolution. A dimer of AE1 membrane domains packed in two-dimensional array showed a projection map similar to that of the prokaryotic homolog of the ClC chloride channel, a Cl(-)/H(+) antiporter. In a three-dimensional map, there are V-shaped densities near the center of the dimer and slightly narrower V-shaped clusters at a greater distance from the center of the dimer. These appear to be inserted into the membrane from opposite sides. The structural motifs, two homologous pairs of helices in internal repeats of the ClC transporter (helices B+C and J+K), are well fitted to those AE1 densities after simple domain movement.

Helical image reconstruction of the outward-open human erythrocyte band 3 membrane domain in tubular crystals.

The C-terminal membrane domain of erythrocyte band 3 functions as an anion exchanger. Here, we report the three-dimensional (3D) structure of the membrane domain in an inhibitor-stabilized, outward-open conformation at 18A resolution. Unstained, frozen-hydrated tubular crystals containing the membrane domain of band 3 purified from human red blood cells (hB3MD) were examined using cryo-electron microscopy and iterative helical real-space reconstruction (IHRSR). The 3D image reconstruction of the tubular crystals showed the molecular packing of hB3MD dimers with dimensions of 60 x 110 A in the membrane plane and a thickness of 70A across the membrane. Immunoelectron microscopy and carboxyl-terminal digestion demonstrated that the intracellular surface of hB3MD was exposed on the outer surface of the tubular crystal. A 3D density map revealed that hB3MD consists of at least two subdomains and that the outward-open form is characterized by a large hollow area on the extracellular surface and continuous density on the intracellular surface.

Topology models of anion exchanger 1 that incorporate the anti-parallel V-shaped motifs found in the EM structure.

We recently published the three-dimensional structure of the membrane domain of human erythrocyte anion exchanger 1 (AE1) at 7.5 Å resolution, solved by electron crystallography. The structure exhibited distinctive anti-parallel V-shaped motifs, which protrude from the membrane bilayer on both sides. Similar motifs exist in the previously reported structure of a bacterial chloride channel (ClC)-type protein. Here, we propose two topology models of AE1 that reflect the anti-parallel V-shaped structural motifs. One is assumed to have structural similarity with the ClC protein and the other is only assumed to have internal repeats, as is often the case with transporters. Both models are consistent with most topological results reported thus far for AE1, each having advantages and disadvantages.

High Resolution Structure of Bacteriorhodopsin Determined by Electron Crystallography

Abstract— Bacteriorhodopsin pumps protons from the cytoplasm to the outside of halobacteria, Halobacterium salinarium, by using absorbed light energy. The newly observed density map at 3 Å resolution clarified nearly the entire structure; the resolution in the direction perpendicular to the membrane surface is 3.2 Å. The new structure clearly indicates the proton transfer pathway in bacteriorhodopsin. In particular, the location of key aspartic acid and glutamic acid residues in the derived structural model suggested funneling structures with different designs for input and output of protons on the cytoplasmic and extracellular sides, respectively, of the protein. This paper describes the major differences between the model based on the new observation and the former model obtained through crystallographic refinement by Grigorieff et al. (J. Mol. Biol 259; 393‐421, 1996).

[Structure of human erythrocyte band 3: two-dimensional crystallographic analysis of the membrane domain].

Band 3 (also known as anion exchanger 1, AE1) is one of the most abundant membrane proteins in human erythrocytes. Band 3 has 911 amino acids and consists of two structurally and functionally distinct domains. One is a 40-kDa N-terminal cytoplasmic domain and the other is a 55-kDa C-terminal membrane domain. The cytoplasmic domain maintains red cell shape through interactions with cytoskeletal proteins, such as protein 4.1, protein 4.2, ankyrin, and spectrin. On the other hand, the membrane domain mediates electroneutral exchange of anions, such as bicarbonate and chloride across the erythrocyte membrane. We reported the three-dimensional structure of the outward-open membrane domain of band 3, which was cross-linked between K539 and K851 with H2DIDS, at 7.5 Å resolution using cryo-electron crystallography. Although the results showed significantly improved resolution as compared with previous structural analyses, we could not assign all α-helices because of low resolution and uncertainty persists regarding the fold of band 3. However, we recognized that band 3 has internal repeats, because the structure exhibited distinctive anti-parallel V-shaped motifs, which protrude from the membrane bilayer on both sides. One of the helices in the motif is very long and highly tilted with respect to the normal structure of the bilayer.