The structure of the light-harvesting chlorophyll a/b-protein complex, an integral membrane protein, has been determined at 3.4 A resolution by electron crystallography of two-dimensional crystals. Two of the three membrane-spanning alpha-helices are held together by ion pairs formed by charged residues that also serve as chlorophyll ligands. In the centre of the complex, chlorophyll a is in close contact with chlorophyll b for rapid energy transfer, and with two carotenoids that prevent the formation of toxic singlet oxygen.
The nicotinic acetylcholine receptor controls electrical signalling between nerve and muscle cells by opening and closing a gated, membrane-spanning pore. Here we present an atomic model of the closed pore, obtained by electron microscopy of crystalline postsynaptic membranes. The pore is shaped by an inner ring of 5 alpha-helices, which curve radially to create a tapering path for the ions, and an outer ring of 15 alpha-helices, which coil around each other and shield the inner ring from the lipids. The gate is a constricting hydrophobic girdle at the middle of the lipid bilayer, formed by weak interactions between neighbouring inner helices. When acetylcholine enters the ligand-binding domain, it triggers rotations of the protein chains on opposite sides of the entrance to the pore. These rotations are communicated through the inner helices, and open the pore by breaking the girdle apart.
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 3.8A 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 A 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.
Gap junctions consist of arrays of intercellular channels between adjacent cells that permit the exchange of ions and small molecules. Here we report the crystal structure of the gap junction channel formed by human connexin 26 (Cx26, also known as GJB2) at 3.5 A resolution, and discuss structural determinants of solute transport through the channel. The density map showed the two membrane-spanning hemichannels and the arrangement of the four transmembrane helices of the six protomers forming each hemichannel. The hemichannels feature a positively charged cytoplasmic entrance, a funnel, a negatively charged transmembrane pathway, and an extracellular cavity. The pore is narrowed at the funnel, which is formed by the six amino-terminal helices lining the wall of the channel, which thus determines the molecular size restriction at the channel entrance. The structure of the Cx26 gap junction channel also has implications for the gating of the channel by the transjunctional voltage.
Activation of G protein-coupled receptors (GPCRs) is triggered and regulated by structural rearrangement of the transmembrane heptahelical bundle containing a number of highly conserved residues. In rhodopsin, a prototypical GPCR, the helical bundle accommodates an intrinsic inverse-agonist 11-cis-retinal, which undergoes photo-isomerization to the all-trans form upon light absorption. Such a trigger by the chromophore corresponds to binding of a diffusible ligand to other GPCRs. Here we have explored the functional role of water molecules in the transmembrane region of bovine rhodopsin by using x-ray diffraction to 2.6 Å. The structural model suggests that water molecules, which were observed in the vicinity of highly conserved residues and in the retinal pocket, regulate the activity of rhodopsin-like GPCRs and spectral tuning in visual pigments, respectively. To confirm the physiological relevance of the structural findings, we conducted single-crystal microspectrophotometry on rhodopsin packed in our three-dimensional crystals and show that its spectroscopic properties are similar to those previously found by using bovine rhodopsin in suspension or membrane environment. C ell surface membrane receptors mediate a variety of biological signaling processes that are triggered by a multitude of diffusible molecules or light in the case of visual pigments. G protein-coupled receptors (GPCRs), including the rhodopsinlike family as a dominant subgroup, are the largest group of membrane receptors. Many of the members are considered as primary drug targets for various medical and pharmacological interventions. These receptors appear to be activated by a mechanism involving common heptahelical transmembrane architecture that undergoes major rearrangement upon signal reception, resulting in activation of the heterotrimeric G protein molecules.Rhodopsin from retinal rod cells mediates scotopic vision. It is a unique member among GPCRs in that it contains an intrinsic inverse-agonist, the 11-cis-retinal. Photon absorption results in retinal isomerization to the all-trans configuration, which drives the protein to the active metarhodopsin form (M II) (1). Visual pigments mediating color vision in cone cells share a common mechanism to evoke a cellular signaling cascade (2) through interaction between the M II state and the G protein. A view of the seven helices of bovine rhodopsin was provided by electron crystallography in 1993 (3), and an x-ray crystallographic study recently determined its structure at 2.8-Å resolution (4). This structure provided the template model at high resolution for the rhodopsin-like GPCRs and has been further refined at the same resolution (5).The 11-cis-retinal chromophore is covalently bound to Lys-296 in transmembrane helix VII by a protonated Schiff base linkage, which is stabilized by the negatively charged counterion Glu-113 in helix III. Disruption of this salt bridge (6) upon proton transfer is thought to trigger conformational changes in rhodopsin (7), which are necessary for G protein ...
We found adult human stem cells that can generate, from a single cell, cells with the characteristics of the three germ layers. The cells are stress-tolerant and can be isolated from cultured skin fibroblasts or bone marrow stromal cells, or directly from bone marrow aspirates. These cells can self-renew; form characteristic cell clusters in suspension culture that express a set of genes associated with pluripotency; and can differentiate into endodermal, ectodermal, and mesodermal cells both in vitro and in vivo. When transplanted into immunodeficient mice by local or i.v. injection, the cells integrated into damaged skin, muscle, or liver and differentiated into cytokeratin 14-, dystrophin-, or albumin-positive cells in the respective tissues. Furthermore, they can be efficiently isolated as SSEA-3(+) cells. Unlike authentic ES cells, their proliferation activity is not very high and they do not form teratomas in immunodeficient mouse testes. Thus, nontumorigenic stem cells with the ability to generate the multiple cell types of the three germ layers can be obtained through easily accessible adult human mesenchymal cells without introducing exogenous genes. These unique cells will be beneficial for cell-based therapy and biomedical research.
Lens-specific aquaporin-0 (AQP0) functions as a specific water pore and forms the thin junctions between fibre cells. We describe a 1.9 Å resolution structure of junctional AQP0, determined by electron crystallography of double-layered two-dimensional crystals. Comparison of junctional and non-junctional AQP0 structures shows that junction formation depends on a conformational switch in an extracellular loop, which may result from cleavage of the cytoplasmic N-and C-termini. In the centre of the water pathway, the closed pore in junctional AQP0 retains only three water molecules, which are too widely spaced to form hydrogen bonds with each other. Packing interactions between AQP0 tetramers in the crystalline array are mediated by lipid molecules, which assume preferred conformations. We could therefore build an atomic model for the lipid bilayer surrounding the AQP0 tetramers, and we describe lipid-protein interactions. KeywordsAquaporin-0; lens; MIP; two-dimensional crystal; lipid-protein interaction; electron crystallography Members of the aquaporin (AQP) family form membrane pores that are either highly selective for water (aquaporins) or also permeable to other small neutral solutes such as glycerol and urea (aquaglyceroporins) (reviewed in 1 ). Structural studies have revealed that all AQPs share the same basic architecture, which consists of two tandem repeats, each containing a bundle of three transmembrane α-helices and a hydrophobic loop with the highly conserved asparagine-proline-alanine (NPA) motif 2 -8 . The two NPA-containing loops B and E fold back into the membrane and form short α-helices (HB and HE) that line the water pore. The ar/R constriction site, so named because it is formed by an aromatic and an arginine residue, confers water selectivity to AQP pores, while the NPA motifs play an important role in the proton exclusion mechanism (reviewed in 9 ).Correspondence to: Thomas Walz.Correspondence and requests for materials should be addressed to T.W. (twalz@hms.harvard.edu). Coordinates and structure factors for junctional and non-junctional AQP0 have been deposited in the Protein Data Bank (accession codes 2B6O and 2B6P, respectively).. Suplementary Information accompanies the paper on www.nature.com/nature. Competing interests statementThe authors declare that they have no competing financial interests. AQP0 is the most abundant protein in lens fibre cell membranes, where it forms not only water pores but also the 11-13 nm "thin lens junctions" that assemble upon proteolytic cleavage of the cytoplasmic termini 10 , 11 . We recently presented the structure of the AQP0-mediated membrane junction at 3 Å resolution as determined by electron crystallography of doublelayered two-dimensional (2D) crystals 7 . The structure showed that AQP0 junctions are stabilised by specific interactions between tetramers in adjoining membranes involving almost exclusively proline residues. Calculated pore profiles also showed that the pore in junctional AQP0 is highly constricted due to a substantially ...
The water permeability of biological membranes has been a longstanding problem in physiology, but the proteins responsible for this remained unknown until discovery of the aquaporin 1 (AQP1) water channel protein. AQP1 is selectively permeated by water driven by osmotic gradients. The atomic structure of human AQP1 has recently been defined. Each subunit of the tetramer contains an individual aqueous pore that permits single-file passage of water molecules but interrupts the hydrogen bonding needed for passage of protons. At least 10 mammalian aquaporins have been identified, and these are selectively permeated by water (aquaporins) or water plus glycerol (aquaglyceroporins). The sites of expression coincide closely with the clinical phenotypes -ranging from congenital cataracts to nephrogenic diabetes insipidus. More than 200 members of the aquaporin family have been found in plants, microbials, invertebrates and vertebrates, and their importance to the physiology of these organisms is being uncovered.
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