CEM15/APOBEC3G is a cellular protein required for resistance to infection by virion infectivity factor (Vif)-deficient human immunodeficiency virus (HIV). Here, using a murine leukemia virus (MLV)-based system, we provide evidence that CEM15/APOBEC3G is a DNA deaminase that is incorporated into virions during viral production and subsequently triggers massive deamination of deoxycytidine to deoxyuridine within the retroviral minus (first)-strand cDNA, thus providing a probable trigger for viral destruction. Furthermore, HIV Vif can protect MLV from this CEM15/APOBEC3G-dependent restriction. These findings imply that targeted DNA deamination is a major strategy of innate immunity to retroviruses and likely also contributes to the sequence variation observed in many viruses (including HIV).
The May 28, 2003 immediate early online version of this article (Cell 113, 803-809, 13 June 2003) contained one sentence that did not appear in the printed version. In the results subsection entitled "CEM15/APOBEC3G Is Incorporated into MLV Virions," a bracketed sentence appeared in the following context: The CEM15/APOBEC3G-mediated suppression of HIV infection is thought to be accomplished by protein transferred as a virion component from virus producing cells into target cells (curiously, such physical transfer of CEM15/ APOBEC3G appears uninhibitable by Vif) (Sheehy et al., 2002). The bracketed text was removed prior to publication of the definitive printed and corresponding online versions of the manuscript. It was our intention that this correction should have occurred in all versions of the article. The authors and Cell Press apologize for any inconvenience that may have been caused.
The catalytic domain of the F-ATPase in mitochondria protrudes into the matrix of the organelle, and is attached to the membrane domain by central and peripheral stalks. Energy for the synthesis of ATP from ADP and phosphate is provided by the transmembrane proton-motive-force across the inner membrane, generated by respiration. The proton-motive force is coupled mechanically to ATP synthesis by the rotation at about 100 times per second of the central stalk and an attached ring of c-subunits in the membrane domain. Each c-subunit carries a glutamate exposed around the midpoint of the membrane on the external surface of the ring. The rotation is generated by protonation and deprotonation successively of each glutamate. Each 360°rotation produces three ATP molecules, and requires the translocation of one proton per glutamate by each c-subunit in the ring. In fungi, eubacteria, and plant chloroplasts, ring sizes of c 10
Mitochondrial ATP synthase is responsible for the synthesis of ATP, a universal energy currency in cells. Whereas X-ray crystallography has revealed the structure of the soluble region of the complex and the membrane-intrinsic c-subunits, little is known about the structure of the six other proteins (a, b, f, A6L, e, and g) that comprise the membrane-bound region of the complex in animal mitochondria. Here, we present the structure of intact bovine mitochondrial ATP synthase at ∼18 Å resolution by electron cryomicroscopy of single particles in amorphous ice. The map reveals that the a-subunit and c 8 -ring of the complex interact with a small contact area and that the b-subunit spans the membrane without contacting the c 8 -ring. The e-and g-subunits extend from the a-subunit density distal to the c 8 -ring. The map was calculated from images of a preparation of the enzyme solubilized with the detergent dodecyl maltoside, which is visible in electron cryomicroscopy maps. The structure shows that the micelle surrounding the complex is curved. The observed bend in the micelle of the detergent-solubilized complex is consistent with previous electron tomography experiments and suggests that monomers of ATP synthase are sufficient to produce curvature in lipid bilayers.A TP synthases are responsible for the synthesis of ATP from ADP and inorganic phosphate. In mammalian mitochondria, the enzyme is an ∼600-kDa membrane protein complex comprised of a catalytic F 1 region and a membrane-bound F O region. The F 1 region consists of subunits α 3 β 3 γδε (1, 2) and the F O region consists of subunits abc 8 defg(A6L)F 6 (3). The F 1 and F O regions are connected by a central stalk, comprised of the γ-, δ-, and ε-subunits from the F 1 region, and a peripheral stalk, comprised of the oligomycin sensitivity conferral protein (OSCP) and subunits b, d, and F 6 from the F O region (4, 5). Previously, electron cryomicroscopy (cryo-EM) of intact detergent-solubilized bovine ATP synthase particles embedded in a thin layer of amorphous ice revealed the overall shape of the complex at 32 Å resolution (6), and subsequent analysis of the Saccharomyces cerevisiae enzyme produced a similar map at 24 Å resolution (7). X-ray crystallography of subcomplexes of the bovine enzyme has defined the arrangement of subunits in the F 1 region (8) and the peripheral stalk (9, 10) and showed the presence of a ring of eight c-subunits in the F O region (11). The structure and arrangement of the remaining subunits in the membrane-bound region of the enzyme are not known.The ATP synthase functions by a rotary catalytic mechanism. Proton translocation through the F O region requires the a-, b-, and c-subunits (12-14) and induces rotation of the membranebound c 8 -ring (15). The structure of the c 8 -ring is thought to be stabilized by binding of cardiolipin to a lysine residue conserved throughout animalia that has been shown to be trimethylated at the ε-amino group in all animal ATP synthases tested (11,16,17). The c 8 -ring is attached to the central st...
The activation-induced deaminase/apolipoprotein B-editing catalytic subunit 1 (AID/APOBEC) family comprises four groups of proteins. Both AID, a lymphoid-specific DNA deaminase that triggers antibody diversification, and APOBEC2 (function unknown) are found in all vertebrates examined. In contrast, APOBEC1, an RNA-editing enzyme in gastrointestinal cells, and APOBEC3 are restricted to mammals. The function of most APOBEC3s, of which there are seven in human but one in mouse, is unknown, although several human APOBEC3s act as host restriction factors that deaminate human immunodeficiency virus type 1 replication intermediates. A more primitive function of APOBEC3s in protecting against the transposition of endogenous retroelements has, however, been proposed. Here, we focus on mouse APOBEC2 (a muscle-specific protein for which we find no evidence of a deaminating activity on cytidine whether as a free nucleotide or in DNA) and mouse APOBEC3 (a DNA deaminase which we find widely expressed but most abundant in lymphoid tissue). Gene-targeting experiments reveal that both APOBEC2 (despite being an ancestral member of the family with no obvious redundancy in muscle) and APOBEC3 (despite its proposed role in restricting endogenous retrotransposition) are inessential for mouse development, survival, or fertility.
Most primates, including humans, are chronically infected with cospecifically evolved, potentially pathogenic CMV. Abs that bind a 10-aa linear epitope (antigenic determinant 2 site 1) within the extracellular domain of human CMV glycoprotein B neutralize viral infectivity. In this study, we show that genes generated by recombinations involving two well-conserved human germline V elements (IGHV3-30 and IGKV3-11), and IGHJ4, encode primary Ig molecules that bind glycoprotein B at this key epitope. These particular VH, JH, and Vκ genes enable humans to generate through recombination and N nucleotide addition, a useful frequency of primary Igs that efficiently target this critical site on human CMV and thus confer an innate foundation for a specific adaptive response to this pathogen.
Electrospray ionization mass spectrometry (ESI-MS) data and molecular modeling calculations were used to gain mechanistic, conformational, and domain-specific information from the acid-induced demetallation reactions of human metallothionein. The recombinant proteins studied were the single α- and β-rhMT-1a domains and the βα- and αβ-rhMT-1a two-domain species, based on the human metallothionein 1a sequence. Complete molecular models (MM3/MD) for all the fully metallated and demetallated species using a modified force field are reported for the first time. Basic residues that contribute to the ESI-MS charge states are identified from the molecular models. Demetallation took place under equilibrium conditions within a narrow pH range. For the two-domain proteins, these results support a demetallation mechanism involving the initial complete demetallation of one domain followed by the other for both βα-rhMT and αβ-rhMT. Based on the stability of the separate domains, the β domain is predicted to demetallate first in the two-domain rhMTs. Both the α domain and the β domain were observed to bind an excess of one Cd2+ ion. The metallated rhMT structures were shown to have very stable conformations, but only when fully metallated. Two or more conformations were observed at low pH in the ESI-MS data, which are interpreted as arising from the presence of structure, as opposed to a random coil, in the apo-rhMT. This is the first report of the existence of a structure in the two-domain metal-free apo-MT proteins. Only at extremely low pH does the structure open fully to give the highest charge distribution, which is associated with a random coil. Pre-existing structural features in the apo-MT would explain why the metallation reactions occur so rapidly.Key words: recombinant human metallothionein-1 (rhMT1), electrospray ionization mass spectrometry (ESI-MS), circular dichroism (CD), molecular mechanics/molecular dynamics (MM3/MD).
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