Oleg Y. Dmitriev scite author profile

Copper-transporting ATPases (Cu-ATPases) ATP7A and ATP7B are evolutionarily conserved polytopic membrane proteins with essential roles in human physiology. The Cu-ATPases are expressed in most tissues, and their transport activity is crucial for central nervous system development, liver function, connective tissue formation, and many other physiological processes. The loss of ATP7A or ATP7B function is associated with severe metabolic disorders, Menkes disease, and Wilson disease. In cells, the Cu-ATPases maintain intracellular copper concentration by transporting copper from the cytosol across cellular membranes. They also contribute to protein biosynthesis by delivering copper into the lumen of the secretory pathway where metal ion is incorporated into copper-dependent enzymes. The biosynthetic and homeostatic functions of Cu-ATPases are performed in different cell compartments; targeting to these compartments and the functional activity of Cu-ATPase are both regulated by copper. In recent years, significant progress has been made in understanding the structure, function, and regulation of these essential transporters. These studies raised many new questions related to specific physiological roles of Cu-ATPases in various tissues and complex mechanisms that control the Cu-ATPase function. This review summarizes current data on the structural organization and functional properties of ATP7A and ATP7B as well as their localization and functions in various tissues, and discusses the current models of regulated trafficking of human Cu-ATPases.

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Solution structure of the N-domain of Wilson disease protein: Distinct nucleotide-binding environment and effects of disease mutations

Dmitriev

Tsivkovskii

Abildgaard³

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

110

159

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Wilson disease protein (ATP7B) is a copper-transporting P1B-type ATPase that regulates copper homeostasis and biosynthesis of copper-containing enzymes in human tissues. Inactivation of ATP7B or related ATP7A leads to severe neurodegenerative disorders, whereas their overexpression contributes to cancer cell resistance to chemotherapeutics. Copper-transporting ATPases differ from other P-type ATPases in their topology and the sequence of their nucleotide-binding domain (N-domain). To gain insight into the structural basis of ATP7B function, we have solved the structure of the ATP7B N-domain in the presence of ATP by using heteronuclear multidimensional NMR spectroscopy. The N-domain consists of a six-stranded ␤-sheet with two adjacent ␣-helical hairpins and, unexpectedly, shows higher similarity to the bacterial K ؉ -transporting ATPase KdpB than to the mammalian Ca 2؉ -ATPase or Na ؉ ,K ؉ -ATPase. The common core structure of P-type ATPases is retained in the 3D fold of the N-domain; however, the nucleotide coordination environment of ATP7B within this fold is different. The residues H1069, G1099, G1101, I1102, G1149, and N1150 conserved in the P1B-ATPase subfamily contribute to ATP binding. Analysis of the frequent disease mutation H1069Q demonstrates that this mutation does not significantly affect the structure of the N-domain but prevents tight binding of ATP. The structure of the N-domain accounts for the disruptive effects of >30 known Wilson disease mutations. The unique features of the N-domain provide a structural basis for the development of specific inhibitors and regulators of ATP7B.

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Structure of the Membrane Domain of Subunit b of theEscherichia coli F0F1 ATP Synthase

Dmitriev

Jones

Jiang

et al. 1999

Journal of Biological Chemistry

136

127

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Mechanics of coupling proton movements to c‐ring rotation in ATP synthase

2003

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F 1 F 0 ATP synthases generate ATP by a rotary catalytic mechanism in which H + transport is coupled to rotation of an oligomeric ring of c subunits extending through the membrane. Protons bind to and then are released from the aspartyl-61 residue of subunit c at the center of the membrane. Subunit a of the F 0 sector is thought to provide proton access channels to and from aspartyl-61. Here, we summarize new information on the structural organization of Escherichia coli subunit a and the mapping of aqueous-accessible residues in the second, fourth and ¢fth transmembrane helices (TMHs). Aqueous-accessible regions of these helices extend to both the cytoplasmic and periplasmic surface. We propose that aTMH4 rotates to alternately expose the periplasmic or cytoplasmic half-channels to aspartyl-61 of subunit c during the proton transport cycle. The concerted rotation of interacting helices in subunit a and subunit c is proposed to be the mechanical force driving rotation of the c-rotor, using a mechanism akin to meshed gears.

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Structure of the subunit c oligomer in the F ₁ F _o ATP synthase: Model derived from solution structure of the monomer and cross-linking in the native enzyme

Dmitriev

Jones

Fillingame

1999

Proc. Natl. Acad. Sci. U.S.A.

110

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The structure of the subunit c oligomer of the H ؉ -transporting ATP synthase of Escherichia coli has been modeled by molecular dynamics and energy minimization calculations from the solution structure of monomeric subunit c and 21 intersubunit distance constraints derived from cross-linking of subunits. Subunit c folds in a hairpin-like structure with two transmembrane helices. In the c 12 oligomer model, the subunits pack to form a compact hollow cylinder with an outer diameter of 55-60 Å and an inner space with a minimal diameter of 11-12 Å. Phospholipids are presumed to pack in the inner space in the native membrane. The transmembrane helices pack in two concentric rings with helix 1 inside and helix 2 outside. The calculations strongly favor this structure versus a model with helix 2 inside and helix 1 outside. Asp-61, the H ؉ -transporting residue, packs toward the center of the four transmembrane helices of two interacting subunits. From this position at the front face of one subunit, the Asp-61 carboxylate lies proximal to side chains of Ala-24, Ile-28, and Ala-62, projecting from the back face of a second subunit. These interactions were predicted from previous mutational analyses. The packing supports the suggestion that a c-c dimer is the functional unit. The positioning of the Asp-61 carboxyl in the center of the interacting transmembrane helices, rather than at the periphery of the cylinder, has important implications regarding possible mechanisms of H ؉ -transport-driven rotation of the c oligomer during ATP synthesis.

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Oleg Y. Dmitriev

Function and Regulation of Human Copper-Transporting ATPases

Solution structure of the N-domain of Wilson disease protein: Distinct nucleotide-binding environment and effects of disease mutations

Structure of the Membrane Domain of Subunit b of theEscherichia coli F0F1 ATP Synthase

Mechanics of coupling proton movements to c‐ring rotation in ATP synthase

Structure of the subunit c oligomer in the F ₁ F _o ATP synthase: Model derived from solution structure of the monomer and cross-linking in the native enzyme

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Oleg Y. Dmitriev

Function and Regulation of Human Copper-Transporting ATPases

Solution structure of the N-domain of Wilson disease protein: Distinct nucleotide-binding environment and effects of disease mutations

Structure of the Membrane Domain of Subunit b of theEscherichia coli F0F1 ATP Synthase

Mechanics of coupling proton movements to c‐ring rotation in ATP synthase

Structure of the subunit c oligomer in the F 1 F o ATP synthase: Model derived from solution structure of the monomer and cross-linking in the native enzyme

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Product

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Structure of the subunit c oligomer in the F ₁ F _o ATP synthase: Model derived from solution structure of the monomer and cross-linking in the native enzyme