Copper-induced conformational changes in the N-terminal domain of the Wilson disease copper-transporting ATPase

The Wilson disease copper-transporting ATPase plays a critical role in the intracellular trafficking of copper. Mutations in this protein lead to the accumulation of a toxic level of copper in the liver, kidney, and brain followed by extensive tissue damage and death. The ATPase has a novel amino-terminal domain ( approximately 70 kDa) which contains six repeats of the copper binding motif GMTCXXC. We have expressed and characterized this domain with respect to the copper binding sites and the conformational consequences of copper binding. A detailed analysis of this domain by X-ray absorption spectroscopy (XAS) has revealed that each binding site ligates copper in the +1 oxidation state using two cysteine side chains with distorted linear geometry. Analysis of copper-induced conformational changes in the amino-terminal domain indicates that both secondary and tertiary structure changes take place upon copper binding. These copper-induced conformational changes could play an important role in the function and regulation of the ATPase in vivo. In addition to providing important insights on copper binding to the protein, these results suggest a possible mechanism of copper trafficking by the Wilson disease ATPase.     

Co-chaperone regulation of conformational switching in the Hsp90 ATPase cycle

ATP hydrolysis by the Hsp90 molecular chaperone requires a connected set of conformational switches triggered by ATP binding to the N-terminal domain in the Hsp90 dimer. Central to this is a segment of the structure, which closes like a "lid" over bound ATP, promoting N-terminal dimerization and assembly of a competent active site. Hsp90 mutants that influence these conformational switches have strong effects on ATPase activity. ATPase activity is specifically regulated by Hsp90 co-chaperones, which directly influence the conformational switches. Here we have analyzed the effect of Hsp90 mutations on binding (using isothermal titration calorimetry and difference circular dichroism) and ATPase regulation by the co-chaperones Aha1, Sti1 (Hop), and Sba1 (p23). The ability of Sti1 to bind Hsp90 and arrest its ATPase activity was not affected by any of the mutants screened. Sba1 bound in the presence of AMPPNP to wild-type and ATPase hyperactive mutants with similar affinity but only very weakly to hypoactive mutants despite their wild-type ATP affinity. Unexpectedly, in all cases Sba1 bound to Hsp90 with a 1:2 molar stoichiometry. Aha1 binding to mutants was similar to wild-type, but the -fold activation of their ATPase varied substantially between mutants. Analysis of complex formation with co-chaperone mixtures showed Aha1 and p50cdc37 able to bind Hsp90 simultaneously but without direct interaction. Sba1 and p50cdc37 bound independently to Hsp90-AMPPNP but not together. These data indicated that Sba1 and Aha1 regulate Hsp90 by influencing the conformational state of the "ATP lid" and consequent N-terminal dimerization, whereas Sti1 does not.     

Identification of the "missing domain" of the rat copper-transporting ATPase, atp7b: insight into the structural and metal binding characteristics of its N-terminal copper-binding domain

Wilson disease is an autosomal disorder of copper transport caused by mutations in the ATP7B gene encoding a copper-transporting P-type ATPase. The Long Evans Cinnamon (LEC) rat is an established animal model for Wilson disease. We have used structural homology modelling of the N-terminal copper-binding region of the rat atp7b protein (rCBD) to reveal the presence of a domain, the fourth domain (rD4), which was previously thought to be missing from rCBD. Although the CXXC motif is absent from rD4, the overall fold is preserved. Using a wide range of techniques, rCBD is shown to undergo metal-induced secondary and tertiary structural changes similar to WCBD. Competition 65Zn(II)-blot experiments with rCBD demonstrate a binding cooperativity unique to Cu(I). Far-UV circular dichroism (CD) spectra suggest significant secondary structural transformation occurring when 2-3 molar equivalents of Cu(I) is added. Near-UV CD spectra, which indicate tertiary structural transformations, show a proportional decrease in rCBD disulfide bonds upon the incremental addition of Cu(I), and a maximum 5:1 Cu(I) to protein ratio. The similarity of these results to those obtained for the Wilson disease N-terminal copper-binding region (WCBD), which has six copper-binding domains, suggests that the metal-dependent conformational changes observed in both proteins may be largely determined by the protein-protein interactions taking place between the heavy metal-associated (HMA) domains, and remain largely unaffected by the absence of one of the six CXXC copper-binding sites.     

ATPase domain of eukaryotic DNA topoisomerase II. Inhibition of ATPase activity by the anti-cancer drug bisdioxopiperazine and ATP/ADP-induced dimerization

We have prepared full-length Drosophila and human topoisomerase II and truncation constructs containing the amino-terminal ATPase domain, and we have analyzed their biochemical properties. The ATPase activity of the truncation proteins, similar to that of the full-length proteins, is greatly stimulated by the presence of DNA. This activity of the truncation proteins is also sensitive to the inhibition by the drug bisdioxopiperazine, ICRF-193, albeit at a much lower level than the full-length protein. Therefore, bisdioxopiperazine can directly interact with the NH(2)-terminal ATPase domain, but the drug-enzyme interaction may involve other domains as well. The ATPase activity of the ATPase domain protein showed a quadratic dependence on enzyme concentration, suggesting that dimerization of the NH(2)-terminal domain is a rate-limiting step. Using both protein cross-linking and sedimentation equilibrium analysis, we showed that the ATPase domain exists as a monomer in the absence of cofactors but can readily dimerize in the presence of a nonhydrolyzable analog of ATP, 5'-adenylyl-beta,gamma-imidodiphosphate. More interestingly, both ATP and ADP can also promote protein dimerization. This result thus suggests that the protein clamp, mediated through the dimerization of ATPase domain, remains closed after ATP hydrolysis and opens upon the dissociation of ADP.     

Limited tryptic digestion of Acanthamoeba myosin IA abolishes regulation of actin-activated ATPase activity by heavy chain phosphorylation

Acanthamoeba myosin IA is a globular protein composed of a 140-kDa heavy chain and a 17-kDa light chain. It expresses high actin-activated Mg2+-ATPase activity when one serine on the heavy chain is phosphorylated. We previously showed that chymotrypsin cleaves the heavy chain into a COOH-terminal 27-kDa peptide that can bind to F-actin but has no ATPase activity and a complex containing the NH2-terminal 112-kDa peptide and the light chain. The complex also binds F-actin and has full actin-activated Mg2+-ATPase activity when the regulatory site is phosphorylated. We have now localized the ATP binding site to within 27 kDa of the NH2 terminus and the regulatory phosphorylatable serine to a 20-kDa region between 38 and 58 kDa of the NH2 terminus. Under controlled conditions, trypsin cleaves the heavy chain at two sites, 38 and 112 kDa from the NH2 terminus, producing a COOH-terminal 27-kDa peptide similar to that produced by chymotrypsin and a complex consisting of an NH2-terminal kDa peptide, a central 74-kDa peptide, and the light chain. This complex is similar to the chymotryptic complex but for the cleavage which separates the 38- and 74-kDa peptides. The tryptic complex has full (K+, EDTA)-ATPase activity (the catalytic site is functional) and normal ATP-sensitive actin-binding properties. However, the actin-activated Mg2+-ATPase activity and the F-actin-binding characteristics of the tryptic complex are no longer sensitive to phosphorylation of the regulatory serine. Therefore, cleavage between the phosphorylation site and the ATP-binding site inhibits the effects of phosphorylation on actin binding and actin-activated Mg2+-ATPase activity without abolishing the interactions between the ATP- and actin-binding sites.     

Functional studies on the candidate ATPase domains of Saccharomyces cerevisiae MutLalpha

Saccharomyces cerevisiae MutL homologues Mlh1p and Pms1p form a heterodimer, termed MutLalpha, that is required for DNA mismatch repair after mismatch binding by MutS homologues. Recent sequence and structural studies have placed the NH(2) termini of MutL homologues in a new family of ATPases. To address the functional significance of this putative ATPase activity in MutLalpha, we mutated conserved motifs for ATP hydrolysis and ATP binding in both Mlh1p and Pms1p and found that these changes disrupted DNA mismatch repair in vivo. Limited proteolysis with purified recombinant MutLalpha demonstrated that the NH(2) terminus of MutLalpha undergoes conformational changes in the presence of ATP and nonhydrolyzable ATP analogs. Furthermore, two-hybrid analysis suggested that these ATP-binding-induced conformational changes promote an interaction between the NH(2) termini of Mlh1p and Pms1p. Surprisingly, analysis of specific mutants suggested differential requirements for the ATPase motifs of Mlh1p and Pms1p during DNA mismatch repair. Taken together, these results suggest that MutLalpha undergoes ATP-dependent conformational changes that may serve to coordinate downstream events during yeast DNA mismatch repair.     

Modulation of troponin T molecular conformation and flexibility by metal ion binding to the NH2-terminal variable region

Troponin T (TnT) plays an allosteric signal transduction role in the actin thin-filament-based Ca(2+)-regulation of striated muscle contraction. Developmentally regulated alternative RNA splicing produces TnT isoforms differing in their NH(2)-terminal structure. Physical property variations of the NH(2)-terminal hypervariable region of TnT may have a role in tuning the Ca(2+)-sensitivity and overall cooperativity of the muscle. We have previously demonstrated that metal ion or monoclonal antibody binding to the NH(2)-terminal region can modulate the epitopic conformation and troponin I and tropomyosin binding affinity of TnT. To further establish the molecular basis of this conformational and functional modulation, we have characterized the NH(2)-terminal variable region-originated secondary conformational effect in TnT using fluorescence spectral analysis. The chicken fast skeletal muscle TnT isoform, TnT8e16, containing a cluster of transition-metal ion binding sites (Tx) in the NH(2)-terminal variable region was used in this study. TnT8e16 was titrated for Cu(II) binding-induced changes in fluorescence intensity and anisotropy of the COOH-domain Trp residues (W234, W236, and W285), which demonstrated considerable environmental sensitivity in TnT denaturation studies. Nonlinear Stern-Volmer plots of Trp quenching indicated a metal ion binding-induced conformational change in TnT. Fluorescence anisotropy changes upon metal ion binding indicated a decrease in the mobility of the Trp residues and an increase in the flexibility of fluorescein-labeled Cys263 in the COOH domain. These data support a model that the alternatively spliced NH(2)-terminal variable region of TnT modulates conformation and flexibility of other domains of the protein.     

Copper transport and its defect in Wilson disease: characterization of the copper-binding domain of Wilson disease ATPase

Copper is an essential trace element which forms an integral component of many enzymes. While trace amounts of copper are needed to sustain life, excess copper is extremely toxic. An attempt is made here to present the current understanding of the normal transport of copper in relation to the absorption, intracellular transport and toxicity. Wilson disease is a genetic disorder of copper transport resulting in the accumulation of copper in organs such as liver and brain which leads to progressive hepatic and neurological damage. The gene responsible for Wilson disease (ATP7B) is predicted to encode a putative copper-transporting P-type ATPase. An important feature of this ATPase is the presence of a large N-terminal domain that contains six repeats of a copper-binding motif which is thought to be responsible for binding this metal prior to its transport across the membrane. We have cloned, expressed and purified the N-terminal domain (approximately 70 kD) of Wilson disease ATPase. Metal-binding properties of the domain showed the protein to bind several metals besides copper; however, copper has a higher affinity for the domain. The copper is bound to the domain in Cu(I) form with a copper: protein ratio of 6.5:1. X-ray absorption studies strongly suggest Cu(I) atoms are ligated to cysteine residues. Circular dichroism spectral analyses suggest both secondary and tertiary structural changes upon copper binding to the domain. Copper-binding studies suggest some degree of cooperativity in binding of copper. These studies as well as detailed structural information of the copper-binding domain will be crucial in determining the specific role played by the copper-transporting ATPase in the homeostatic control of copper in the body and how the transport of copper is interrupted by mutations in the ATPase gene.     

Defining a pathway of communication from the C-terminal peptide binding domain to the N-terminal ATPase domain in a AAA protein

AAA proteins remodel other proteins to affect a multitude of biological processes. Their power to remodel substrates must lie in their capacity to couple substrate binding to conformational changes via cycles of nucleotide binding and hydrolysis, but these relationships have not yet been deciphered for any member. We report that when one AAA protein, Hsp104, engages polypeptide at the C-terminal peptide-binding region, the ATPase cycle of the C-terminal nucleotide-binding domain (NBD2) drives a conformational change in the middle region. This, in turn, drives ATP hydrolysis in the N-terminal ATPase domain (NBD1). This interdomain communication pathway can be blocked by mutation in the middle region or bypassed by antibodies that bind there, demonstrating the crucial role this region plays in transducing signals from one end of the molecule to the other.     

Troponin T core structure and the regulatory NH2-terminal variable region

The conserved central and COOH-terminal regions of troponin T (TnT) interact with troponin C, troponin I, and tropomyosin to regulate striated muscle contraction. Phylogenic data show that the NH2-terminal region has evolved as an addition to the conserved core structure of TnT. This NH2-terminal region does not bind other thin filament proteins, and its sequence is hypervariable between fiber type and developmental isoforms. Previous studies have demonstrated that NH2-terminal modifications alter the COOH-terminal conformation of TnT and thin filament Ca2+-activation, yet the functional core structure of TnT and the mechanism of NH2-terminal modulation are not well understood. To define the TnT core structure and investigate the regulatory role of the NH2-terminal variable region, we investigated two classes of model TnT molecules: (1) NH2-terminal truncated cardiac TnT and (2) chimera proteins consisting of an acidic or basic skeletal muscle TnT NH2-terminus spliced to the cardiac TnT core. Deletion of the TnT hypervariable NH2-terminus preserved binding to troponin I and tropomyosin and sustained cardiac muscle contraction in the heart of transgenic mice. Further deletion of the conserved central region diminished binding to tropomyosin. The reintroduction of differently charged NH2-terminal domains in the chimeric molecules produced long-range conformational changes in the central and COOH-terminal regions to alter troponin I and tropomyosin binding. Similar NH2-terminal charge effects are demonstrated in naturally occurring cardiac TnT isoforms, indicating a physiological significance. These results suggest that the hypervariable NH2-terminal region modulates the conformation and function of the TnT core structure to fine-tune muscle contractility.     

Solution structure of the dimeric zinc binding domain of the chaperone ClpX

ClpX (423 amino acids), a member of the Clp/Hsp100 family of molecular chaperones and the protease, ClpP, comprise a multimeric complex supporting targeted protein degradation in Escherichia coli. The ClpX sequence consists of an NH2-terminal zinc binding domain (ZBD) and a COOH-terminal ATPase domain. Earlier, we have demonstrated that the zinc binding domain forms a constitutive dimer that is essential for the degradation of some ClpX substrates such as gammaO and MuA but is not required for the degradation of other substrates such as green fluorescent protein-SsrA. In this report, we present the NMR solution structure of the zinc binding domain dimer. The monomer fold reveals that ZBD is a member of the treble clef zinc finger family, a motif known to facilitate protein-ligand, protein-DNA, and protein-protein interactions. However, the dimeric ZBD structure is not related to any protein structure in the Protein Data Bank. A trimer-of-dimers model of ZBD is presented, which might reflect the closed state of the ClpX hexamer.     

A yeast Golgi E-type ATPase with an unusual membrane topology.

E-type ATPases are involved in many biological processes such as modulation of neural cell activity, prevention of intravascular thrombosis, and protein glycosylation. In this study, we show that a gene of Saccharomyces cerevisiae, identified by similarity to that of animal ectoapyrase CD39, codes for a new member of the E-type ATPase family (Apy1p). Overexpression of Apy1p in yeast cells causes an increase in intracellular membrane-bound nucleoside di- and triphosphate hydrolase activity. The activity is highest with ADP as substrate and is stimulated similarly by Ca (2+), Mg(2+), and Mn(2+). The results also indicate that Apy1p is an integral membrane protein located predominantly in the Golgi compartment. Sequence analysis reveals that Apy1p contains one large NH(2)-terminal hydrophilic apyrase domain, one COOH-terminal hydrophilic domain, and two hydrophobic stretches in the central region of the polypeptide. Although no signal sequence is found at the NH(2)-terminal portion of the protein and no NH(2)-terminal cleavage of the protein is observed, demonstrated by the detection of NH(2)-terminal tagged Apy1p, the NH(2)-terminal domain of Apylp is on the luminal side of the Golgi apparatus, and the COOH-terminal hydrophilic domain binds to the cytoplasmic face of the Golgi membrane. The second hydrophobic stretch of Apy1p is the transmembrane domain. These results indicate that Apylp is a type III transmembrane protein; however, the size of the Apy1p extracytoplasmic NH(2) terminus is much larger than those of other type III transmembrane proteins, suggesting that a novel translocation mechanism is utilized.     

Protein structural requirements for Ca2+ binding to the light chain of factor X. Studies using isolated intact fragments containing the gamma-carboxyglutamic acid region and/or the epidermal growth factor-like domains

Coagulation factor X is a multidomain proenzyme of a serine protease. Calcium ions bind to the vitamin K-dependent gamma-carboxyglutamic acid (Gla) residues and to a site in the NH2-terminal of two epidermal growth factor (EGF)-like domains. To study structure-function relationships in the NH2-terminal part of factor X and to determine the structure of isolated domains, we have developed methods that allow the subsequent isolation of the first or both EGF-like domains with or without an attached Gla domain from controlled proteolytic digests of the protein. The Ca2(+)-induced changes of the intrinsic protein fluorescence were measured to elucidate whether the isolated fragments retain their native conformation. Changes in the fluorescence caused by Ca2+ binding were found to result from perturbations of the environment of the Trp residue in position 41. Calcium ion binding to the Gla-containing region linked to the NH2-terminal EGF-like domain was identical with that to intact factor X, indicating a native orientation of the ligand binding groups in the fragment. In contrast, the isolated Gla peptide had a lower affinity for Ca2+, suggesting that the NH2-terminal EGF-like domain serves as a scaffold for the folding of the Gla region. Similarly, the presence of the Gla region was found to increase the affinity of the Gla-independent site in the first EGF-like domain for Ca2+. The metal ion-induced resistance against chymotryptic cleavage COOH-terminal of Tyr-44 in intact factor X is similar in the isolated fragment that contains the Gla region linked to one EGF-like domain, indicating a native conformation of the fragment in the presence of Ca2+. Furthermore, the Gla-independent metal ion binding site binds Ca2+ but does not appear to bind Mg2+.     

Structural requirements for Ca2+ binding to the gamma-carboxyglutamic acid and epidermal growth factor-like regions of factor IX. Studies using intact domains isolated from controlled proteolytic digests of bovine factor IX

Blood coagulation factor IX is composed of discrete domains with an NH2-terminal vitamin K-dependent gamma-carboxyglutamic acid (Gla)-containing region, followed by two domains that are homologous with the epidermal growth factor (EGF) precursor and a COOH-terminal serine protease part. Calcium ions bind to the Gla-containing region and to the NH2-terminal EGF-like domain. To be able to determine the structure and function of the Gla- and EGF-like domains, we have devised a method for cleaving factor IX under controlled conditions and isolating the intact domains in high yield, either separately or linked together. The Ca2+ and Mg2+ binding properties of these fragments were examined by monitoring the metal ion-induced changes in intrinsic protein fluorescence. A fragment, consisting of the Gla region linked to the two EGF-like domains, bound Ca2+ in a manner that was indistinguishable from that of the intact molecule, indicating a native conformation. The Ca2+ affinity of the isolated Gla region was lower, suggesting that the EGF-like domains function as a scaffold for the folding of the Gla region. The Gla-independent high affinity metal ion binding site in the NH2-terminal EGF-like domain was shown to bind Ca2+ but not Mg2+. A comparison with similar studies of factor X (Persson, E., Bj?rk, I., and Stenflo, J. (1991) J. Biol. Chem. 266, 2444-2452) suggests that the Ca2(+)-induced fluorescence quenching is due to an altered environment primarily around the tryptophan residue in position 42.     

The upper cytokine-binding module and the Ig-like domain of the leukaemia inhibitory factor (LIF) receptor are sufficient for a functional LIF receptor complex.

To elucidate the function of the two cytokine-binding modules (CBM) of the leukemia inhibitory factor receptor (LIFR), receptor chimeras of LIFR and the interleukin-6 receptor (IL-6R) were constructed. Either the NH(2)-terminal (chimera RILLIFdeltaI) or the COOH-terminal LIFR CBM (chimera RILLIFdeltaII) were replaced by the structurally related CBM of the IL-6R which does not bind LIF. Chimera RILLIFdeltaI is functionally inactive, whereas RILLIFdeltaII binds LIF and mediates signalling as efficiently as the wild-type LIFR. Deletion mutants of the LIFR revealed that both the NH(2)-terminal CBM and the Ig-like domain of the LIFR are involved in LIF binding, presumably via the LIF site III epitope. The main function of the COOH-terminal CBM of the LIFR is to position the NH(2)-terminal CBM and the Ig-like domain, so that these can bind to LIF. In analogy to a recently published model of the IL-6R complex, a model of the active LIFR complex is suggested which positions the COOH-terminal CBM at LIF site I and the NH(2)-terminal CBM and the Ig-like domain at site III. An additional contact is postulated between the Ig-like domain of gp130 and the NH(2)-terminal CBM of the LIFR.     

Activation of human plasminogen by equimolar levels of streptokinase.

Native Glu-human plasminogen (Mr approximately 92,000 with NH2-terminal glutamic acid) is able to combine directly with streptokinase in an equivalent molar ratio, to yield a stoichiometric complex. The plasminogen moiety in the complex then undergoes streptokinase-induced conformational changes. As a result of such, an active center develops in the plasminogen moiety of the complex. This proteolytically active complex then activates plasminogen in the complex to plasmin and at least two peptide bonds are cleaved in the process. The data presented in this paper reveal that initially an internal peptide bond of plasminogen (in the complex) is cleaved to yield a two-chain, disulfide-linked plasmin molecule. The heavy chain (Mr approximately 67,000 with NH2-terminal glutamic acid) of this plasmin molecule has an identical NH2-terminal amico acid as the native plasminogen. The light chain (Mr approximately 25,000 with NH2-terminal valine) of plasmin is known to be derived from the COOH-terminal portion of the parent plasminogen molecule. A second peptide is then cleaved from the NH2-terminal end of the heavy chain of plasmin producing a proteolytically modified heavy chain (Mr =60.000 with NH2-terminal lysine). This cleavage of the NH2-terminal peptide from the heavy chain of plasmin is shown to be mediated by the dissociated free plasmin present in the activation mixture. Plasmin in the streptokinase-plasmin complex is unable to cleave this NH2-terminal peptide. This same NH2-terminal peptide can also be cleaved from native Glu-plasminogen or from the Glu-plasminogen-streptokinase complex by free plasmin and not by a complex of streptokinase-plasmin. From these studies we conclude (a) in the streptokinase-plasminogen complex, the NH2-terminal peptide need not be released prior to the cleavage of the essential Arg-Val peptide bond which leads to the formation of a two chain plasmin molecule and (b) that this peptide is cleaved from the native plasminogen or from the heavy chain of the initially formed plasmin in the streptokinase complex by free plasmin and not by the plasmin associated with streptokinase. In agreement with this, plasmin associated with streptokinase was unable to cleave the NH2-terminal peptide from the isolated native heavy chain possessing glutamic acid as the NH2-terminal amino acid; whereas free plasmin readily cleaved this peptide from the same isolated Glu-heavy chain.     

Functional characterization of the 180-kD ribosome receptor in vivo

A cDNA encoding the 180-kD canine ribosome receptor (RRp) was cloned and sequenced. The deduced primary structure indicates three distinct domains: an NH2-terminal stretch of 28 uncharged amino acids representing the membrane anchor, a basic region (pI = 10.74) comprising the remainder of the NH2-terminal half and an acidic COOH- terminal half (pI = 4.99). The most striking feature of the amino acid sequence is a 10-amino acid consensus motif, NQGKKAEGAP, repeated 54 times in tandem without interruption in the NH2-terminal positively charged region. We postulate that this repeated sequence represents a ribosome binding domain which mediates the interaction between the ribosome and the ER membrane. To substantiate this hypothesis, recombinant full-length ribosome receptor and two truncated versions of this protein, one lacking the potential ribosome binding domain, and one lacking the COOH terminus, were expressed in Saccharomyces cerevisiae. Morphological and biochemical analyses showed all proteins were targeted to, and oriented correctly in the ER membrane. In vitro ribosome binding assays demonstrated that yeast microsomes containing the full-length canine receptor or one lacking the COOH-terminal domain were able to bind two to four times as many human ribosomes as control membranes lacking a recombinant protein or microsomes containing a receptor lacking the NH2-terminal basic domain. Electron micrographs of these cells revealed that the expression of all receptor constructs led to a proliferation of perinuclear ER membranes known as "karmellae." Strikingly, in those strains which expressed cDNAs encoding a receptor containing the putative ribosome binding domain, the induced ER membranes (examined in situ) were richly studded with ribosomes. In contrast, karmellae resulting from the expression of receptor cDNA lacking the putative ribosome binding domain were uniformly smooth and free of ribosomes. Cell fractionation and biochemical analyses corroborated the morphological characterization. Taken together these data provide further evidence that RRp functions as a ribosome receptor in vitro, provide new evidence indicating its functionality in vivo, and in both cases indicate that the NH2-terminal basic domain is essential for ribosome binding.     

Domain structure of the HSC70 cochaperone, HIP.

The domain structure of the HSC70-interacting protein (HIP), a 43-kDa cytoplasmic cochaperone involved in the regulation of HSC70 chaperone activity and the maturation of progesterone receptor, has been probed by limited proteolysis and biophysical and biochemical approaches. HIP proteolysis by thrombin and chymotrypsin generates essentially two fragments, an NH2-terminal fragment of 25 kDa (N25) and a COOH-terminal fragment of 18 kDa (C18) that appear to be well folded and stable as indicated by circular dichroism and recombinant expression in Escherichia coli. NH2-terminal amino acid sequencing of the respective fragments indicates that both proteases cleave HIP within a predicted alpha-helix following the tetratricopeptide repeat (TPR) region, despite their different specificities and the presence of several potential cleavage sites scattered throughout the sequence, thus suggesting that this region is particularly accessible and may constitute a linker between two structural domains. After size exclusion chromatography, N25 and C18 elute as two distinct and homogeneous species having a Stokes radius of 49 and 24 A, respectively. Equilibrium sedimentation and sedimentation velocity indicate that N25 is a stable dimer, whereas C18 is monomeric in solution, with sedimentation coefficients of 3.2 and 2.3 S and f/f(o) values of 1.5 and 1.1 for N25 and C18, respectively, indicating that the N25 is elongated whereas C18 is globular in shape. Both domains are able to bind to the ATPase domain of HSC70 and inhibit rhodanese aggregation. Moreover, their effects appear to be additive when used in combination, suggesting a cooperation of these domains in the full-length protein not only for HSC70 binding but also for chaperone activity. Altogether, these results indicate that HIP is made of two structural and functional domains, an NH2-terminal 25-kDa domain, responsible for the dimerization and the overall asymmetry of the molecule, and a COOH-terminal 18-kDa globular domain, both involved in HSC70 and unfolded protein binding.     

The regulation of catalytic activity of the menkes copper-translocating P-type ATPase. Role of high affinity copper-binding sites

The Menkes protein is a transmembrane copper translocating P-type ATPase. Mutations in the Menkes gene that affect the function of the Menkes protein may cause Menkes disease in humans, which is associated with severe systemic copper deficiency. The catalytic mechanism of the Menkes protein, including the formation of transient acylphosphate, is poorly understood. We transfected and overexpressed wild-type and targeted mutant Menkes protein in yeast and investigated its transient acyl phosphorylation. We demonstrated that the Menkes protein is transiently phosphorylated by ATP in a copper-specific and copper-dependent manner and appears to undergo conformational changes in accordance with the classical P-type ATPase model. Our data suggest that the catalytic cycle of the Menkes protein begins with the binding of copper to high affinity binding sites in the transmembrane channel, followed by ATP binding and transient phosphorylation. We propose that putative copper-binding sites at the N-terminal domain of the Menkes protein are important as sensors of low concentrations of copper but are not essential for the overall catalytic activity.     

Inter-domain motions of the N-domain of the KdpFABC complex, a P-type ATPase, are not driven by ATP-induced conformational changes

P-type ATPases are involved in the active transport of ions across biological membranes. The KdpFABC complex (P-type ATPase) of Escherichia coli is a high-affinity K+ uptake system that operates only when the cell experiences osmotic stress or K+ limitation. Here, we present the solution structure of the nucleotide binding domain of KdpB (backbone RMSD 0.17 A) and a model of the AMP-PNP binding mode based on intermolecular distance restraints. The calculated AMP-PNP binding mode shows the purine ring of the nucleotide to be "clipped" into the binding pocket via a pi-pi-interaction to F377 on one side and a cation-pi-interaction to K395 on the other. This binding mechanism seems to be conserved in all P-type ATPases, except the heavy metal transporting ATPases (type IB). Thus, we conclude that the Kdp-ATPase (currently type IA) is misgrouped and has more similarities to type III ATPases. The KdpB N-domain is the smallest and simplest known for a P-type ATPase, and represents a minimal example of this functional unit. No evidence of significant conformational changes was observed within the N-domain upon nucleotide binding, thus ruling out a role for ATP-induced conformational changes in the reaction cycle.