A new ATP-binding fold in actin, hexokinase and Hsc70

Modulation of annexin VI--driven aggregation of phosphatidylserine liposomes by ATP

Annexin (Anx) VI has been implicated in mediating the endosome aggregation and vesicle fusion in secreting epithelia during exocytosis. In addition, AnxVI of porcine liver is an ATP-binding protein, and ATP in vitro modulates its interaction with membranes and cytoskeletal elements (Bandorowicz-Pikuła and Awasthi, FEBS Lett. 409 (1997) 300-306). In this study, we examined the effect of ATP on phosphatidylserine (PtdSer) aggregation in the presence of annexin and on calcium-dependent binding of protein to liposomes, and found that ATP stimulates the former process, although it increases the calcium concentration necessary for half-maximal binding of AnxVI to membranes. These results were corroborated by the experiments with fluorescent analog of ATP, in which binding of ATP to AnxVI was affected by binding of Ca2+ and/or phospholipids to the protein. Taken together they favour an idea of ATP being a functional ligand for AnxVI, which even in the relative absence of Ca2+ may modulate interaction of AnxVI with PtdSer-enriched membranes.

Crystallization of acetate kinase from Methanosarcina thermophila and prediction of its fold

The unique biochemical properties of acetate kinase present a classic conundrum in the study of the mechanism of enzyme-catalyzed phosphoryl transfer. Large, single crystals of acetate kinase from Methanosarcina thermophila were grown from a solution of ammonium sulfate in the presence of ATP. The crystals diffract to beyond 1.7 A resolution. Analysis of X-ray data from the crystals is consistent with a space group of C2 and unit cell dimensions a = 181 A, b = 67 A, c = 83 A, beta = 103 degrees. Diffraction data have been collected from the crystals at 110 and 277 K. Data collected at 277 K extend to lower resolution, but are more reproducible. The orientation of a noncrystallographic two-fold axis of symmetry has been determined. Based on an analysis of the predicted amino acid sequences of acetate kinase from several organisms, we hypothesize that acetate kinase is a member of the sugar kinase/actin/hsp70 structural family.

Interactions between heterologous FtsA and FtsZ proteins at the FtsZ ring

FtsZ and FtsA are essential for cell division in Escherichia coli and colocalize to the septal ring. One approach to determine what regions of FtsA and FtsZ are important for their interaction is to identify in vivo interactions between FtsA and FtsZ from different species. As a first step, the ftsA genes of Rhizobium meliloti and Agrobacterium tumefaciens were isolated and characterized. In addition, an FtsZ homolog that shared the unusual C-terminal extension of R. meliloti FtsZ1 was found in A. tumefaciens. In order to visualize their localization in cells, we tagged these proteins with green fluorescent protein (GFP). When R. meliloti FtsZ1-GFP or A. tumefaciens FtsZ-GFP was expressed at low levels in E. coli, they specifically localized only to the E. coli FtsZ ring, possibly by coassembly. When A. tumefaciens FtsA-GFP or R. meliloti FtsA-GFP was expressed in E. coli, they failed to localize detectably to the E. coli FtsZ ring. However, when R. meliloti FtsZ1 was coexpressed with them, fluorescence localized to a band at the midcell division site, strongly suggesting that FtsA from either A. tumefaciens or R. meliloti can bind directly to its cognate FtsZ. As expected, GFP-tagged FtsZ1 and FtsA from either R. meliloti or A. tumefaciens localized to the division site in A. tumefaciens cells. Therefore, the 61 amino acid changes between A. tumefaciens FtsA and R. meliloti FtsA do not prevent their direct interaction with FtsZ1 from either species, suggesting that those residues are not essential for protein-protein contacts. Moreover, the failure of the two non-E. coli FtsA derivatives to interact strongly with E. coli FtsZ in this in vivo system unless their cognate FtsZ was also present suggests that FtsA-FtsZ interactions have coevolved and that the residues which differ between the E. coli proteins and those of the two other species may be important for specific interactions.

Who's who among the Saccharomyces cerevisiae actin-related proteins? A classification and nomenclature proposal for a large family

Inspection of the complete Saccharomyces cerevisiae genome sequence and analysis of the actin-related proteins (ARPs) found therein revealed seven proteins, in addition to the previously designated actin-related proteins Arp1, Arp2 and Arp3, which contained substantial blocks of conservation relative to a chosen sub-set of actins. We have ordered the new ARPs relative to this group of actins and propose to name the more distantly related ARP members, according to their amino acid identity and similarity, Arp4-Arp10. Most of these proteins appear to represent the first example of new classes of ARPs, each of which may have specific localization(s) and cellular function(s). Recently reported ARPs from other species have also been included in the phylogenetic tree derived from the overall alignment of 29 actins and 28 ARPs.

Partitioning of plasmid R1. The ParM protein exhibits ATPase activity and interacts with the centromere-like ParR-parC complex

The parA system of plasmid R1 consists of two genes, parM and parR, and a cis-acting centromere-like site parC. The ParM protein exhibits similarity with a superfamily of ATPases that includes actin, hsp70 and hexokinase. ParM was purified to near-homogeneity and assayed for in vitro ATPase activity. The wild-type ParM protein was found to posses ATPase activity. Mutant ParM derivatives that exhibited decreased in vitro ATPase activity were non-functional in vivo, indicating that the ATP turnover by ParM is essential for correct plasmid partitioning. The mutant ParM proteins exhibited trans-dominance, suggesting that ParM participates as a structural component of the partitioning apparatus. The ATPase activity of ParM was activated slightly by the presence of ParR and activated to a much greater extent when ParR was bound to the centromere-like parC region. An analysis using the yeast two-hybrid system indicated that ParM and ParR interact, and demonstrated that ParR interacts with itself. Thus our results suggest a direct interaction of ParM and ParR at the natural partition site parC, and that the ATPase activity of ParM is specifically stimulated by this interaction.

Interaction of Hsp70 chaperones with substrates

Determination of the structure of the substrate binding domain of the Escherichia coli Hsp70 chaperone, DnaK, and the biochemical characterisation of the motif it recognizes within substrates provide insights into the principles governing Hsp70 interaction with polypeptide chains. DnaK recognizes extended peptide strands composed of up to five consecutive hydrophobic residues within and positively charged residues outside the substrate binding cavity.

Protein structures sustain evolutionary drift

A protein sequence folds into a unique three-dimensional protein structure. Different sequences, though, can fold into similar structures. How stable is a protein structure with respect to sequence changes? What percentage of the sequence is 'anchor' residues, that is, residues crucial for protein structure and function? Here, answers to these questions are pursued by analyzing large numbers of structurally homologous protein pairs. Most pairs of similar structures have sequence identity as low as expected from randomly related sequences (8-9%). On average, only 3-4% of all residues are 'anchor' residues. The symmetric shape of the distribution at low sequence identity suggests that for most structures, four billion years of evolution was sufficient to reach an equilibrium. The mean identities for convergent (different ancestor) and divergent (same ancestor) evolution of proteins to similar structures are quite close and hence, in most cases, it is difficult to distinguish between the two effects. In particular, low levels of sequence identity appear not to be indicative of convergent evolution.

Kinetics and thermodynamics of phalloidin binding to actin filaments from three divergent species

We compared the kinetics and thermodynamics of rhodamine phalloidin binding to actin purified from rabbit skeletal muscle, Acanthamoeba castellanii, and Saccharomyces cerevisiae in 50 mM KCl, 1 mM MgCl2, and pH 7.0 buffer at 22 degrees C. Filaments of S. cerevisiae actin bind rhodamine phalloidin more weakly than Acanthamoeba and rabbit skeletal muscle actin filaments due to a more rapid dissociation rate in spite of a significantly faster association rate constant. The higher dissociation rate constant and lower binding affinity of rhodamine phalloidin for S. cerevisiae actin filaments provide a quantitative explanation for the inefficient staining of yeast actin filaments, compared with that of rabbit skeletal muscle actin filaments [Kron et al. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 4466-4470]. The temperature dependence of the rate constants was interpreted according to transition state theory. There is a small enthalpic difference (delta H++) between the ground states and the transition state. Consequently, the free energy of activation (delta G++) for association and dissociation of rhodamine phalloidin is dominated by entropic changes (delta S++). At equilibrium, rhodamine phalloidin binding generates a positive entropy change (delta S0). The rates of rhodamine phalloidin binding are independent of the pH, ionic strength, and filament length. Rhodamine covalently bound decreases the association rate and affinity of phalloidin for actin. The association rate constant is low for both phalloidin and rhodamine phalloidin because the filaments must undergo conformational changes (i.e. "breathe") to expose the phalloidin binding site [De La Cruz, E. M., & Pollard, T. D. (1994) Biochemistry 33, 14387-14392]. Raising the solvent microviscosity, but not the macroviscosity, dampens these conformational fluctuations, and phalloidin binding kinetics are inhibited. Yeast actin filaments bind rhodamine phalloidin more rapidly, suggesting that perhaps they are more flexible and can breathe more easily than rabbit or Acanthamoeba actin filaments.

A single amino acid change in Escherichia coli glycerol kinase abolishes glucose control of glycerol utilization in vivo

Escherichia coli glycerol kinase (EC 2.7.1.30; ATP:glycerol 3-phosphotransferase) is a key element in glucose control of glycerol metabolism. Its catalytic activity is inhibited allosterically by the glycolytic intermediate, fructose 1,6-biphosphate, and by the phosphotransferase system phosphocarrier protein, IIIGlc (also known as IIAGlc). These inhibitors provide mechanisms by which glucose blocks glycerol utilization in vivo. We report here the cloning and sequencing of the glpK22 gene isolated from E. C. C. Lin strain 43, a strain that shows the loss of glucose control of glycerol utilization. DNA sequencing shows a single missense mutation that translates to the amino acid change Gly-304 to Ser (G-304-S) in glycerol kinase. The effects of this substitution on the functional and physical properties of the purified mutant enzyme were determined. Neither of the allosteric ligands inhibits it under conditions that produce strong inhibition of the wild-type enzyme, which is sufficient to explain the phenotype of strain 43. However, IIIGlc activates the mutant enzyme, which could not be predicted from the phenotype. In the wild-type enzyme, G-304 is located 1.3 nm from the active site and 2.5 nm from the IIIGlc binding site (M. Feese, D. W. Pettigrew, N. D. Meadow, S. Roseman, and S. J. Remington, Proc. Natl. Acad. Sci. USA 91:3544-3548, 1994). It is located in the same region as amino acid substitutions in the related protein DnaK which alter its catalytic and regulatory properties and which are postulated to interfere with a domain closure motion (A. S. Kamath-Loeb, C. Z. Lu, W.-C. Suh, M. A. Lonetto, and C. A. Gross, J. Biol. Chem. 270:30051-30059, 1995). The global effect of the G-304-S substitution on the conformation and catalytic and regulatory properties of glycerol kinase is consistent with a role for the domain closure motion in the molecular mechanism for glucose control of glycerol utilization.

Nucleotide-induced conformational changes in the ATPase and substrate binding domains of the DnaK chaperone provide evidence for interdomain communication

Interactions of the DnaK (Hsp70) chaperone from Escherichia coli with substrates are controlled by ATP. Nucleotide-induced changes in DnaK conformation were investigated by monitoring changes in tryptic digestion pattern and tryptophan fluorescence. Using nucleotide-free DnaK preparations, not only the known ATP-induced major changes in kinetics and pattern of proteolysis but also minor ADP-induced changes were detected. Similar ATP-induced conformational changes occurred in the DnaK-T199A mutant protein defective in ATPase activity, demonstrating that they result from binding, not hydrolysis, of ATP. N-terminal sequencing and immunological mapping of tryptic fragments of DnaK identified cleavage sites that, upon ATP addition, appeared within the proposed C-terminal substrate binding region and disappeared in the N-terminal ATPase domain. They hence reflect structural alterations in DnaK correlated to substrate release and indicate ATP-dependent domain interactions. Domain interactions are a prerequisite for efficient tryptic degradation as fragments of DnaK comprising the ATPase and C-terminal domains were highly protease-resistant. Fluorescence analysis of the N-terminally located single tryptophan residue of DnaK revealed that the known ATP-induced alteration of the emission spectrum, proposed to result directly from conformational changes in the ATPase domain, requires the presence of the C-terminal domain and therefore mainly results from altered domain interaction. Analyses of the C-terminally truncated DnaK163 mutant protein revealed that nucleotide-dependent interdomain communication requires a 15-kDa segment assumed to constitute the substrate binding site.

Identification of a major subfamily of large hsp70-like proteins through the cloning of the mammalian 110-kDa heat shock protein

A major mammalian heat shock protein of 110 kDa (hsp110) has long been observed, but has not been cloned. We have cloned the hamster cDNA for hsp110 and show that it hybridizes on a Northern blot to a 3.5-kilobase heat-inducible message in hamster and mouse. The hsp110 sequence was found to share an approximately 30-33% amino acid identity with members of the hsp70 family, most of which occurs in the conserved ATP-binding domain of these molecules. In addition, five sequences were found to be highly similar to hsp110. These are the sea urchin egg receptor for sperm (Foltz, K.R., Partin, J. S., and Lennarz, W.J. (1993) Science 259, 1421-1425) and additional sequences from human and Caenorhaditis elegans and two from yeast. The carboxyl-terminal two-thirds of hsp110 and these five related proteins contain a pattern of highly conserved regions of sequence unique to this group. A probe containing these conserved sequences was found to strongly cross-react on a Southern blot with genomic sequences from yeast to man. A Western blot analysis of several murine tissues indicates that hsp110 is constitutively expressed in all mouse tissues and is highly expressed in brain. Therefore, hsp110 belongs to a new category of large and structurally unique stress proteins that are the most distantly related known members of the hsp70 family.

Ultrastructural analysis of the dynactin complex: an actin-related protein is a component of a filament that resembles F-actin

The dynactin complex visualized by deepetch electron microscopy appears as a short filament 37-nm in length, which resembles F-actin, plus a thinner, laterally oriented filament that terminates in two globular heads. The locations of several of the constituent polypeptides were identified on this structure by applying antibodies to decorate the dynactin complex before processing for electron microscopy. Antibodies to the actin-related protein Arp1 (previously referred to as actin-RPV), bound at various sites along the filament, demonstrating that this protein assembles in a polymer similar to conventional actin. Antibodies to the barbed-end actin-binding protein, capping protein, bound to one end of the filament. Thus, an actin-binding protein that binds conventional actin may also bind to Arp1 to regulate its polymerization. Antibodies to the 62-kD component of the dynactin complex also bound to one end of the filament. An antibody that binds the COOH-terminal region of the 160/150-kD dynactin polypeptides bound to the globular domains at the end of the thin lateral filament, suggesting that the dynactin polypeptide comprises at least part of the sidearm structure.

A conserved loop in the ATPase domain of the DnaK chaperone is essential for stable binding of GrpE

The activity of DnaK (Hsp70) chaperones in assisting protein folding relies on DnaK binding and ATP-controlled release of protein substrates. The ATPase activity of DnaK is tightly controlled by the nucleotide exchange factor GrpE. We find that GrpE interacts stably with the amino-terminal ATPase domain of DnaK. Analysis of the mutant DnaK756 protein, which has a lower affinity for GrpE, reveals a role for residue Gly 32 in GrpE binding. Gly 32 is located in an exposed loop near the nucleotide binding site of DnaK. Deletion of this loop prevents stable GrpE binding, ATPase stimulation by GrpE, and DnaK chaperone activity. Conservation of this loop within the Hsp70 family suggests that cooperation between Hsp70 and GrpE-like proteins may be a general feature of this class of chaperone.

Does the HIV Nef protein mimic the MHC?

The sequence of the HIV Nef protein has no significant homology to other proteins in the SwissProt database, and experimental data concerning its function are sparse and contradictory. Using a novel protein sequence comparison method, we find similarities between different Nef sequences and the alpha chain of human MHC class I proteins. The possible biological implications of this finding are discussed.

Mammalian glucokinase and its gene

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Convergent evolution of similar enzymatic function on different protein folds: the hexokinase, ribokinase, and galactokinase families of sugar kinases

Kinases that catalyze phosphorylation of sugars, called here sugar kinases, can be divided into at least three distinct nonhomologous families. The first is the hexokinase family, which contains many prokaryotic and eukaryotic sugar kinases with diverse specificities, including a new member, rhamnokinase from Salmonella typhimurium. The three-dimensional structure of hexokinase is known and can be used to build models of functionally important regions of other kinases in this family. The second is the ribokinase family, of unknown three-dimensional structure, and comprises pro- and eukaryotic ribokinases, bacterial fructokinases, the minor 6-phosphofructokinase 2 from Escherichia coli, 6-phosphotagatokinase, 1-phosphofructokinase, and, possibly, inosine-guanosine kinase. The third family, also of unknown three-dimensional structure, contains several bacterial and yeast galactokinases and eukaryotic mevalonate and phosphomevalonate kinases and may have a substrate binding region in common with homoserine kinases. Each of the three families of sugar kinases appears to have a distinct three-dimensional fold, since conserved sequence patterns are strikingly different for the three families. Yet each catalyzes chemically equivalent reactions on similar or identical substrates. The enzymatic function of sugar phosphorylation appears to have evolved independently on the three distinct structural frameworks, by convergent evolution. In addition, evolutionary trees reveal that (1) fructokinase specificity has evolved independently in both the hexokinase and ribokinase families and (2) glucose specificity has evolved independently in different branches of the hexokinase family. These are examples of independent Darwinian adaptation of a structure to the same substrate at different evolutionary times. The flexible combination of active sites and three-dimensional folds observed in nature can be exploited by protein engineers in designing and optimizing enzymatic function.