Structural and biochemical analysis of sliding clamp/ligand interactions suggest a competition between replicative and translesion DNA polymerases

Most DNA polymerases interact with their cognate processive replication factor through a small peptide, this interaction being absolutely required for their function in vivo. We have solved the crystal structure of a complex between the beta sliding clamp of Escherichia coli and the 16 residue C-terminal peptide of Pol IV (P16). The seven C-terminal residues bind to a pocket located at the surface of one beta monomer. This region was previously identified as the binding site of another beta clamp binding protein, the delta subunit of the gamma complex. We show that peptide P16 competitively prevents beta-clamp-mediated stimulation of both Pol IV and alpha subunit DNA polymerase activities, suggesting that the site of interaction of the alpha subunit with beta is identical with, or overlaps that of Pol IV. This common binding site for delta, Pol IV and alpha subunit is shown to be formed by residues that are highly conserved among many bacterial beta homologs, thus defining an evolutionarily conserved hydrophobic crevice for sliding clamp ligands and a new target for antibiotic drug design.     

Two invariant tryptophans on the alpha1 subunit define domains necessary for GABA(A) receptor assembly.

Two invariant tryptophan residues on the N-terminal extracellular region of the rat alpha1 subunit, Trp-69 and Trp-94, are critical for the assembly of the GABA(A) (gamma-aminobutyric acid, type A) receptor into a pentamer. These tryptophans are common not only to all GABA(A) receptor subunits, but also to all ligand-gated ion channel subunits. Converting each Trp residue to Phe and Gly by site-directed mutagenesis allowed us to study the role of these invariant tryptophan residues. Mutant alpha1 subunits, coexpressed with beta2 subunits in baculovirus-infected Sf9 cells, displayed high affinity binding to [(3)H]muscimol, a GABA site ligand, but no binding to [(35)S]t-butyl bicyclophosphorothionate, a ligand for the receptor-associated ion channel. Neither [(3)H]muscimol binding to intact cells nor immunostaining of nonpermeabilized cells gave evidence of surface expression of the receptor. When expressed with beta2 and gamma2 polypeptides, the mutant alpha1 polypeptides did not form [(3)H]flunitrazepam binding sites though wild-type alpha1 polypeptides did. The distribution of the mutant receptors on sucrose gradients suggests that the effects on ligand binding result from the inability of the mutant alpha1 subunits to form pentamers. We conclude that Trp-69 and Trp-94 participate in the formation of the interface between alpha and beta subunits, but not of the GABA binding site.     

Total reconstitution of DNA polymerase III holoenzyme reveals dual accessory protein clamps

DNA polymerase III holoenzyme (holoenzyme) is the 10-subunit replicase of the Escherichia coli chromosome. In this report, pure preparations of delta, delta', and a gamma chi psi complex are resolved from the five protein gamma complex subassembly. Using these subunits and other holoenzyme subunits isolated from overproducing plasmid strains of E. coli, the rapid and highly processive holoenzyme has been reconstituted from only five pure single subunits: alpha, epsilon, gamma, delta, and beta. The preceding report showed that of the three subunits in the core polymerase, only a complex of alpha (DNA polymerase) and epsilon (3'-5' exonuclease) are required to assemble a processive holoenzyme on a template containing a preinitiation complex (Studwell, P.S., and O'Donnell, M. (1990) J. Biol. Chem. 265, 1171-1178). This report shows that of the five proteins in the gamma complex only a heterodimer of gamma and delta is required with the beta subunit to form the ATP-activated preinitiation complex with a primed template. Surprisingly, the delta' subunit does not form an active complex with gamma but forms a fully active heterodimer complex with the tau subunit (as does delta). Hence, the tau delta' and gamma delta heterodimers are fully active in the preinitiation complex reaction with beta and primed DNA. Holoenzymes reconstituted using the alpha epsilon complex, beta subunit, and either gamma delta or tau delta' are fully processive in DNA synthesis, and upon completing the template they rapidly cycle to a new primed template endowed with a preinitiation complex clamp. Since the holoenzyme molecule contains all of these accessory subunits (gamma, delta, tau, delta', and beta) in all likelihood it has the capacity to form two preinitiation complex clamps simultaneously at two primer termini. Two primer binding components within one holoenzyme may mediate its rapid cycling to multiple primers on the lagging strand and also provides functional evidence for the hypothesis of holoenzyme as a dimeric polymerase capable of simultaneous replication of both leading and lagging strands of a replication fork.     

The DNA replication machine of a gram-positive organism

This report outlines the protein requirements and subunit organization of the DNA replication apparatus of Streptococcus pyogenes, a Gram-positive organism. Five proteins coordinate their actions to achieve rapid and processive DNA synthesis. These proteins are: the PolC DNA polymerase, tau, delta, delta', and beta. S. pyogenes dnaX encodes only the full-length tau, unlike the Escherichia coli system in which dnaX encodes two proteins, tau and gamma. The S. pyogenes tau binds PolC, but the interaction is not as firm as the corresponding interaction in E. coli, underlying the inability to purify a PolC holoenzyme from Gram-positive cells. The tau also binds the delta and delta' subunits to form a taudeltadelta' "clamp loader." PolC can assemble with taudeltadelta' to form a PolC.taudeltadelta' complex. After PolC.taudeltadelta' clamps beta to a primed site, it extends DNA 700 nucleotides/second in a highly processive fashion. Gram-positive cells contain a second DNA polymerase, encoded by dnaE, that has homology to the E. coli alpha subunit of E. coli DNA polymerase III. We show here that the S. pyogenes DnaE polymerase also functions with the beta clamp.     

Devoted to the lagging strand-the subunit of DNA polymerase III holoenzyme contacts SSB to promote processive elongation and sliding clamp assembly.

Escherichia coli DNA polymerase III holoenzyme contains 10 different subunits which assort into three functional components: a core catalytic unit containing DNA polymerase activity, the beta sliding clamp that encircles DNA for processive replication, and a multisubunit clamp loader apparatus called gamma complex that uses ATP to assemble the beta clamp onto DNA. We examine here the function of the psi subunit of the gamma complex clamp loader. Omission of psi from the holoenzyme prevents contact with single-stranded DNA-binding protein (SSB) and lowers the efficiency of clamp loading and chain elongation under conditions of elevated salt. We also show that the product of a classic point mutant of SSB, SSB-113, lacks strong affinity for psi and is defective in promoting clamp loading and processive replication at elevated ionic strength. SSB-113 carries a single amino acid replacement at the penultimate residue of the C-terminus, indicating the C-terminus as a site of interaction with psi. Indeed, a peptide of the 15 C-terminal residues of SSB is sufficient to bind to psi. These results establish a role for the psi subunit in contacting SSB, thus enhancing the clamp loading and processivity of synthesis of the holoenzyme, presumably by helping to localize the holoenzyme to sites of SSB-coated ssDNA.     

Mechanism of the E. coli tau processivity switch during lagging-strand synthesis

The E. coli replication machinery employs a beta clamp that tethers the polymerase to DNA, thus ensuring high processivity. The replicase also contains a processivity switch that dissociates the polymerase from its beta clamp. The switch requires the tau subunit of the clamp loader and is regulated by different DNA structures. At a primed site, the switch is "off." When the replicase reaches the downstream primer to form a nick, the switch is flipped, and tau ejects the polymerase from beta. This switch has high fidelity for completed synthesis, remaining "off" until just prior to incorporation of the last nucleotide and turning "on" only after addition of the last dNTP. These actions of tau are confined to its C-terminal region, which is located outside the clamp loading apparatus. Thus, this highly processive replication machine has evolved a mechanism to specifically counteract processivity at a defined time in the lagging-strand cycle.     

Assembly of mutant subunits of the nicotinic acetylcholine receptor lacking the conserved disulfide loop structure.

Each subunit of the nicotinic acetylcholine receptor (AChR) contains two conserved cysteine residues, which are known to form a disulfide bond, in the N-terminal extracellular domain. The role of this retained structural feature in the biogenesis of the AChR was studied by expressing site-directed mutant alpha and beta subunits together with other normal subunits from Torpedo californica AChR in Xenopus oocytes. Mutation of the cysteines at position 128 or 142 in the alpha subunit, or in the beta subunit, did not prevent subunit assembly. All Cys128 and Cys142 mutants of the alpha and beta subunits were able to associate with coexpressed other normal subunits, although associational efficiency of the mutant alpha subunits with the delta subunit was reduced. Functional studies of the mutant AChR complexes showed that the mutations in the alpha subunit abolished detectable 125I-alpha-bungarotoxin (alpha-BuTX) binding in whole oocytes, whereas the mutations in the beta subunit resulted in decreased total binding of 125I-alpha-BuTX and no detectable surface 125I-alpha-BuTX binding. Additionally, all mutant subunits, when co-expressed with the other normal subunits in oocytes, produced small acetylcholine-activated membrane currents, suggesting incorporation of only small numbers of functional mutant AChRs into the plasma membrane. The functional acetylcholine-gated ion channel formed with mutant alpha subunits, but not mutant beta subunits, could not be blocked by alpha-BuTX. Thus, a disulfide bond between Cys128 and Cys142 of the AChR alpha or beta subunits is not needed for acetylcholine-binding. However, this disulfide bond on the alpha subunit is necessary for formation of the alpha-BuTX-binding site. These results also suggest that the most significant effect caused by disrupting the conserved disulfide loop structure is intracellular retention of most of the assembled AChR complexes.     

DNA polymerase III holoenzyme of Escherichia coli. III. Distinctive processive polymerases reconstituted from purified subunits

The 10 distinctive polypeptides of DNA polymerase III holoenzyme, purified as individual subunits or complexes, could be reconstituted to generate a polymerase with the high catalytic rate of the isolated intact holoenzyme. Functions and interactions of the subunits can be inferred from partial assemblies of the pol III core (alpha, epsilon, and theta subunits) with auxiliary subunits. The core possesses the polymerase and proofreading activities; the auxiliary subunits provide the core with processivity, the capacity to replicate long stretches of DNA without dissociating from the template. In a sequence of reconstruction steps, the beta subunit binds the primed template in an ATP-dependent manner through the catalytic action of a complex made up of the gamma, delta, delta', chi, and psi polypeptides. With the beta subunit in place, a processive polymerase is produced upon addition of the core. When the tau subunit is lacking, binding of polymerase to the primed template is less efficient and stable. The tau-less reconstituted polymerase is more prone to dissociation upon encountering secondary structures in the template in its path, such as a hairpin region in the single strand or a duplex region formed by a strand annealed to the template. With the tau subunit present, the interaction of the core.beta complex (the basic unit of a processive polymerase) with the primed template is strengthened. The tau-containing reconstituted polymerase can replicate DNA continuously through secondary structures in the template. The two distinctive kinds of processivity demonstrated by the tau-less and tau-containing reconstituted polymerases fit nicely into a scheme in which, organized as an asymmetric dimeric holoenzyme, the tau half is responsible for continuous synthesis of one strand, and the less stable half for discontinuous synthesis of the other.     

tau binds and organizes Escherichia coli replication through distinct domains. Partial proteolysis of terminally tagged tau to determine candidate domains and to assign domain V as the alpha binding domain

The tau subunit dimerizes Escherichia coli DNA polymerase III core through interactions with the alpha subunit. In addition to playing critical roles in the structural organization of the holoenzyme, tau mediates intersubunit communications required for efficient replication fork function. We identified potential structural domains of this multifunctional subunit by limited proteolysis of C-terminal biotin-tagged tau proteins. The cleavage sites of each of eight different proteases were found to be clustered within four regions of the tau subunit. The second susceptible region corresponds to the hinge between domain II and III of the highly homologous delta' subunit, and the third region is near the C-terminal end of the tau-delta' alignment (Guenther, B., Onrust, R., Sali, A., O'Donnell, M., and Kuriyan, J. (1997) Cell 91, 335-345). We propose a five-domain structure for the tau protein. Domains I and II are based on the crystallographic structure of delta' by Guenther and colleagues. Domains III-V are based on our protease cleavage results. Using this information, we expressed biotin-tagged tau proteins lacking specific protease-resistant domains and analyzed their binding to the alpha subunit by surface plasmon resonance. Results from these studies indicated that the alpha binding site of tau lies within its C-terminal 147 residues (domain V).     

The C terminus of annexin II mediates binding to F-actin

Annexin II heterotetramer (AIIt) is a multifunctional Ca(2+)-binding protein composed of two 11-kDa subunits and two annexin II subunits. The annexin II subunit contains the binding sites for anionic phospholipids, heparin, and F-actin, whereas the p11 subunit provides a regulatory function. The F-actin-binding site is presently unknown. In the present study we have utilized site-directed mutagenesis to create annexin II mutants with truncations in the C terminus of the molecule. Interestingly, a mutant annexin II lacking its C-terminal 16, 13, or 9 amino acids was unable to bind to F-actin but still retained its ability to interact with both anionic phospholipids and heparin. Recombinant AIIt, composed of wild-type p11 subunits and the mutant annexin II subunits, was also unable to bundle F-actin. This loss of F-actin bundling activity was directly attributable to the inability of mutant AIIt to bind F-actin. These results establish for the first time that the annexin II C-terminal amino acid residues, LLYLCGGDD, participate in F-actin binding.     

Identification of conserved residues contributing to the activities of adenovirus DNA polymerase

Adenovirus codes for a DNA polymerase that is a member of the DNA polymerase alpha family and uses a protein primer for initiation of DNA synthesis. It contains motifs characteristic of a proofreading 3'-5'-exonuclease domain located in the N-terminal region and several polymerase motifs located in the C-terminal region. To determine the role of adenovirus DNA polymerase in DNA replication, 22 site-directed mutations were introduced into the conserved DNA polymerase motifs in the C-terminal region of adenovirus DNA polymerase and the mutant forms were expressed in insect cells using a baculovirus expression system. Each mutant enzyme was tested for DNA binding activity, the ability to interact with pTP, DNA polymerase catalytic activity, and the ability to participate in the initiation of adenovirus DNA replication. The mutant phenotypes identify functional domains within the adenovirus DNA polymerase and allow discrimination between the roles of conserved residues in the various activities carried out by the protein. Using the functional data in this study and the previously published structure of the bacteriophage RB69 DNA polymerase (J. Wang et al., Cell 89:1087-1099, 1997), it is possible to envisage how the conserved domains in the adenovirus DNA polymerase function.     

Thermal stabilities of mutant Escherichia coli tryptophan synthase alpha subunits.

Random chemical mutagenesis, in vitro, of the 5' portion of the Escherichia coli trpA gene has yielded 66 mutant alpha subunits containing single amino acid substitutions at 49 different residue sites within the first 121 residues of the protein; this portion of the alpha subunit contains four of the eight alpha helices and three of the eight beta strands in the protein. Sixty-two of the subunits were examined for their heat stabilities by sensitivity to enzymatic inactivation (52 degrees C for 20 min) in crude extracts and by differential scanning calorimetry (DSC) with 29 purified proteins. The enzymatic activities of mutant alpha subunits that contained amino acid substitutions within the alpha and beta secondary structures were more heat labile than the wild-type alpha subunit. Alterations only in three regions, at or immediately C-terminal to the first three beta strands, were stability neutral or stability enhancing with respect to enzymatic inactivation. Enzymatic thermal inactivation appears to be correlated with the relative accessibility of the substituted residues; stability-neutral mutations are found at accessible residual sites, stability-enhancing mutations at buried sites. DSC analyses showed a similar pattern of stabilization/destabilization as indicated by inactivation studies. Tm differences from the wild-type alpha subunit varied +/- 7.6 degrees C. Eighteen mutant proteins containing alterations in helical and sheet structures had Tm's significantly lower (-1.6 to -7.5 degrees C) than the wild-type Tm (59.5 degrees C). In contrast, 6 mutant alpha subunits with alterations in the regions following beta strands 1 and 3 had increased Tm's (+1.4 to +7.6 degrees C). Because of incomplete thermal reversibilities for many of the mutant alpha subunits, most likely due to identifiable aggregated forms in the unfolded state, reliable differences in thermodynamic stability parameters are not possible. The availability of this group of mutant alpha subunits which clearly contain structural alterations should prove useful in defining the roles of certain residues or sequences in the unfolding/folding pathway for this protein when examined by urea/guaninidine denaturation kinetic analysis.     

Crystal structure of the oligomerization domain of the phosphoprotein of vesicular stomatitis virus

In the replication cycle of nonsegmented negative-strand RNA viruses, the viral RNA-dependent RNA polymerase (L) recognizes a nucleoprotein (N)-enwrapped RNA template during the RNA polymerase reaction. The viral phosphoprotein (P) is a polymerase cofactor essential for this recognition. We report here the 2.3-angstroms-resolution crystal structure of the central domain (residues 107 to 177) of P from vesicular stomatitis virus. The fold of this domain consists of a beta hairpin, an alpha helix, and another beta hairpin. The alpha helix provides the stabilizing force for forming a homodimer, while the two beta hairpins add additional stabilization by forming a four-stranded beta sheet through domain swapping between two molecules. This central dimer positions the N- and C-terminal domains of P to interact with the N and L proteins, allowing the L protein to specifically recognize the nucleocapsid-RNA template and to progress along the template while concomitantly assembling N with nascent RNA. The interdimer interactions observed in the noncrystallographic packing may offer insight into the mechanism of the RNA polymerase processive reaction along the viral nucleocapsid-RNA template.     

Constitution of the twin polymerase of DNA polymerase III holoenzyme

It is speculated that DNA polymerases which duplicate chromosomes are dimeric to provide concurrent replication of both leading and lagging strands. DNA polymerase III holoenzyme (holoenzyme), is the 10-subunit replicase of the Escherichia coli chromosome. A complex of the alpha (DNA polymerase) and epsilon (3'-5' exonuclease) subunits of the holoenzyme contains only one of each protein. Presumably, one of the eight other subunit(s) functions to dimerize the alpha epsilon polymerase within the holoenzyme. Based on dimeric subassemblies of the holoenzyme, two subunits have been elected as possible agents of polymerase dimerization, one of which is the tau subunit (McHenry, C. S. (1982) J. Biol. Chem. 257, 2657-2663). Here, we have used pure alpha, epsilon, and tau subunits in binding studies to determine whether tau can dimerize the polymerase. We find tau binds directly to alpha. Whereas alpha is monomeric, tau is a dimer in its native state and thereby serves as an efficient scaffold to dimerize the polymerase. The epsilon subunit does not associate directly with tau but becomes dimerized in the alpha epsilon tau complex by virtue of its interaction with alpha. We have analyzed the dimeric alpha epsilon tau complex by different physical methods to increase the confidence that this complex truly contains a dimeric polymerase. The tau subunit is comprised of the NH2-terminal two-thirds of tau but does not bind to alpha epsilon, identifying the COOH-terminal region of tau as essential to its polymerase dimerization function. The significance of these results with respect to the organization of subunits within the holoenzyme is discussed.     

Crystal structure of Rab geranylgeranyltransferase at 2.0 A resolution

BACKGROUND: Rab geranylgeranyltransferase (RabGGT) catalyzes the addition of two geranylgeranyl groups to the C-terminal cysteine residues of Rab proteins, which is crucial for membrane association and function of these proteins in intracellular vesicular trafficking. Unlike protein farnesyltransferase (FT) and type I geranylgeranyltransferase, which both prenylate monomeric small G proteins or short peptides, RabGGT can prenylate Rab only when Rab is in a complex with Rab escort protein (REP). RESULTS: The crystal structure of rat RabGGT at 2.0 A resolution reveals an assembly of four distinct structural modules. The beta subunit forms an alpha-alpha barrel that contains most of the residues in the active site. The alpha subunit consists of a helical domain, an immunoglobulin (Ig)-like domain, and a leucine-rich repeat (LRR) domain. The N-terminal region of the alpha subunit binds to the active site in the beta subunit; residue His2alpha directly coordinates a zinc ion. The prenyl-binding pocket of RabGGT is deeper than that in FT. CONCLUSIONS: LRR and Ig domains are often involved in protein-protein interactions; in RabGGT they might participate in the recognition and binding of REP. The binding of the N-terminal peptide of the alpha subunit to the active site suggests an autoinhibition mechanism that might contribute to the inability of RabGGT to recognize short peptides or Rab alone as its substrate. Replacement of residues Trp102beta and Tyr154beta in FT by Ser48beta and Leu99beta, respectively, in RabGGT largely determine the different lipid-binding specificities of the two enzymes.     

Homologous mutations on different subunits cause unequal but additive effects on n-alcohol block in the nicotinic receptor pore.

Hydrophobic antagonists of the nicotinic acetylcholine receptor inhibit channel activity by binding within the transmembrane pore formed by the second of four transmembrane domains (M2) on each of the receptor's subunits. Hydrophobic mutagenesis near the middle (10' locus) of the alpha-subunit M2 domain results in channels that are much more sensitive to block by long-chain alcohols and general anesthetics, indicating that the inhibitory site on wild-type receptors is nearby. To determine whether other receptor subunits also contribute to the blocker site, the hydrophobic mutagenesis strategy was extended to all four subunits at 10' loci. alpha S10'l causes the largest increase in apparent hexanol binding (4.3-fold compared to wild type), approximately twice the size of the change caused by beta T10'l (2.2-fold). gamma A10'l and delta A10'l mutations cause much smaller changes in apparent hexanol binding affinity (about 1.2-fold each), even when corrected for their smaller degree of side-chain hydrophobicity changes. When 10'l mutant subunits are coexpressed, the change from wild type in apparent hexanol binding energy (delta delta Gmixture) is roughly equal to the sum of hexanol binding energy changes for the constituent mutant subunits (sigma delta delta Gsubunits). The simplest model consistent with these results is one in which hydrophobic blockers make simultaneous contact with all five M2 10' residues, but the extent of contact is much greater for the alpha and beta than for gamma and delta side chains.     

Gating of heteromeric retinal rod channels by cyclic AMP: role of the C-terminal and pore domains

Cyclic nucleotide-gated channels are tetramers composed of homologous alpha and beta subunits. C-terminal truncation mutants of the alpha and beta subunits of the retinal rod channel were expressed in Xenopus oocytes, and analyzed for cGMP- and cAMP-induced currents (single-channel records and macroscopic currents). When the alpha subunit truncated downstream of the cGMP-binding site (alpha D608stop) is co-injected with truncated beta subunits, the heteromeric channels present a drastic increase of cAMP sensitivity. A partial effect is observed with heteromeric alpha R656stop-containing channels, while alpha K665stop-containing channels behave like alpha wt/beta wt. The three truncated alpha subunits have wild-type activity when expressed alone. Heteromeric channels composed of alpha wt or truncated alpha subunits and chimeric beta subunits containing the pore domain of the alpha subunit have the same cAMP sensitivity as alpha-only channels. The results disclose the key role of two domains distinct from the nucleotide binding site in the gating of heteromeric channels by cAMP: the pore of the beta subunit, which has an activating effect, and a conserved domain situated downstream of the cGMP-binding site in the alpha subunit (I609-K665), which inhibits this effect.