Elucidation of the epsilon-theta subunit interface of Escherichia coli DNA polymerase III by NMR spectroscopy

The DNA polymerase III holoenzyme (HE) is the primary replicative polymerase of Escherichia coli. The epsilon (epsilon) subunit of HE provides the 3'-->5' exonucleolytic proofreading activity for this complex. Epsilon consists of two domains: an N-terminal domain containing the proofreading exonuclease activity (residues 1-186) and a C-terminal domain required for binding to the polymerase (alpha) subunit (residues 187-243). In addition to alpha, epsilon also binds the small (8 kDa) theta (theta) subunit. The function of theta is unknown, although it has been hypothesized to enhance the 3'-->5' exonucleolytic proofreading activity of epsilon. Using NMR analysis and molecular modeling, we have previously reported a structural model of epsilon186, the N-terminal catalytic domain of epsilon [DeRose et al. (2002) Biochemistry 41, 94]. Here, we have performed 3D triple resonance NMR experiments to assign the backbone and C(beta) resonances of [U-(2)H,(13)C,(15)N] methyl protonated epsilon186 in complex with unlabeled theta. A structural comparison of the epsilon186-theta complex with free epsilon186 revealed no major changes in secondary structure, implying that the overall structure is not significantly perturbed in the complex. Amide chemical shift comparisons between bound and unbound epsilon186 revealed a potential binding surface on epsilon for interaction with theta involving structural elements near the epsilon catalytic site. The most significant shifts observed for the epsilon186 amide resonances are localized to helix alpha1 and beta-strands 2 and 3 and to the region near the beginning of alpha-helix 7. Additionally, a small stretch of residues (K158-L161), which previously had not been assigned in uncomplexed epsilon186, is predicted to adopt beta-strand secondary structure in the epsilon186-theta complex and may be significant for interaction with theta. The amide shift pattern was confirmed by the shifts of aliphatic methyl protons, for which the larger shifts generally were concentrated in the same regions of the protein. These chemical shift mapping results also suggest an explanation for how the unstable dnaQ49 mutator phenotype of epsilon may be stabilized by binding theta.     

Nuclear magnetic resonance solution structure of the Escherichia coli DNA polymerase III theta subunit

The catalytic core of Escherichia coli DNA polymerase III holoenzyme contains three subunits: alpha, epsilon, and theta. The alpha subunit contains the polymerase, and the epsilon subunit contains the exonucleolytic proofreading function. The small (8-kDa) theta subunit binds only to epsilon. Its function is not well understood, although it was shown to exert a small stabilizing effect on the epsilon proofreading function. In order to help elucidate its function, we undertook a determination of its solution structure. In aqueous solution, theta yielded poor-quality nuclear magnetic resonance spectra, presumably due to conformational exchange and/or protein aggregation. Based on our recently determined structure of the theta homolog from bacteriophage P1, named HOT, we constructed a homology model of theta. This model suggested that the unfavorable behavior of theta might arise from exposed hydrophobic residues, particularly toward the end of alpha-helix 3. In gel filtration studies, theta elutes later than expected, indicating that aggregation is potentially responsible for these problems. To address this issue, we recorded 1H-15N heteronuclear single quantum correlation (HSQC) spectra in water-alcohol mixed solvents and observed substantially improved dispersion and uniformity of peak intensities, facilitating a structural determination under these conditions. The structure of theta in 60/40 (vol/vol) water-methanol is similar to that of HOT but differs significantly from a previously reported theta structure. The new theta structure is expected to provide additional insight into its physiological role and its effect on the epsilon proofreading subunit.     

A preliminary CD and NMR study of the Escherichia coli DNA polymerase III theta subunit.

The theta subunit of DNA polymerase III, the main replicative polymerase of Escherichia coli, has been examined by circular dichroism and by NMR spectroscopy. The polymerase core consists of three subunits: alpha, epsilon, and theta, with alpha possessing the polymerase activity, epsilon functioning as a proofreading exonuclease, and theta, a small subunit of 8.9 kD, of undetermined function. The theta subunit has been expressed in E. coli, and a CD analysis of theta indicates the presence of a significant amount of secondary structure: approximately 52% alpha helix, 9% beta sheet, 21% turns, and 18% random coil. However, at higher concentrations, theta yields a poorly-resolved 1D proton NMR spectrum in which both the amide protons and the methyl protons show poor chemical shift dispersion. Subsequent 1H-15N HSQC analysis of uniformly-15N-labeled theta supports the conclusion that approximately half of the protein is reasonably well-structured. Another quarter of the protein, probably including some of the N-terminal region, is highly mobile, exhibiting a chemical shift pattern indicative of random coil structure. The remaining amide resonances exhibit significant broadening, indicative of intermolecular and/or intramolecular exchange processes. Improved chemical shift dispersion and greater uniformity of resonance intensities in the 1H-15N HSQC spectra resulted when [U-15N]-theta was examined in the presence of epsilon186--the N-terminal domain of the epsilon-subunit. Further work is currently in progress to define the solution structure of theta and the theta-epsilon186 complex.     

Two functional domains of the epsilon subunit of DNA polymerase III

The epsilon subunit is the 3'-->5' proofreading exonuclease that associates with the alpha and theta subunits in the E. coli DNA polymerase III. Two fragments of the epsilon protein were prepared, and binding of these epsilon fragments with alpha and theta was investigated using gel filtration chromatography and exonuclease stimulation assays. The N-terminal fragment of epsilon, containing amino acids 2-186 (epsilon186), is a relatively protease-resistant core domain of the exonuclease. The purified recombinant epsilon186 protein catalyzes the cleavage of 3' terminal nucleotides, demonstrating that the exonuclease domain of epsilon is present in the N-terminal region of the protein. The absence of the C-terminal 57 amino acids of epsilon in the epsilon186 protein reduces the binding affinity of epsilon186 for alpha by at least 400-fold relative to the binding affinity of epsilon for alpha. In addition, stimulation of the epsilon186 exonuclease by alpha using a partial duplex DNA is about 50-fold lower than stimulation of the epsilon exonuclease by alpha. These results indicate that the C-terminal region of epsilon is required in the epsilonalpha association. To directly demonstrate that the C-terminal region of epsilon contains the alpha-association domain fusion protein, constructs containing the maltose-binding protein (MBP) and fragments of the C-terminal region of epsilon were prepared. Gel filtration analysis demonstrates that the alpha-association domain of epsilon is contained within the C-terminal 40 amino acids of epsilon. Also, the epsilon186 protein forms a tight complex with theta, demonstrating that the association of theta with epsilon is localized to the N-terminal region of epsilon. Association of epsilon186 and theta is further supported by the stimulation of the epsilon186 exonuclease in the presence of theta. These data support the concept that epsilon contains a catalytic domain located within the N-terminal region and an alpha-association domain located within the C-terminal region of the protein.     

Phage like it HOT: solution structure of the bacteriophage P1-encoded HOT protein, a homolog of the theta subunit of E. coli DNA polymerase III

DNA polymerase III, the main replicative polymerase of E. coli, contains a small subunit, theta, that binds to the epsilon proofreading subunit and appears to enhance the enzyme's proofreading function--especially under extreme conditions. It was recently discovered that E. coli bacteriophage P1 encodes a theta homolog, named HOT. The (1)H-(15)N HSQC spectrum of HOT exhibits more uniform intensities and less evidence of conformational exchange than that of theta; this uniformity facilitates a determination of the HOT solution structure by NMR. The structure contains three alpha helices, as reported previously for theta; however, the folding topology of the two proteins is very different. Residual dipolar coupling measurements on labeled theta support the conclusion that it is structurally homologous with HOT. As judged by CD measurements, the melting temperature of HOT was 62 degrees C, compared to 56 degrees C for theta, consistent with other data suggesting greater thermal stability of the HOT protein.     

NMR solution structure of the theta subunit of DNA polymerase III from Escherichia coli

The catalytic core of Escherichia coli DNA polymerase III contains three tightly associated subunits (alpha, epsilon, and theta). The theta subunit is the smallest, but the least understood of the three. As a first step in a program aimed at understanding its function, the structure of the theta subunit has been determined by triple-resonance multidimensional NMR spectroscopy. Although only a small protein, theta was difficult to assign fully because approximately one-third of the protein is unstructured, and some sections of the remaining structured parts undergo intermediate intramolecular exchange. The secondary structure was deduced from the characteristic nuclear Overhauser effect patterns, the 3J(HN alpha) coupling constants and the consensus chemical shift index. The C-terminal third of the protein, which has many charged and hydrophilic amino acid residues, has no well-defined secondary structure and exists in a highly dynamic state. The N-terminal two-thirds has three helical segments (Gln10-Asp19, Glu38-Glu43, and His47-Glu54), one short extended segment (Pro34-Ala37), and a long loop (Ala20-Glu29), of which part may undergo intermediate conformational exchange. Solution of the three-dimensional structure by NMR techniques revealed that the helices fold in such a way that the surface of theta is bipolar, with one face of the protein containing most of the acidic residues and the other face containing most of the long chain basic residues. Preliminary chemical shift mapping experiments with a domain of the epsilon subunit have identified a loop region (Ala20-Glu29) in theta as the site of association with epsilon.     

Structure of the Escherichia coli DNA polymerase III epsilon-HOT proofreading complex

The epsilon subunit of Escherichia coli DNA polymerase III possesses 3'-exonucleolytic proofreading activity. Within the Pol III core, epsilon is tightly bound between the alpha subunit (DNA polymerase) and subunit. Here, we present the crystal structure of epsilon in complex with HOT, the bacteriophage P1-encoded homolog of , at 2.1 A resolution. The epsilon-HOT interface is defined by two areas of contact: an interaction of the previously unstructured N terminus of HOT with an edge of the epsilon central beta-sheet as well as interactions between HOT and the catalytically important helix alpha1-loop-helix alpha2 motif of epsilon. This structure provides insight into how HOT and, by implication, may stabilize the epsilon subunit, thus promoting efficient proofreading during chromosomal replication.     

The C-terminal domain of dnaQ contains the polymerase binding site

The Escherichia coli dnaQ gene encodes the 3'-->5' exonucleolytic proofreading (epsilon) subunit of DNA polymerase III (Pol III). Genetic analysis of dnaQ mutants has suggested that epsilon might consist of two domains, an N-terminal domain containing the exonuclease and a C-terminal domain essential for binding the polymerase (alpha) subunit. We have created truncated forms of dnaQ resulting in epsilon subunits that contain either the N-terminal or the C-terminal domain. Using the yeast two-hybrid system, we analyzed the interactions of the single-domain epsilon subunits with the alpha and theta subunits of the Pol III core. The DnaQ991 protein, consisting of the N-terminal 186 amino acids, was defective in binding to the alpha subunit while retaining normal binding to the theta subunit. In contrast, the NDelta186 protein, consisting of the C-terminal 57 amino acids, exhibited normal binding to the alpha subunit but was defective in binding to the theta subunit. A strain carrying the dnaQ991 allele exhibited a strong, recessive mutator phenotype, as expected from a defective alpha binding mutant. The data are consistent with the existence of two functional domains in epsilon, with the C-terminal domain responsible for polymerase binding.     

Hydrolysis of the 5'-p-nitrophenyl ester of TMP by the proofreading exonuclease (epsilon) subunit of Escherichia coli DNA polymerase III

The core of DNA polymerase III, the replicative polymerase in Escherichia coli, consists of three subunits (alpha, epsilon, and theta). The epsilon subunit is the 3'-5' proofreading exonuclease that associates with the polymerase (alpha) through its C-terminal region and theta through a 185-residue N-terminal domain (epsilon 186). A spectrophotometric assay for measurement of epsilon activity is described. Proteins epsilon and epsilon 186 and the epsilon 186.theta complex catalyzed the hydrolysis of the 5'-p-nitrophenyl ester of TMP (pNP-TMP) with similar values of k(cat) and K(M), confirming that the N-terminal domain of epsilon bears the exonuclease active site, and showing that association with theta has little direct effect on the chemistry occurring at the active site of epsilon. On the other hand, formation of the complex with theta stabilized epsilon 186 by approximately 14 degrees C against thermal inactivation. For epsilon 186, k(cat) = 293 min(-)(1) and K(M) = 1.08 mM at pH 8.00 and 25 degrees C, with a Mn(2+) concentration of 1 mM. Hydrolysis of pNP-TMP by epsilon 186 depended absolutely on divalent metal ions, and was inhibited by the product TMP. Dependencies on Mn(2+) and Mg(2+) concentrations were examined, giving a K(Mn) of 0.31 mM and a k(cat) of 334 min(-1) for Mn(2+) and a K(Mg) of 6.9 mM and a k(cat) of 19.9 min(-1) for Mg(2+). Inhibition by TMP was formally competitive [K(i) = 4.3 microM (with a Mn(2+) concentration of 1 mM)]. The pH dependence of pNP-TMP hydrolysis by epsilon 186, in the pH range of 6.5-9.0, was found to be simple. K(M) was essentially invariant between pH 6.5 and 8.5, while k(cat) depended on titration of a single group with a pK(a) of 7.7, approaching limiting values of 50 min(-1) at pH <6.5 and 400 min(-1) at pH >9.0. These data are used in conjunction with crystal structures of the complex of epsilon 186 with TMP and two Mn(II) ions bound at the active site to develop insights into the mechanisms of pNP-TMP hydrolysis by epsilon at high and low pH values.     

Structure of the Rhodobacter sphaeroides light-harvesting 1 beta subunit in detergent micelles.

The light harvesting 1 antenna (LH1) complex from Rhodobacter sphaeroides funnels excitation energy to the photosynthetic reaction center. Our ultimate goal is to build up the structure of LH1 from structures of its individual subunits, much as the antenna can self-assemble from its components in membrane-mimicking detergent micelles. The beta subunit adopts a nativelike conformation in Zwittergent 3:12 micelles as demonstrated by its ability to take the first step of assembly, binding BChl a. Multidimensional NMR spectroscopy shows that the beta subunit folds as a helix((L12-S25))-hinge((G26-W28))-helix((L29-W44)) structure with the helical regions for the 10 lowest-energy structures having backbone rmsds of 0.26 and 0.24 A, respectively. Mn(2+) relaxation data and the protein-detergent NOE pattern show the C-terminal helix embedded in the micelle and the N-terminal helix lying along the detergent micelle surface with a 60 degrees angle between their long axes. (15)N relaxation data for residues L12-W44 are typical of a well-ordered protein with a correlation time of 8.25 +/- 2.1 ns. The presence of the hinge region placing the N-terminal helix along the membrane surface may be the structural feature responsible for the functional differences observed between the LH1 and LH2 beta subunits.     

Zinc-substituted Desulfovibrio gigas desulforedoxins: resolving subunit degeneracy with nonsymmetric pseudocontact shifts

Desulfovibrio gigas desulforedoxin (Dx) consists of two identical peptides, each containing one [Fe-4S] center per monomer. Variants with different iron and zinc metal compositions arise when desulforedoxin is produced recombinantly from Escherichia coli. The three forms of the protein, the two homodimers [Fe(III)/Fe(III)]Dx and [Zn(II)/Zn(II)]Dx, and the heterodimer [Fe(III)/Zn(II)]Dx, can be separated by ion exchange chromatography on the basis of their charge differences. Once separated, the desulforedoxins containing iron can be reduced with added dithionite. For NMR studies, different protein samples were prepared labeled with (15)N or (15)N + (13)C. Spectral assignments were determined for [Fe(II)/Fe(II)]Dx and [Fe(II)/Zn(II)]Dx from 3D (15)N TOCSY-HSQC and NOESY-HSQC data, and compared with those reported previously for [Zn(II)/Zn(II)]Dx. Assignments for the (13)C(alpha) shifts were obtained from an HNCA experiment. Comparison of (1)H-(15)N HSQC spectra of [Zn(II)/Zn(II)]Dx, [Fe(II)/Fe(II)]Dx and [Fe(II)/Zn(II)]Dx revealed that the pseudocontact shifts in [Fe(II)/Zn(II)]Dx can be decomposed into inter- and intramonomer components, which, when summed, accurately predict the observed pseudocontact shifts observed for [Fe(II)/Fe(II)]Dx. The degree of linearity observed in the pseudocontact shifts for residues >/=8.5 A from the metal center indicates that the replacement of Fe(II) by Zn(II) produces little or no change in the structure of Dx. The results suggest a general strategy for the analysis of NMR spectra of homo-oligomeric proteins in which a paramagnetic center introduced into a single subunit is used to break the magnetic symmetry and make it possible to obtain distance constraints (both pseudocontact and NOE) between subunits.     

Model for the catalytic domain of the proofreading epsilon subunit of Escherichia coli DNA polymerase III based on NMR structural data.

The DNA polymerase III holoenzyme (HE) is the primary replicative polymerase of Escherichia coli. The epsilon subunit of the HE complex provides the 3'-exonucleolytic proofreading activity for this enzyme complex. epsilon consists of two domains: an N-terminal domain containing the proofreading exonuclease activity (residues 1-186) and a C-terminal domain required for binding to the polymerase (alpha) subunit (residues 187-243). Multidimensional NMR studies of (2)H-, (13)C-, and (15)N-labeled N-terminal domains (epsilon186) were performed to assign the backbone resonances and measure H(N)-H(N) nuclear Overhauser effects (NOEs). NMR studies were also performed on triple-lableled [U-(2)H,(13)C,(15)N]epsilon186 containing Val, Leu, and Ile residues with protonated methyl groups, which allowed for the assignment of H(N)-CH(3) and CH(3)-CH(3) NOEs. Analysis of the (13)C(alpha), (13)C(beta), and (13)CO shifts, using chemical shift indexing and the TALOS program, allowed for the identification of regions of the secondary structure. H(N)-H(N) NOEs provided information on the assembly of the extended strands into a beta-sheet structure and confirmed the assignment of the alpha helices. Measurement of H(N)-CH(3) and CH(3)-CH(3) NOEs confirmed the beta-sheet structure and assisted in the positioning of the alpha helices. The resulting preliminary characterization of the three-dimensional structure of the protein indicated that significant structural homology exists with the active site of the Klenow proofreading exonuclease domain, despite the extremely limited sequence homology. On the basis of this analogy, molecular modeling studies of epsilon186 were performed using as templates the crystal structures of the exonuclease domains of the Klenow fragment and the T4 DNA polymerase and the recently determined structure of the E. coli Exonuclease I. A multiple sequence alignment was constructed, with the initial alignment taken from the previously published hidden Markov model and NMR constraints. Because several of the published structures included complexed ssDNA, we were also able to incorporate an A-C-G trinucleotide into the epsilon186 structure. Nearly all of the residues which have been identified as mutators are located in the portion of the molecule which binds the DNA, with most of these playing either a catalytic or structural role.     

An NMR structural study of nickel-substituted rubredoxin

The Ni(II) and Zn(II) derivatives of Desulfovibrio vulgaris rubredoxin (DvRd) have been studied by NMR spectroscopy to probe the structure at the metal centre. The βCH₂ proton pairs from the cysteines that bind the Ni(II) atom have been identified using 1D nuclear Overhauser enhancement (NOE) difference spectra and sequence specifically assigned via NOE correlations to neighbouring protons and by comparison with the published X-ray crystal structure of a Ni(II) derivative of Clostridium pasteurianum rubredoxin. The solution structures of DvRd(Zn) and DvRd(Ni) have been determined and the paramagnetic form refined using pseudocontact shifts. The determination of the magnetic susceptibility anisotropy tensor allowed the contact and pseudocontact contributions to the observed chemical shifts to be obtained. Analysis of the pseudocontact and contact chemical shifts of the cysteine Hβ protons and backbone protons close to the metal centre allowed conclusions to be drawn as to the geometry and hydrogen-bonding pattern at the metal binding site. The importance of NH–S hydrogen bonds at the metal centre for the delocalization of electron spin density is confirmed for rubredoxins and can be extrapolated to metal centres in Cu proteins: amicyanin, plastocyanin, stellacyanin, azurin and pseudoazurin.     

Cloning and expression of the epsilon 4 subunit of the NMDA receptor channel.

The primary structure of a novel subunit of the mouse NMDA (N-methyl-D-aspartate) receptor channel, designated epsilon 4, has been revealed by cloning and sequencing the cDNA. The epsilon 4 subunit shares high amino acid sequence identity with the epsilon 1, epsilon 2 and epsilon 3 subunits of the mouse NMDA receptor channel, thus constituting the epsilon subfamily of the glutamate receptor channel. Expression from cloned cDNAs of the epsilon 4 subunit together with the zeta 1 subunit in Xenopus oocytes yields functional NMDA receptor channels. The epsilon 4/zeta 1 heteromeric channel exhibits high apparent affinities for agonists and low sensitivities to competitive antagonists. The epsilon 4 subunit is thus distinct in functional properties from the epsilon 1, epsilon 2 and epsilon 3 subunits, and contributes further diversity of the NMDA receptor channel.     

PSEUDYANA for NMR structure calculation of paramagnetic metalloproteins using torsion angle molecular dynamics

The program DYANA, for calculation of solution structures of biomolecules with an algorithm based on simulated annealing by torsion angle dynamics, has been supplemented with a new routine, PSEUDYANA, that enables efficient use of pseudocontact shifts as additional constraints in structure calculations of paramagnetic metalloproteins. PSEUDYANA can determine the location of the metal ion inside the protein frame and allows to define a single tensor of magnetic susceptibility from a family of conformers. As an illustration, a PSEUDYANA structure calculation is provided for a metal-undecapeptide complex, where simulated pseudocontact shifts but no NOE restraints are used as conformational constraints.     

Application of electrospray ionization mass spectrometry to study the hydrophobic interaction between the epsilon and theta subunits of DNA polymerase III

The interactions between the N-terminal domain of the epsilon (epsilon186) and theta subunits of DNA polymerase III of Escherichia coli were investigated using electrospray ionization mass spectrometry. The epsilon186-theta complex was stable in 9 M ammonium actetate (pH 8), suggesting that hydrophobic interactions have a predominant contribution to the stability of the complex. Addition of primary alkanols to epsilon186-theta in 0.1 M ammonium acetate (pH 8), led to dissociation of the complex, as observed in the mass spectrometer. The concentrations of methanol, ethanol, and 1-propanol required to dissociate 50% of the complex were 8.9 M, 4.8 M, and 1.7 M, respectively. Closer scrutiny of the effect of alkanols on epsilon186, theta, and epsilon186-theta showed that epsilon186 formed soluble aggregates prior to precipitation, and that the association of epsilon186 with theta stabilized epsilon186. In-source collision-induced dissociation experiments and other results suggested that the epsilon186-theta complex dissociated in the mass spectrometer, and that the stability (with respect to dissociation) of the complex in vacuo was dependent on the solution from which it was sampled.     

DNA and RNA-DNA annealing activity associated with the tau subunit of the Escherichia coli DNA polymerase III holoenzyme.

The DNA polymerase III (pol III)holoenzyme is the 10 subunit replicase of Escherichia coli. The 71 kDa tau subunit, encoded by dnaX, dimerizes the core polymerase (alpha epsilon theta) to form pol III'[(alpha epsilon theta)2 tau 2]. tau is also a single-stranded DNA-dependent ATPase and can substitute for the gamma subunit during initiation complex formation. We show here that tau also possesses a DNA-DNA and RNA-DNA annealing activity that is stimulated by Mg2+, but neither requires ATP nor is inhibited by non-hydrolyzable ATP analogs. This suggests the tau may act to stabilize the primer-template interaction during DNA replication.     

The theta subunit of Escherichia coli DNA polymerase III: a role in stabilizing the epsilon proofreading subunit

The function of the theta subunit of Escherichia coli DNA polymerase III holoenzyme is not well established. theta is a tightly bound component of the DNA polymerase III core, which contains the alpha subunit (polymerase), the epsilon subunit (3'-->5' exonuclease), and the theta subunit, in the linear order alpha-epsilon-theta. Previous studies have shown that the theta subunit is not essential, as strains carrying a deletion of the holE gene (which encodes theta) proved fully viable. No significant phenotypic effects of the holE deletion could be detected, as the strain displayed normal cell health, morphology, and mutation rates. On the other hand, in vitro experiments have indicated the efficiency of the 3'-exonuclease activity of epsilon to be modestly enhanced by the presence of theta. Here, we report a series of genetic experiments that suggest that theta has a stabilizing role for the epsilon proofreading subunit. The observations include (i) defined DeltaholE mutator effects in mismatch-repair-defective mutL backgrounds, (ii) strong DeltaholE mutator effects in certain proofreading-impaired dnaQ strains, and (iii) yeast two- and three-hybrid experiments demonstrating enhancement of alpha-epsilon interactions by the presence of theta. theta appears conserved among gram-negative organisms which have an exonuclease subunit that exists as a separate protein (i.e., not part of the polymerase polypeptide), and the presence of theta might be uniquely beneficial in those instances where the proofreading 3'-exonuclease is not part of the polymerase polypeptide.     

The polymerase subunit of DNA polymerase III of Escherichia coli. II. Purification of the alpha subunit, devoid of nuclease activities

The alpha subunit (140 kDa) of DNA polymerase III (pol III) holoenzyme has been purified to near-homogeneity from a plasmid-carrying Escherichia coli strain which overproduced the alpha subunit about 20-fold. Pol III core (containing only the alpha, epsilon, and theta subunits), produced at twice the normal level, was also purified in good yield. The isolated alpha subunit has DNA polymerase activity, which is completely inhibited by 10 mM N-ethylmaleimide or 150 mM KCl as observed in the pol III core or holoenzyme. The alpha subunit has an apparent turnover number of 7.7 nucleotides polymerized per s, compared to 20 for pol III core, and is more thermolabile. The alpha subunit lacks the 3'----5' exonuclease (proofreading) activity of pol III core; neither alpha subunit nor core (nor holoenzyme) possesses any of the previously reported 5'----3' exonuclease activity. Thus, the alpha polypeptide is the polymerase subunit and epsilon (27 kDa) is the proofreading subunit (Scheuermann, R. H., and Echols, H. (1984) Proc. Natl. Acad. Sci. U. S. A. 81, 7747-7751). Together with the theta polypeptide (10 kDa), of unknown function, they form a pol III core with greater stability and catalytic efficiency.     

The use of pseudocontact shifts to refine solution structures of paramagnetic metalloproteins: Met80Ala cyano-cytochrome c as an example

 The availability of NOE constraints and of the relative solution structure of a paramagnetic protein permits the use of pseudocontact shifts as further structural constraints. We have developed a strategy based on: (1) determination of the χ tensor anisotropy parameters from the starting structure; (2) recalculation of a new structure by using NOE and pseudocontact shift constraints simultaneously; (3) redetermination of the χ tensor anisotropy parameters from the new structure, and so on until self-consistency. The system investigated is the cyanide derivative of a variant of the oxidized Saccharomyces cerevisiae iso-1-cytochrome c containing the Met80Ala mutation. The structure has been substantially refined. It is shown that the analysis of the deviation of the experimental pseudocontact shifts from those calculated using the starting structure may be unsound, as may the simple structure refinement based on the pseudocontact shift constraints only. Received: 11 July 1995 / Accepted: 30 October 1995