The weak interdomain coupling observed in the 70 kDa subunit of human replication protein A is unaffected by ssDNA binding.

Replication protein A (RPA) is a heterotrimeric, multi-functional protein that binds single-stranded DNA (ssDNA) and is essential for eukaryotic DNA metabolism. Using heteronuclear NMR methods we have investigated the domain interactions and ssDNA binding of a fragment from the 70 kDa subunit of human RPA (hRPA70). This fragment contains an N-terminal domain (NTD), which is important for hRPA70-protein interactions, connected to a ssDNA-binding domain (SSB1) by a flexible linker (hRPA70(1-326)). Correlation analysis of the amide (1)H and (15)N chemical shifts was used to compare the structure of the NTD and SSB1 in hRPA70(1-326) with two smaller fragments that corresponded to the individual domains. High correlation coefficients verified that the NTD and SSB1 maintained their structures in hRPA70(1-326), indicating weak interdomain coupling. Weak interdomain coupling was also suggested by a comparison of the transverse relaxation rates for hRPA70(1-326) and one of the smaller hRPA70 fragments containing the NTD and the flexible linker (hRPA70(1-168)). We also examined the structure of hRPA70(1-326) after addition of three different ssDNA substrates. Each of these substrates induced specific amide (1)H and/or (15)N chemical shift changes in both the NTD and SSB1. The NTD and SSB1 have similar topologies, leading to the possibility that ssDNA binding induced the chemical shift changes observed for the NTD. To test this hypothesis we monitored the amide (1)H and (15)N chemical shift changes of hRPA70(1-168) after addition of ssDNA. The same amide (1)H and (15)N chemical shift changes were observed for the NTD in hRPA70(1-168) and hRPA70(1-326). The NTD residues with the largest amide (1)H and/or (15)N chemical shift changes were localized to a basic cleft that is important for hRPA70-protein interactions. Based on this relationship, and other available data, we propose a model where binding between the NTD and ssDNA interferes with hRPA70-protein interactions.

Interactions of human nucleotide excision repair protein XPA with DNA and RPA70 Delta C327: chemical shift mapping and 15N NMR relaxation studies.

Human XPA is an essential component in the multienzyme nucleotide excision repair (NER) pathway. The solution structure of the minimal DNA binding domain of XPA (XPA-MBD: M98-F219) was recently determined [Buchko et al. (1998) Nucleic Acids Res. 26, 2779-2788, Ikegami et al. (1998) Nat. Struct. Biol. 5, 701-706] and shown to consist of a compact zinc-binding core and a loop-rich C-terminal subdomain connected by a linker sequence. Here, the solution structure of XPA-MBD was further refined using an entirely new class of restraints based on pseudocontact shifts measured in cobalt-substituted XPA-MBD. Using this structure, the surface of XPA-MBD which interacts with DNA and a fragment of the largest subunit of replication protein A (RPA70 Delta C327: M1-Y326) was determined using chemical shift mapping. DNA binding in XPA-MBD was highly localized in the loop-rich subdomain for DNA with or without a lesion [dihydrothymidine (dhT) or 6-4-thymidine-cytidine (64TC)], or with DNA in single- or double-stranded form, indicating that the character of the lesion itself is not the driving force for XPA binding DNA. RPA70 Delta C327 was found to contact regions in both the zinc-binding and loop-rich subdomains. Some overlap of the DNA and RPA70 Delta C327 binding regions was observed in the loop-rich subdomain, indicating a possible cooperative DNA-binding mode between XPA and RPA70 Delta C327. To complement the chemical shift mapping data, the backbone dynamics of free XPA-MBD and XPA-MBD bound to DNA oligomers containing dhT or 64TC lesions were investigated using 15N NMR relaxation data. The dynamic analyses for the XPA-MBD complexes with DNA revealed localized increases and decreases in S2 and an increase in the global correlation time. Regions of XPA-MBD with the largest increases in S2 overlapped regions having the largest chemical shifts changes upon binding DNA, indicating that the loop-rich subdomain becomes more rigid upon binding DNA. Interestingly, S2 decreased for some residues in the zinc-binding core upon DNA association, indicating a possible concerted structural rearrangement on binding DNA.

Human replication protein A: global fold of the N-terminal RPA-70 domain reveals a basic cleft and flexible C-terminal linker.

Human Replication Protein A (hsRPA) is required for multiple cellular processes in DNA metabolism including DNA repair, replication and recombination. It binds single-stranded DNA with high affinity and interacts specifically with multiple proteins. hsRPA forms a heterotrimeric complex composed of 70-, 32- and 14-kDa subunits (henceforth RPA70, RPA32, and RPA14). The N-terminal 168 residues of RPA70 form a structurally distinct domain that stimulates DNA polymerase alpha activity, interacts with several transcriptional activators including tumor suppressor p53, and during the cell cycle it signals escape from the DNA damage induced G2/M checkpoint. We have solved the global fold of the fragment corresponding to this domain (RPA70 delta 169) and we find residues 8-108 of the N-terminal domain are structured. The remaining C-terminal residues are unstructured and may form a flexible linker to the DNA-binding domain of RPA70. The globular region forms a five-stranded anti-parallel beta-barrel. The ends of the barrel are capped by short helices. Two loops on one side of the barrel form a large basic cleft which is a likely site for binding the acidic motifs of transcriptional activators. Many lethal or conditional lethal yeast point mutants map to this cleft, whereas no mutations with severe phenotype have been found in the linker region.

Topology and dynamics of the 10 kDa C-terminal domain of DnaK in solution.

Hsp70 molecular chaperones contain three distinct structural domains, a 44 kDa N-terminal ATPase domain, a 17 kDa peptide-binding domain, and a 10 kDa C-terminal domain. The ATPase and peptide binding domains are conserved in sequence and are functionally well characterized. The function of the 10 kDa variable C-terminal domain is less well understood. We have characterized the secondary structure and dynamics of the C-terminal domain from the Escherichia coli Hsp70, DnaK, in solution by high-resolution NMR. The domain was shown to be comprised of a rigid structure consisting of four helices and a flexible C-terminal subdomain of approximately 33 amino acids. The mobility of the flexible region is maintained in the context of the full-length protein and does not appear to be modulated by the nucleotide state. The flexibility of this region appears to be a conserved feature of Hsp70 architecture and may have important functional implications. We also developed a method to analyze 15N nuclear spin relaxation data, which allows us to extract amide bond vector directions relative to a unique diffusion axis. The extracted angles and rotational correlation times indicate that the helices form an elongated, bundle-like structure in solution.

Phosphotransfer and CheY-binding domains of the histidine autokinase CheA are joined by a flexible linker.

Multidimensional heteronuclear NMR techniques were applied to study a protein fragment of the histidine autokinase CheA from Escherichia coli. This fragment (CheA1-233) contains the phosphotransfer domain and the CheY-binding domain joined by a linker region. Comparison of chemical shift and NOE cross-peak patterns indicates that the structures of the two domains in CheA1-233 remain nearly the same as in the two individual domain fragments, CheA1-134 and CheA124-257. Relaxation properties of the backbone 15N nuclei were measured to study the rotational correlations of the two domains and properties of the linker region. Dynamics data were analyzed both by an isotropic motional model and an anisotropic motional model. The experimental T1 and T2 values, the derived rotational correlation times, and motional anisotropy are significantly different for the two domains, indicating the two domains reorient independently and the linker region is highly flexible. Dynamics data of CheA1-233 were also compared with those of CheA1-134. Our studies show that flexible domain linkers and extended and flexible terminal polypeptide chains can have significant effects on the motional properties of the adjacent structured regions. These observations suggest a model for the graded regulation of CheA autophosphorylation activity. In this model, the various activity states of the receptor are generated by controlling the access of the mean position of the kinase domain to the phosphotransfer domain. This would then modulate the diffusional encounter rate of the domains and hence activity over a wide and graded range of values.

Localized perturbations in CheY structure monitored by NMR identify a CheA binding interface.

Phosphotransfer between the autophosphorylating histidine kinase CheA and the response regulator CheY represents a crucial step in the bacterial chemotaxis signal transduction pathway. The 15N-1H correlation spectrum of CheY complexed with an amino-terminal fragment of CheA exhibits specific localized differences in chemical shifts when compared to the spectrum of uncomplexed CheY. When mapped onto the three-dimensional structure of CheY, these changes define a region distinct from the active site. A single amino-acid substitution within this binding region on CheY, alanine to valine at position 103, significantly decreases the affinity of CheY for CheA. The binding face described by these changes partially overlaps a flagellar switch binding surface previously defined by mutagenesis.

Nuclear magnetic resonance assignments and global fold of a CheY-binding domain in CheA, the chemotaxis-specific kinase of Escherichia coli.

CheA is the histidine autokinase in the Escherichia coli chemotaxis signal transduction pathway responsible for coupling of signals received by transmembrane receptors to the response regulators CheY and CheB. Here NMR spectroscopy is used to study a 14 kDa fragment of CheA, residues 124-257, that binds the response regulator CheY. Backbone atom resonance assignments were obtained by analysis of 3D HNCACB, 3D CBCA(CO)NH, and HNCO spectra, whereas side-chain assignments were obtained primarily by analysis of 3D H(CCO)NH, 3D C(CO)NH, 3D HCCH-TOCSY, and 3D 1H, 15N TOCSY-HSMQC spectra. NOE cross peak patterns and intensities as well as torsion angle restraints were used to determine the secondary structure, and a low-resolution structure was calculated by hybrid distance-geometry simulated annealing methods. The CheA124-257 fragment consists of four antiparallel beta strands and two helices, arranged in an "open-faced beta-sandwich" motif, as well as two unstructured ends that correspond to domain linkers in the full-length protein. The 15N-1H correlation spectrum of 15N-labeled CheA124-257 bound to unlabeled CheY shows specific localized changes that may correspond to a CheY-binding face on CheA.

NMR studies of the phosphotransfer domain of the histidine kinase CheA from Escherichia coli: assignments, secondary structure, general fold, and backbone dynamics.

Multidimensional heteronuclear NMR techniques were applied to study the phosphotransfer domain, residues 1-134, of the histidine kinase CheA, from Escherichia coli, which contains the site of autophosphorylation, His48. Assignments of the backbone amide groups and side chain protons are nearly complete. Our studies show that this protein fragment consists of five alpha-helices (A-E) connected by turns. Analysis of NOE distance restraints provided by two-dimensional (2D) 1H-1H and three-dimensional (3D) 15N-edited NOESY spectra using model building and structure calculations indicates that the five helices form an antiparallel helix bundle with near-neighbor connectivity. The amino-terminal four helices are proposed to be arranged in a right-handed manner with helix E packing against helices C and D. From ideal hydrophobic helical packing and structure calculations, the site of autophosphorylation, His48, is nearly fully exposed to the solvent. We measured the NMR relaxation properties of the backbone 15N nuclei using inverse detected two-dimensional NMR spectroscopy. The protein backbone dynamics studies show that CheA1-134 is formed into a tight and compact structure with very limited flexibilities both in helices and turns. Structural implications of titration and phosphorylation experiments are briefly discussed.

Signal transduction in chemotaxis. A propagating conformation change upon phosphorylation of CheY.

The CheY protein from Escherichia coli and Salmonella typhimurium are among the best characterized proteins of the receiver domain family of two component signal transduction systems in bacteria. Phosphorylation of CheY plays a central role in bacterial chemotaxis. However, it is not entirely clear how its state of phosphorylation contributes to its function. Genetic evidence suggests that CheY changes its conformation upon phosphorylation. We present evidence for this conformation change by comparing the NMR 15N-1H correlation spectra of CheY.Mg2+ complex and phospho-CheY in the presence of magnesium. Large changes in chemical shift are used as indicators of chemical changes and probable structural changes in the protein backbone. Our observations suggest that significant structural changes occur in CheY upon phosphorylation and that these changes are distinct from the changes produced by magnesium ion binding. In addition to residues Asn-59 and Gly-65 that are immediately adjacent to the site of phosphorylation at Asp-57, a large number of other residues show significant chemical shift changes as a result of phosphorylation. These include Met-17, Val-21, Asn-23, Gly-39, Met-60, Met-63, Asp-64, Leu-66, Glu-67, Leu-68, Leu-69, Met-85, Val-86, Thr-87, Ala-88, Asn-94, Val-107, Lys-109, Thr-112, Ala-113, Ala-114, and Asn-121. These results appear inconsistent with the recent suggestion that phosphorylation produces the same structural changes as magnesium binding (Bellsolell, L., Prieto, J., Serrano, L., and Coll, M. (1994) J. Mol. Biol. 238, 489-495). We find that some regions change overlap with a genetically defined motor binding face. We therefore propose that the conformation switch modulates the interaction of CheY with its target, the flagellar motor. Other regions also change, possibly reflecting the many different functions of CheY homologues.

Assignments, secondary structure, global fold, and dynamics of chemotaxis Y protein using three- and four-dimensional heteronuclear (13C,15N) NMR spectroscopy.

NMR spectroscopy has been used to study recombinant Escherichia coli CheY, a 128-residue protein involved in regulating bacterial chemotaxis. Heteronuclear three- and four-dimensional (3D and 4D) experiments have provided sequence-specific resonance assignments and quantitation of short-, medium-, and long-range distance restraints from nuclear Overhauser enhancement (NOE) intensities. These distance restraints were further supplemented with measurements of three-bond scalar coupling constants to define the local dihedral angles, and with the identification of amide protons undergoing slow solvent exchange from which hydrogen-bonding patterns were identified. The current model structure shows the same global fold of CheY as existing X-ray structures (Volz & Matsumura, 1991; Stock et al. 1993) with a (beta/alpha)5 motif of five parallel beta-strands at the central core surrounded by three alpha-helices on one face and with two on the opposite side. Heteronuclear 15N-1H relaxation experiments are interpreted to show portions of the protein structure in the Mg2+ binding loop are ill-defined because of slow motion (chemical exchange) on the NMR time scale. Moreover, the presence of Mg2+ disrupts the salt bridge between the highly conserved Lys-109 and Asp-57, the site of phosphorylation.

NMR study of the phosphate-binding loops of Thermus thermophilus elongation factor Tu.

The phosphoryl-binding loops in the guanosine diphosphate binding domain of elongation factor Tu were studied by 15N heteronuclear proton-observe NMR methods. Five proton resonances were found below 10.5 ppm. One of these was assigned to the amide group of Lys 24, which is a conserved residue in the phosphoryl-binding concensus loop of purine nucleotide binding proteins. The uncharacteristic downfield proton shift is attributed to a strong hydrogen bond with a phosphate oxygen. The amide protons from the homologous lysines in N-ras p21 [Redfield, A.G., & Papastavros, M.Z. (1990) Biochemistry 29, 3509-3514] and the catalytic domain of Escherichia coli elongation factor Tu [Lowry, D.F., Cool, R.H., Redfield, A.G., & Parmeggiani, A. (1991) Biochemistry 30, 10872-10877] also resonate downfield in similar positions. We propose that the downfield shift of this lysine amide proton is a spectral marker for this class of proteins. We also have studied the temperature dependence of the downfield resonances and find a possible conformation change at 40 degrees C.

NMR study of the phosphate-binding elements of Escherichia coli elongation factor Tu catalytic domain.

The phosphoryl-binding elements in the GDP-binding domain of elongation factor Tu were studied by heteronuclear proton observe methods. Five proton resonances were found below 10.5 ppm. Two of these were assigned to the amide groups of Lys 24 and Gly 83. These are conserved residues in each of the consensus sequences. Their uncharacteristic downfield proton shifts are attributed to strong hydrogen bonds to phosphate oxygens as for resonances in N-ras-p21 [Redfield, A. G., & Papastavros, M. Z. (1990) Biochemistry 29, 3509-3514]. The Lys 24 of the EF-Tu G-domain has nearly the same proton and nitrogen shifts as the corresponding Lys 16 in p21. These results suggest that this conserved lysine has a similar structural role in proteins in this class. The tentative Gly 83 resonance has no spectral analogue in p21. A mutant protein with His 84 changed to glycine was fully 15N-labeled and the proton resonance assigned to Gly 83 shifted downfield by 0.3 ppm, thereby supporting the assignment.

Assignment of the backbone 1H and 15N NMR resonances of bacteriophage T4 lysozyme.

The proton and nitrogen (15NH-H alpha-H beta) resonances of bacteriophage T4 lysozyme were assigned by 15N-aided 1H NMR. The assignments were directed from the backbone amide 1H-15N nuclei, with the heteronuclear single-multiple-quantum coherence (HSMQC) spectrum of uniformly 15N enriched protein serving as the master template for this work. The main-chain amide 1H-15N resonances and H alpha resonances were resolved and classified into 18 amino acid types by using HMQC and 15N-edited COSY measurements, respectively, of T4 lysozymes selectively enriched with one or more of alpha-15N-labeled Ala, Arg, Asn, Asp, Gly, Gln, Glu, Ile, Leu, Lys, Met, Phe, Ser, Thr, Trp, Tyr, or Val. The heteronuclear spectra were complemented by proton DQF-COSY and TOCSY spectra of unlabeled protein in H2O and D2O buffers, from which the H beta resonances of many residues were identified. The NOE cross peaks to almost every amide proton were resolved in 15N-edited NOESY spectra of the selectively 15N enriched protein samples. Residue specific assignments were determined by using NOE connectivities between protons in the 15NH-H alpha-H beta spin systems of known amino acid type. Additional assignments of the aromatic proton resonances were obtained from 1H NMR spectra of unlabeled and selectively deuterated protein samples. The secondary structure of T4 lysozyme indicated from a qualitative analysis of the NOESY data is consistent with the crystallographic model of the protein.