Sequential 1H NMR assignments and secondary structure of the kringle domain from urokinase.

The sequence-specific 1H NMR assignments of the 89-residue recombinant kringle domain from human urokinase are presented. These were achieved primarily by utilizing TOCSY and NOESY spectra in conjunction with COSY spectra recorded at 500 MHz and 600 MHz. Regular secondary structure elements have been derived from a qualitative interpretation of nuclear Overhauser enhancement, JNH alpha coupling constant, and amide proton exchange data. Two helices have been identified. One helix, involving Ser40-Gly46, corresponds to that reported for t-PA kringle 2 (Byeon et al., 1991), but does not exist in other kringles with known structures. The second helix, in the region Asn26-Gln33, is thus far unique to the urokinase kringle. Three antiparallel beta-sheets and three tight turns have also been identified, which correspond exactly to those identified in t-PA kringle 2 both in solution and in the crystalline state (de Vos et al., 1992). Despite the very different ligand binding properties of the urokinase kringle, NOE data indicate that the tertiary fold of the molecule conforms closely to that found for other kringles.     

Sequential 1H NMR assignments and secondary structure of an IgG-binding domain from protein G

Protein G is a member of a class of cell surface bacterial proteins from Streptococcus that bind IgG with high affinity. A fragment of molecular mass 6988, which retains IgG-binding activity, has been generated by proteolytic digestion and analyzed by 1H NMR. Two-dimensional DQF-COSY, TOCSY, and NOESY spectra have been employed to assign the 1H NMR spectrum of the peptide. Elements of regular secondary structure have been identified by using nuclear Overhauser enhancement, coupling constant, and amide proton exchange data. The secondary structure consists of a central alpha-helix (Ala28-Val44), flanked by two portions of beta-sheet (Val5-Val26 and Asp45-Lys62). This is a fundamentally different arrangement of secondary structure from that of protein A, which is made up of three consecutive alpha-helices in free solution (Torigoe et al., 1990). We conclude that the molecular mechanisms underlying the association of protein A and protein G with IgG are different.     

Proton NMR assignments and secondary structure of the snake venom protein echistatin.

The snake venom protein echistatin is a potent inhibitor of platelet aggregation. The inhibitory properties of echistatin have been attributed to the Arg-Gly-Asp sequence at residues 24-26. In this paper, sequence-specific nuclear magnetic resonance assignments are presented for the proton resonances of echistatin in water. The single-chain protein contains 49 amino acids and 4 cystine bridges. All of the backbone amide, C alpha H, and side-chain resonances, except for the eta-NH of the arginines, have been assigned. The secondary structure of the protein was characterized from the pattern of nuclear Overhauser enhancements, from the identification of slowly exchanging amide protons, from 3JC alpha H-NH coupling constants, and from circular dichroism studies. The data suggest that the secondary structure consists of a type I beta-turn, a short beta-hairpin, and a short, irregular, antiparallel beta-sheet and that the Arg-Gly-Asp sequence is in a flexible loop connecting two strands of the distorted antiparallel beta-sheet.     

Chemical shift assignments and secondary structure of the Grb2 SH2 domain by heteronuclear NMR spectroscopy

Summary The growth factor receptor-bound protein-2 (Grb2) is an adaptor protein that mediates signal transduction pathways. Chemical shift assignments were obtained for the SH2 domain of Grb2 by heteronuclear NMR spectroscopy, employing the uniformly ¹³C-/¹⁵N-enriched protein as well as the protein containing selectively ¹⁵N-enriched amino acids. Using the Chemical Shift Index (CSI) method, the chemical shift indices of four nuclei, ¹H, ¹³C, ¹³C and ¹³CO, were used to derive the secondary structure of the protein. Nuclear Overhauser enhancements (NOEs) were then employed to confirm the secondary structure. The CSI results were compared to the secondary structural elements predicted for the Grb2 SH2 domain from a sequence alignment [Lee et al. (1994) Structure, 2, 423–438]. The core structure of the SH2 domain contains an antiparallel -sheet and two -helices. In general, the secondary structural elements determined from the CSI method agree well with those predicted from the sequence alignment.Abbreviations crk viral p47^gag-crk - EGF epidermal growth factor - GAP GTPase-activating protein - PI3K phosphatidylinositol-3-kinase - PLC- phospholipase-C-, shc, src homologous and collagen - src sarcoma family of nonreceptor tyrosine kinase     

Sequential 1H and 15N NMR assignments and secondary structure of a recombinant anti-digoxin antibody VL domain.

A uniformly 15N-labeled recombinant light-chain variable (VL) domain from the anti-digoxin antibody 26-10 has been investigated by heteronuclear two-dimensional (2D) and three-dimensional (3D) NMR spectroscopy. Complementary homonuclear 2D NMR studies of the unlabeled VL domain were also performed. Sequence-specific assignments for 97% of the main-chain and 70% of the side-chain proton resonances have been obtained. Patterns of nuclear Overhauser effects observed in 2D NOESY, 3D NOESY-HSQC, and 3D NOESY-TOCSY-HSQC spectra afford a detailed characterization of the VL domain secondary structure in solution. The observed secondary structure--a nine-stranded antiparallel beta-barrel--corresponds to that observed crystallographically for VL domains involved in quaternary associations. The locations of slowly exchanging amide protons have been discerned from a 2D TOCSY spectrum recorded after dissolving the protein in 2H2O. Strands B, C, E, and F are found to be particularly stable. The possible consequences of these results for domain-domain interactions are discussed.     

Two-dimensional NMR studies of Kazal proteinase inhibitors. 1. Sequence-specific assignments and secondary structure of turkey ovomucoid third domain

Two-dimensional proton NMR experiments have been used to sequentially assign resonances to all of the peptide backbone protons of turkey ovomucoid third domain (OMTKY3) except those of the N-terminal alpha-amino group whose signal was not resolved owing to exchange with the solvent. Assignments also have been made for more than 80% of the side-chain protons. Two-dimensional chemical shift correlated spectroscopy (COSY), relayed coherence transfer spectroscopy (RELAY), and two-dimensional homonuclear Hartmann-Hahn spectroscopy (HOHAHA) were used to identify the spin systems of almost half of the residues prior to sequential assignment. Assignments were based on two-dimensional nuclear Overhauser enhancements observed between adjacent residues. The secondary structure of OMTKY3 in solution was determined from additional assigned NOESY cross-peaks; it closely resembles the secondary structure determined by single-crystal X-ray diffraction of OMTKY3 in complex with Streptomyces griseus proteinase B [Fujinaga, M., Read, R.J., Sielecki, A., Ardelt, W., Laskowski, M., Jr., & James, M.N.G. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 4868-4872]. The NMR data provide evidence for three slowly exchanging amide protons that were not identified as hydrogen-bond donors in the crystal structure.     

Backbone assignments and secondary structure of the Escherichia coli enzyme-II mannitol A domain determined by heteronuclear three-dimensional NMR spectroscopy.

This report presents the backbone assignments and the secondary structure determination of the A domain of the Escherichia coli mannitol transport protein, enzyme-IImtl. The backbone resonances were partially assigned using three-dimensional heteronuclear 1H NOE 1H-15N single-quantum coherence (15N NOESY-HSQC) spectroscopy and three-dimensional heteronuclear 1H total correlation 1H-15N single-quantum coherence (15N TOCSY-HSQC) spectroscopy on uniformly 15N enriched protein. Triple-resonance experiments on uniformly 15N/13C enriched protein were necessary to complete the backbone assignments, due to overlapping 1H and 15N frequencies. Data obtained from three-dimensional 1H-15N-13C alpha correlation experiments (HNCA and HN(CO)CA), a three-dimensional 1H-15N-13CO correlation experiment (HNCO), and a three-dimensional 1H alpha-13C alpha-13CO correlation experiment (COCAH) were combined using SNARF software, and yielded the assignments of virtually all observed backbone resonances. Determination of the secondary structure of IIAmtl is based upon NOE information from the 15N NOESY-HSQC and the 1H alpha and 13C alpha secondary chemical shifts. The resulting secondary structure is considerably different from that reported for IIAglc of E. coli and Bacillus subtilis determined by NMR and X-ray.     

Sequence-specific 1H NMR assignments and secondary structure of porcine motilin

The solution structure of the 22-residue peptide hormone motilin has been studied by circular dichroism and two-dimensional 1H nuclear magnetic resonance spectroscopy. Circular dichroism spectra indicate the presence of alpha-helical secondary structure in aqueous solution, and the secondary structure can be stabilized with hexafluoro-2-propanol. Sequence-specific assignments of the proton NMR spectrum of porcine motilin in 30% hexafluoro-2-propanol have been made by using two-dimensional NMR techniques. All backbone proton resonances (NH and alpha CH) and most of the side-chain resonances have been assigned by using double-quantum-filtered COSY, RELAYED-COSY, and NOESY experiments. Simulations of NOESY cross-peak intensities as a function of mixing time indicate that spin diffusion has a relatively small effect in peptides the size of motilin, thereby allowing the use of long mixing times to confidently make assignments and delineate secondary structure. Sequential alpha CH-NH and NH-NH NOESY connectivities were observed over a significant portion of the length of the peptide. A number of medium-range NOESY cross-peaks indicate that the peptide is folded into alpha-helix from Glu9 to Lys20, which agrees favorably with the 50% helical content determined from CD measurements. The intensities of selected NOESY cross-peaks relative to corresponding diagonal peaks were used to estimate a rotational correlation time of approximately 2.5 ns for the peptide, indicating that the peptide exists as a monomer in solution under the conditions used here.     

Two-dimensional NMR studies on des-pentapeptide-insulin. Proton resonance assignments and secondary structure analysis

The shortened analogue of insulin, des-(B26-B30)-pentapeptide insulin, has been characterized by two-dimensional 1H NMR. The 1H resonance assignments and the secondary structure in water solution are discussed The results indicate that the secondary structure in solution is very similar to that reported for the crystalline state. A high flexibility of both A and B chains is observed. Of the two conformations seen in the 2-Zn insulin crystals and indicated as molecules 1 and 2 (Chinese nomenclature), the structure of the analogue is more similar to that of molecule 1.     

1H NMR studies of the glucocorticoid receptor DNA-binding domain: sequential assignments and identification of secondary structure elements

Two protein fragments containing the DNA-binding domain (DBD) of the glucocorticoid receptor (GR) have been studied by two-dimensional 1H NMR spectroscopy. The two peptides (93 and 115 residues, respectively) contain a common segment corresponding to residues C440-I519 of the rat GR or residues C421-I500 of the human GR and include two Zn-binding "finger" domains. The structures of this segment are almost identical in the two protein fragments, as judged from chemical shifts and sequential NOE connectivities. More than 90% of all observable 1H resonances within a 71-residue segment encompassing C440-R510 (rat GR) could be sequentially assigned by standard techniques, and stereospecific assignments could be made for the methyl groups in four valine residues within this segment. Sequential NOE connectivities indicate several elements of secondary structure including two alpha-helical segments consisting of residues S459-E469 and P493-G504, a type I reverse turn between residues R479 and C482, a type II reverse turn between residues L475 and G478, and several regions of extended peptide conformation. No evidence for alpha-helical conformation was found within the two putative zinc-finger domains, indicating that the structures of these domains differ from that of TFIIIA-type zinc fingers. The observation of some very slowly exchanging amide protons in the N-terminal (CI) domain of the DBD in combination with slow rotation of the Y452 aromatic ring indicates that this domain has a restricted conformational flexibility compared to the C-terminal (CII) domain. We also observe several long-range NOE connectivities within C440-R510, suggesting that the sequential assignments presented here will provide a basis for a complete structure determination of this segment of the GR.     

Sequence-specific 1H NMR assignments and secondary structure of eglin c

Sequence-specific nuclear magnetic resonance assignments were obtained for eglin c, a polypeptide inhibitor of the granulocytic proteinases elastase and cathepsin G and some other proteinases. The protein consists of a single polypeptide chain of 70 residues. All proton resonances were assigned except for some labile protons of arginine side chains. The patterns of nuclear Overhauser enhancements and coupling constants and the observation of slow hydrogen exchange were used to characterize the secondary structure of the protein. The results indicate that the solution structure of the free inhibitor is very similar to the crystal structure reported for the same protein in the complex with subtilisin Carlsberg. However, a part of the binding loop seems to have a significantly different conformation in the free protein.     

Heteronuclear NMR assignments and secondary structure of the coiled coil trimerization domain from cartilage matrix protein in oxidized and reduced forms.

The C-terminal oligomerization domain of chicken cartilage matrix protein is a trimeric coiled coil comprised of three identical 43-residue chains. NMR spectra of the protein show equivalent magnetic environments for each monomer, indicating a parallel coiled coil structure with complete threefold symmetry. Sequence-specific assignments for 1H-, 15N-, and 13C-NMR resonances have been obtained from 2D 1H NOESY and TOCSY spectra, and from 3D HNCA, 15N NOESY-HSQC, and HCCH-TOCSY spectra. A stretch of alpha-helix encompassing five heptad repeats (35 residues) has been identified from intra-chain HN-HN and HN-H alpha NOE connectivities. 3JHNH alpha coupling constants, and chemical shift indices. The alpha-helix begins immediately downstream of inter-chain disulfide bonds between residues Cys 5 and Cys 7, and extends to near the C-terminus of the molecule. The threefold symmetry of the molecule is maintained when the inter-chain disulfide bonds that flank the N-terminus of the coiled coil are reduced. Residues Ile 21 through Glu 36 show conserved chemical shifts and NOE connectivities, as well as strong protection from solvent exchange in the oxidized and reduced forms of the protein. By contrast, residues Ile 10 through Val 17 show pronounced chemical shift differences between the oxidized and reduced protein. Strong chemical exchange NOEs between HN resonances and water indicate solvent exchange on time scales faster than 10 s, and suggests a dynamic fraying of the N-terminus of the coiled coil upon reduction of the disulfide bonds. Possible roles for the disulfide crosslinks of the oligomerization domain in the function of cartilage matrix protein are proposed.     

Solution structure, hydrodynamics and thermodynamics of the UvrB C-terminal domain.

The solution structure, thermodynamic stability and hydrodynamic properties of the 55-residue C-terminal domain of UvrB that interacts with UvrC during excision repair in E. coli have been determined using a combination of high resolution NMR, ultracentrifugation, 15N NMR relaxation, gel permeation, NMR diffusion, circular dichroism and differential scanning calorimetry. The subunit molecular weight is 7,438 kDa., compared with 14.5+/-1.0 kDa. determined by equilibrium sedimentation, indicating a dimeric structure. The structure determined from NMR showed a stable dimer of anti-parallel helical hairpins that associate in an unusual manner, with a small and hydrophobic interface. The Stokes radius of the protein decreases from a high plateau value (ca. 22 A) at protein concentrations greater than 4 microM to about 18 A at concentrations less than 0.1 microM. The concentration and temperature-dependence of the far UV circular dichroism show that the protein is thermally stable (Tm ca. 71.5 degrees C at 36 microM). The simplest model consistent with these data was a dimer dissociating into folded monomers that then unfolds co-operatively. The van't Hoff enthalpy and dissociation constant for both transition was derived by fitting, with deltaH1=23 kJ mol(-1). K1(298)=0.4 microM and deltaH2= 184 kJ mol(-1). This is in good agreement with direct calorimetric analysis of the thermal unfolding of the protein, which gave a calorimetric enthalpy change of 181 kJ mol(-1) and a van't Hoff enthalpy change of 354 kJ mol(-1), confirming the dimer to monomer unfolding. The thermodynamic data can be reconciled with the observed mode of dimerisation. 15N NMR relaxation measurements at 14.1 T and 11.75 T confirmed that the protein behaves as an asymmetric dimer at mM concentrations, with a flexible N-terminal linker for attachment to the remainder of the UvrB protein. The role of dimerisation of this domain in the excision repair mechanism is discussed.     

Kringle-2 domain of the tissue-type plasminogen activator. 1H-NMR assignments and secondary structure

A recombinant 90-residue polypeptide fragment containing the three-loop kringle-2 domain of human tissue-type plasminogen activator (t-PA) has been studied by two-dimensional 1H-NMR spectroscopy at 500 MHz. Complete sequence-specific resonance assignments were derived. Overall, the kringle exhibits a compact, folded conformation with more than 50% of the residues in irregular structures. Elements of secondary structure were identified from sequential, medium- and long-range dipolar (Overhauser) interproton interactions. These identifications were corroborated by analysis of spin-spin scalar 3J alpha N splittings and identification of backbone amide NH protons exhibiting retarded 1H/2H exchange in 2H2O. Three antiparallel beta-sheets and six tight turns were located. In addition, one short alpha-helical region was found in the Ser43-Ala44-Gln44a-Ala44b-Leu44c-Gly45+ ++ segment; this region contains three-residue insertions unique to the t-PA and urokinase kringles. Although the secondary structure of the t-PA kringle 2 in solution is in overall agreement with that observed in the crystallographic structure of the prothrombin kringle 1 [Tulinsky, A., Park, C.H. & Skrzypczak-Jankun, E. (1988) J. Mol. Biol. 202, 885-901], the alpha-helical segment and other details of the secondary structure differ somewhat from the prothrombin homolog.     

Sequence-specific 1H NMR assignments and determination of the secondary structure for the activation domain isolated from pancreatic procarboxypeptidase B

Nearly complete sequence-specific 1H NMR assignments are presented for amino acid residues 3-81 in the 81-residue globular activation domain of porcine pancreatic procarboxypeptidase B isolated after limited tryptic proteolysis of the zymogen. These resonance assignments are consistent with the chemically determined amino acid sequence. Regular secondary structure elements were identified from nuclear Overhauser effects and the sequence locations of slowly exchanging backbone amide protons. The molecule contains two alpha-helices, including residues 20-30 and approximately residues 58-72, and a three-stranded antiparallel beta-sheet with the individual strands extending approximately from 12 to 17, 50 to 55, and 75 to 77. The identification of these secondary structures and a preliminary analysis of additional long-range NOE distance constraints show that isolated activation domain B forms a stable structure with the typical traits of a globular protein. The data presented here are the basis for the determination of the complete three-dimensional structure of activation domain B, which is currently in progress.     

NMR assignment and secondary structure of the C-terminal DNA binding domain of Arabidopsis thaliana VERNALIZATION1

VERNALIZATION1 (VRN1) is a multidomain DNA binding protein from Arabidopsis thaliana that is required for the acceleration of flowering time in response to prolonged cold treatment; a physiological process called vernalization. VRN1 is a 39 kDa protein comprised of two B3 domains flanking a putative nuclear localization sequence and two PEST domains. Here we report the ¹H, ¹³C and ¹⁵N resonance assignments of the 134 residue C-terminal region of VRN1, comprising a B3 DNA binding domain of the REM family and an upstream region that is highly conserved among VRN1 homologs from other dicotyledonous plant species.     

The isomerization of the UvrB-DNA preincision complex couples the UvrB and UvrC activities

In Escherichia coli nucleotide excision repair, the UvrB-DNA preincision complex plays a key role, linking adduct recognition to incision. We previously showed that the efficiency of the incision is inversely related to the stability of the preincision complex. We postulated that an isomerization reaction converts [UvrB-DNA], stable but incompetent for incision, into the [UvrB-DNA]' complex, unstable and competent for incision. Here, we identify two parameters, negative supercoiling and presence of a nick at the fifth phosphodiester bond 3' to the lesion, that accelerate the isomerization leading to an increasing incision efficiency. We also show that the [UvrB-DNA] complex is more resistant to a salt concentration increase than the [UvrB-DNA]' complex. Finally, we report that the [UvrB-DNA]' is recognized by UvrC. These data suggest that the isomerization reaction leads to an exposure of single-stranded DNA around the lesion. This newly exposed single-stranded DNA serves as a binding site and substrate for the UvrC endonuclease. We propose that the isomerization reaction is responsible for coupling UvrB and UvrC activities and that this reaction corresponds to the binding of ATP.     

1H NMR studies of echistatin in solution. Sequential resonance assignments and secondary structure.

Two-dimensional 1H-NMR methods have been used to obtain complete proton resonance assignments for the 49-residue protein echistatin from the viper Echis carinatus. The protein in solution contains only a small amount of regular secondary structure with four very short beta-strands. These beta-strands form two short segments of antiparallel beta-sheet, as evidenced by the observed cross-strand NOE. The first two strands are connected with a tight reverse turn, whereas the remaining two strands are linked together by an 11-residue loop forming a so-called hairpin. The tripeptide unit Arg-Gly-Asp, responsible for the binding of echistatin to the fibrinogen receptor glycoprotein GPIIb/IIIa, is located at the tip of this very hydrophilic loop.     

Two-dimensional NMR studies of Kazal proteinase inhibitors. 2. Sequence-specific assignments and secondary structure of reactive site modified turkey ovomucoid third domain

The solution structure of modified turkey ovomucoid third domain (OMTKY3*) was investigated by high-resolution proton NMR techniques. OMTKY3* was obtained by enzymatic hydrolysis of the scissile reactive site peptide bond (Leu18-Glu19) in turkey ovomucoid third domain (OMTKY3). All of the backbone proton resonances were assigned to sequence-specific residues except the NH's of Leu1 and Glu19, which were not observed. Over 80% of the side-chain protons also were assigned. The secondary structure of OMTKY3*, as determined from assigned NOESY cross-peaks and identification of slowly exchanging amide protons, contains antiparallel beta-sheet consisting of three strands (residues 21-25, 28-32, and 49-54), one alpha-helix (residues 33-44), and one reverse turn (residues 26-28). This secondary structure closely resembles that of OMTKY3 in solution [Robertson, A. D., Westler, W. M., & Markley, J. L. (1988) Biochemistry (preceding paper in this issue)]. On the other hand, changes in the tertiary structure of the protein near to and remote from the cleavage site are indicated by differences in the chemical shifts of numerous backbone protons of OMTKY3 and OMTKY3*.