The crystal structure of a major dust mite allergen Der p 2, and its biological implications.

The crystal structure of the common house mite (Dermatophagoides sp.) Der p 2 allergen was solved at 2.15 A resolution using the MAD phasing technique, and refined to an R-factor of 0.209. The refined atomic model, which reveals an immunoglobulin-like tertiary fold, differs in important ways from the previously described NMR structure, because the two beta-sheets are significantly further apart and create an internal cavity, which is occupied by a hydrophobic ligand. This interaction is structurally reminiscent of the binding of a prenyl group by a regulatory protein, the Rho guanine nucleotide exchange inhibitor. The crystal structure suggests that binding of non-polar molecules may be essential to the physiological function of the Der p 2 protein.

Disorder-to-order transition of the active site of human class Pi glutathione transferase, GST P1-1.

Glutathione transferases comprise a large family of cellular detoxification enzymes that function by catalyzing the conjugation of glutathione (GSH) to electron-deficient centers on carcinogens and other toxins. NMR methods have been used to characterize the structure and dynamics of a human class pi enzyme, GST P1-1, in solution. Resonance assignments have been obtained for the unliganded enzyme and the GSH and S-hexylglutathione (GS-hexyl) complexes. Differences in chemical shifts between the GSH and GS-hexyl complexes suggest more extensive structural differences between these two enzyme-ligand complexes than detected by previous crystallographic methods. The NMR studies reported here clearly show that an alpha-helix (alpha2) within the GSH binding site exists in multiple conformations at physiological temperatures in the absence of ligand. A single conformation of alpha2 is induced by the presence of either GSH or GS-hexyl or a reduction in temperature to below 290 K. The large enthalpy of the transition ( approximately 150 kJ/mol) suggests a considerable structural rearrangement of the protein. The Gibbs free energy for the transition to the unfolded form is on the order of -4 to -6 kJ/mol at physiological temperatures (37 degrees C). This order-to-disorder transition contributes substantially to the overall thermodynamics of ligand binding and should be considered in the design of selective inhibitors of class pi glutathione transferases.

Changes in Ca2+ affinity upon activation of Agkistrodon piscivorus piscivorus phospholipase A2.

Changes in the affinity of calcium for phospholipase A2 from Agkistrodon piscivorus piscivorus during activation of the enzyme on the surface of phosphatidylcholine vesicles have been investigated by site-directed mutagenesis and fluorescence spectroscopy. Changes in fluorescence that occur during lipid binding and subsequent activation have been ascribed to each of the three individual Trp residues in the protein. This was accomplished by generating a panel of mutant proteins, each of which lacks one or more Trp residues. Both Trp21, which is found in the interfacial binding region, and Trp119 show changes in fluorescence upon protein binding to small unilamellar zwitterionic vesicles or large unilamellar vesicles containing sufficient anionic lipid. Trp31, which is near the Ca2+ binding loop, exhibits little change in fluorescence upon lipid bilayer binding. A change in the fluorescence of the protein also occurs during activation of the enzyme. These changes arise from residue Trp31 as well as residues Trp21 and Trp119. The calcium dependence of the fluorescence change of Trp31 indicates that the affinity of the enzyme for calcium increases at least 3 orders of magnitude upon activation. These studies suggest either that a change in conformation of the enzyme occurs upon activation or that the increase in calcium affinity reflects formation of a ternary complex of calcium, enzyme, and substrate.

Hydrogen exchange nuclear magnetic resonance spectroscopy mapping of antibody epitopes on the house dust mite allergen Der p 2.

New strategies for allergen-specific immunotherapy have focused on reducing IgE reactivity of purified recombinant allergens while maintaining T-cell epitopes. Previously, we showed that disrupting the disulfide bonds of the major house dust mite allergen Der p 2 resulted in 10-100-fold less skin test reactivity in mite-allergic subjects but did not change in vitro T-cell proliferative responses. To provide a more complete picture of the antigenic surface of Der p 2, we report here the identification of three epitopes using hydrogen protection nuclear magnetic resonance spectroscopy. The epitopes are defined by monoclonal antibodies that are able to inhibit IgE antibody binding to the allergen. Each monoclonal antibody affected the amide exchange rate of 2-3 continuous residues in different regions of Der p 2. Based on these data, a number of other residues were predicted to belong to each epitope, and this prediction was tested for monoclonal antibody 7A1 by generating alanine point mutants. The results indicate that only a small number of residues within the predicted epitope are functionally important for antibody binding. The molecular definition of these three epitopes will enable us to target limited positions for mutagenesis and to expand our studies of hypoallergenic variants for immunotherapy.

Ligand-induced changes in the structure and dynamics of a human class Mu glutathione S-transferase.

Glutathione transferases are detoxification enzymes that catalyze the addition of glutathione (GSH) to a wide variety of hydrophobic compounds. Although this group of enzymes has been extensively characterized by crystallographic studies, little is known about their dynamic properties. This study investigates the role of protein dynamics in the mechanism of a human class mu enzyme (GSTM2-2) by characterizing the motional properties of the unliganded enzyme, the enzyme-substrate (GSH) complex, an enzyme-product complex [S-(2,4-dinitrobenzyl)glutathione, GSDNB], and an enzyme-inhibitor complex (S-1-hexylglutathione, GSHEX). The kinetic on- and off-rates for these ligands are 10-20-fold lower than the diffusion limit, suggesting dynamic conformational heterogeneity of the active site. The off-rate of GSDNB is similar to the turnover number for its enzymatic formation, suggesting that product release is rate-limiting when 1-chloro-2,4-dinitrobenzene is the substrate. The dynamic properties of GSTM2-2 were investigated over a wide range of time scales using (15)N nuclear spin relaxation, residual dipolar couplings, and amide hydrogen-deuterium exchange rates. These data show that the majority of the protein backbone is rigid on the nanosecond to picosecond time scale for all forms of the enzyme. The presence of motion on the millisecond to microsecond time scale was detected for a small number of residues within the active site. These motions are likely to play a role in facilitating substrate binding and product release. The residual dipolar couplings also show that the conformation of the active site region is more open in solution than in the crystalline environment, further enhancing ligand accessibility to the active site. Amide hydrogen-deuterium exchange rates indicate a reduction in the dynamic properties of several residues near the active site due to the binding of ligand. GSH binding reduces the exchange rate of a number of residues in proximity to its binding site, while GSHEX causes a reduction in amide-exchange rates throughout the entire active site region. The location of the dinitrobenzene (DNB) ring in the GSDNB-GSTM2-2 complex was modeled using chemical shift changes that occur when GSDNB binds to the enzyme. The DNB ring makes a number of contacts with hydrophobic residues in the active site, including Met108. Replacement of Met108 with Ala increases the turnover number of the enzyme by a factor of 1.7.

A J(CH)-modulated 2D (HACACO)NH pulse scheme for quantitative measurement of (13)C(alpha)-(1)H(alpha) couplings in (15)N, (13)C-labeled proteins.

A triple-resonance pulse sequence is presented for the quantitative measurement of (1)H(alpha)-(13)C(alpha) single-bond couplings in (15)N, (13)C uniformly labeled proteins. This (1)J(CH)-modulated (HACACO)NH experiment yields (1)H(N)-(15)N-correlated 2D spectra in which the amplitude of each peak is modulated by the (1)H(alpha)-(13)C(alpha) J coupling of the preceding residue, (i - 1). The experiment is demonstrated on a 1.0 mM sample of Rho130, the 15-kDa RNA binding domain of E. coli Rho factor. The average error in the measured coupling constants was less than 0.8%. This sequence allows the measurement of the (1)J(CH )couplings from a proton-nitrogen HSQC without the need for assigning the H(alpha) and C(alpha) resonances.

Solution structure of the carboxyl terminus of a human class Mu glutathione S-transferase: NMR assignment strategies in large proteins.

Strategies to obtain the NMR assignments for the HN, N, CO, Calpha and Cbeta resonance frequencies for the human class mu glutathione-S-transferase GSTM2-2 are reported. These assignments were obtained with deuterated protein using a combination of scalar and dipolar connectivities and various specific labeling schemes. The large size of this protein (55 kDa, homodimer) necessitated the development of a novel pulse sequence and specific labeling strategies. These aided in the identification of residue type and were essential components in determining sequence specific assignments. These assignments were utilized in this study to characterize the structure and dynamics of the carboxy-terminal residues in the unliganded protein. Previous crystallographic studies of this enzyme in complex with glutathione suggested that this region may be disordered, and that this disorder may be essential for catalysis. Furthermore, in the related class alpha protein extensive changes in conformation of the C terminus are observed upon ligand binding. On the basis of the results presented here, the time-averaged conformation of the carboxyl terminus of unliganded GSTM2-2 is similar to that seen in the crystal structure. NOE patterns and 1H-15N heteronuclear nuclear Overhauser enhancements suggest that this region of the enzyme does not undergo motion on a rapid time scale.

Unambiguous correlations of backbone amide and aliphatic gamma resonances in deuterated proteins.

Two 3D NMR pulse sequences that correlate aliphatic gamma carbon resonance frequencies to amide proton and nitrogen chemical shifts in perdeuterated proteins are presented. The HN(COCACB)CG provides only interresidue connectivities (NH(i) and Cgamma(i-1)) while the HN(CACB)CG detects both the inter- and intraresidue (NH(i) and Cgamma(i) or Cgamma(i-1)) correlations. These two experiments are useful for sequential assignments and the identification of residue type from the Cgamma shifts. Spectra acquired on a perdeuterated 53-kDa protein illustrate the sensitivity and utility of these experiments.

Effect of deuteration on the accuracy of HN-HN distance constraints.

The effect of deuteration on the measurement of HN-HN distances in moderately sized (15 kDa) proteins is discussed. Data are presented for a 15 kDa protein which is 95% deuterated on the Halpha position, and partially (70%) deuterated at other aliphatic sites. Deuteration of the protein increases the signal intensity of HN-HN cross peaks in NOESY spectra such that dipolar couplings between protons 4-5 A apart are readily detected. Experimental data and computer simulations show that either perdeuteration or partial deuteration of the protein increases the accuracy of amide-amide distance constraints. Thus, partial deuteration can be used to obtain more accurate long-range distance constraints for structure determination by NMR.

Tertiary structure of the major house dust mite allergen Der p 2: sequential and structural homologies.

Sensitization to indoor allergens, especially those of the house dust mite, is strongly correlated with the development of asthma. We report the tertiary structure of the major house dust mite allergen, Der p 2, determined by NMR methods. The structure of Der p 2 is a beta-barrel and is composed of two three-stranded antiparallel beta-pleated sheets. This arrangement of beta-strands is similar to the immunoglobulin fold with respect to the orientation of the two sheets and the interactions of the strands. However, the three-dimensional structure of Der p 2 aligns equivalently with a number of proteins from different families within the immunoglobulin superfamily. The structural homology with the highest significance score from analysis by DALI is to Der f 2. Although Der p 2 and Der f 2 are 87% identical in amino acid sequence, they align in three dimensions rather poorly (4.85 A RMSD; Z-score, 8.58). This unexpected finding is likely due to the different solution conditions used during structure determination by NMR for both proteins. While the structural comparisons did not elucidate a clear homologue for the function of Der p 2 in mites, we report that Der p 2 is sequentially homologous to esr16. This is a protein from moths that is expressed coincident with molting. Thus, this homology has important ramifications for the study of mite allergy. The structure of Der p 2 provides a useful tool in the design of recombinant immunotherapeutics for the group 2 allergens.

Crystal structure of the RNA-binding domain from transcription termination factor rho.

Transcription termination factor rho is an ATP-dependent hexameric helicase found in most eubacterial species. The Escherichia coli rho monomer consists of two domains, an RNA-binding domain (residues 1-130) and an ATPase domain (residues 131-419). The ATPase domain is homologous to the beta subunit of F1-ATPase. Here, we report that the crystal structure of the RNA-binding domain of rho (rho130) at 1.55 A confirms that rho130 contains the oligosaccharide/oligonucleotide-binding (OB) fold, a five stranded beta-barrel. The beta-barrel of rho130 is also surprisingly similar to the N-terminal beta-barrel of F1 ATPase, extending the applicability of F1 ATPase as a structural model for hexameric rho.

The NMR structure of the RNA binding domain of E. coli rho factor suggests possible RNA-protein interactions.

Rho protein is an essential hexameric RNA-DNA helicase that binds nascent mRNA transcripts and terminates transcription in a wide variety of eubacterial species. The NMR solution structure of the RNA binding domain of rho, rho130, is presented. This structure consists of two sub-domains, an N-terminal three-helix bundle and a C-terminal beta-barrel that is structurally similar to the oligosaccharide/oligonucleotide binding (OB) fold. Chemical shift changes of rho130 upon RNA binding and previous mutagenetic analyses of intact rho suggest that residues Asp 60, Phe 62, Phe 64, and Arg 66 are critical for binding and support the hypothesis that ssRNA/ssDNA binding is localized in the beta-barrel sub-domain. On the basis of these studies and the tertiary structure of rho130, we propose that residues Asp 60, Phe 62, Phe 64, Arg 66, Tyr 80, Lys 105, and Arg 109 participate in RNA-protein interactions.

Expression and secondary structure determination by NMR methods of the major house dust mite allergen Der p 2.

There exists a strong correlation between asthma and sensitization to indoor allergens. This study reports on the secondary structure of the major house dust mite allergen Der p 2, determined using heteronuclear NMR methods. The DNA was subcloned from the yeast expression vector pSAY1 into the high yield bacterial expression vector pET21a, resulting in yields of 50 mg/liter. The recombinant protein was shown to have immunoreactivity comparable with that of the natural mite protein using competitive inhibition enzyme-linked immunosorbent assay (ELISA) and a modified monoclonal radioallergosorbent test (RAST). The secondary structure was determined by examining chemical shifts, short and long range NOESYs, JHN-HA coupling constants, and amide exchange rates. From these data, it is clear that Der p 2 is composed of beta-sheets and random coil. Based on long range distance constraints, a number of beta-strands were aligned into two three-stranded, anti-parallel beta-sheets.

Reduction in the amide hydrogen exchange rates of an anti-lysozyme Fv fragment due to formation of the Fv-lysozyme complex.

The Fv fragment of the monoclonal antibody D1.3 was expressed in bacteria. Standard triple resonance techniques were used to obtain the NMR resonance assignments for 211 out of 215 backbone 15N/NH atoms for D1.3 Fv. Using these assignments, hydrogen exchange rates are measured for 82 amide hydrogen atoms in D1.3 Fv free and bound to hen egg-white lysozyme. Upon binding to antigen, exchange rates are decreased for residues throughout the Fv. Many of these residues are located remote from the site of interaction with the antigen. These changes are larger than previously observed for the antigen portion of the complex. Evidently, the beta-sheet structure of the Fv propagates the effects of binding more efficiently than the antigen. These effects are compared between the three different polypeptide chains that make up the complex. These data suggest that reduced dynamics are a general feature of antibody binding to antigen.

Characteristics of DNA-tagged liposomes allowing their use in capillary-migration, sandwich-hybridization assays.

Liposomes that have been labeled externally with a DNA oligomer are used in a capillary-migration, sandwich-hybridization assay for specific DNA target sequences. The liposomes are used in a DNA detection scheme that produces visually observable results in 10 min. The preparation and covalent attachment of a thiol-activated 22-base oligomer to the external surface of dye-containing liposomes is described, and the specificity of the assay toward perfectly complementary target DNA is demonstrated. Several characteristics of DNA-tagged liposomes that allow the use of increased stringency during hybridization are evaluated. These include the effect of temperature, formamide, and salt concentration on both the sandwich-hybridization assay and the liposomes themselves. The effects of several components of a common hybridization solution are determined with regard to both assay performance and liposome stability. Using a solution of 0.02% sodium dodecyl sulfate in 3X standard saline citrate, a visual detection limit of 200 amol of target DNA was obtained.

1H, 15N and 13C resonance assignments and secondary structure determination of the RNA-binding domain of E.coli rho protein.

Protein fragments containing the RNA-binding domain of Escherichia coli rho protein have been over-expressed in E. coli. NMR spectra of the fragment containing residues 1-116 of rho protein (Rho116) show that a region of this protein is unfolded in solution. Addition of (dC)10 to this fragment stabilizes the folded form of the protein. The fragment comprising residues 1-130 of rho protein (Rho130) is found to be stably folded, both in absence and presence of nucleic acid. NMR studies of the complex of Rho130 with RNA and DNA oligonucleotides indicate that the binding-site size, affinity, and specificity of Rho130 are similar to those of intact rho protein; therefore, Rho130 is a suitable model of the RNA-binding domain of Rho protein. NMR line widths as well as titration experiments of Rho130 complexed with oligonucleotides of various lengths suggests that Rho130 forms oligomers in the presence of longer oligonucleotides. 1H, 15N and 13C resonance assignments were facilitated by the utilization of two pulse sequences, CN-NOESY and CCH-TOCSY. The secondary structure of unliganded Rho130 has been determined by NMR techniques, and it is clear that the RNA-binding domain of rho is more structurally similar to the cold shock domain than to the RNA recognition motif.

Rapid method for visual identification of specific DNA sequences based on DNA-tagged liposomes.

We describe a rapid method for visually determining specific DNA sequences at femtomole concentrations. Liposomes, encapsulating a red dye and labeled with oligonucleotide, were used in a capillary migration-sandwich hybridization assay. Capture probe was immobilized on nitrocellulose strips, and liposomes, migrating along each strip, formed a visually discernible band in the presence of target DNA. One femtomole of synthetic target sequence could be detected in < 10 min. Sufficiently stringent hybridization conditions can be used to allow the discrimination of a 10% mismatch sequence from perfectly complementary DNA. A 366-base PCR product was detected at 200 fmol.

Global changes in amide hydrogen exchange rates for a protein antigen in complex with three different antibodies.

The binding of anti-lysozyme monoclonal antibodies, D44.1 or D1.3, to their antigen reduces the rate of exchange for many amide hydrogens in lysozyme. The D44.1 antibody contacts a similar region of lysozyme to the HyHEL-5 antibody, while the D1.3 antibody binds to the side of lysozyme which is opposite to the HyHEL-5 and D44.1 epitopes. We compare the effects of binding these antibodies on amide hydrogen exchange rates in lysozyme. These comparisons suggest that there are regions of lysozyme that fluctuate in a coordinated manner such that the effects of binding can be propagated to regions that are distant from the epitope. The activation enthalpies for hydrogen exchange for 36 of the 126 amide hydrogens in lysozyme and for 25 of 126 lysozyme amide hydrogens in the lysozyme-D1.3 complex are also reported. These data suggest that the reduction in amide hydrogen exchange rates upon antibody binding reflect changes in the dynamics of the antigen. These changes contribute to a reduction in the specific heat capacity upon binding.

1H, 15N and 13C resonance assignments and secondary structure of group II phospholipase A2 from Agkistrodon piscivorus piscivorus: presence of an amino-terminal helix in solution.

1H, 15N and 13C resonance assignments are presented for the group II phospholipase A2 (PLA2) from Agkistrodon piscivorus piscivorus. The secondary structure of the enzyme has been inferred from an analysis of coupling constants, interproton distances, chemical shifts, and kinetics of amide exchange. Overall, the secondary structure of this PLA2 is similar to the crystal structure of the homologous group II human nonpancreatic secretory phospholipase [Scott, D.L., White, S.P., Browning, J.L., Rosa, J.J., Gelb, M.H. and Sigler, P.B. (1991) Science, 254, 1007-1010]. In the group I enzyme from porcine pancreas, the amino-terminal helix becomes fully ordered in the ternary complex of enzyme, lipid micelles and inhibitor. The formation of this helix is thought to be important for the increase in activity of phospholipases on aggregated substrates [Van den Berg, B., Tessari, M., Boelens, R., Dijkman, R., De Haas, G. H., Kaptein, R. and Verheij, H.M. (1995) Nature Strct. Biol., 2, 402-406]. However, the group II enzyme from Agkistrodon piscivorus piscivorus possesses a defined and well-positioned amino-terminal helix in the absence of substrate. Therefore, there is a clear difference between the conformation group I and group II enzymes in solution. These conformational differences suggest that formation of the amino-terminal helix is a necessary, but not sufficient, step in interfacial activation of phospholipases.