Monomer-trimer equilibrium of the ectodomain of SIV gp41: insight into the mechanism of peptide inhibition of HIV infection.

The monomer-trimer equilibrium of the ectodomain of SIV gp41 (residues 27-149, e-gp41) has been characterized by analytical ultracentrifugation, circular dichroism (CD), and NMR spectroscopy. Based on analytical ultracentrifugation experiments performed at different rotor speeds and protein concentrations, the equilibrium association constant for the SIV e-gp41 trimer is 3.1 x 10(11) M(-2).

Autoprocessing of HIV-1 protease is tightly coupled to protein folding.

In the Gag-Pol polyprotein of HIV-1, the 99-amino acid protease is flanked at its N-terminus by a transframe region (TFR) composed of the transframe octapeptide (TFP) and 48 amino acids of the p6pol, separated by a protease cleavage site. The intact precursor (TFP-p6pol-PR) has very low dimer stability relative to that of the mature enzyme and exhibits negligible levels of stable tertiary structure. Thus, the TFR functions by destabilizing the native structure, unlike proregions found in zymogen forms of monomeric aspartic proteases.

Crystal structure of cyanovirin-N, a potent HIV-inactivating protein, shows unexpected domain swapping.

The crystal structure of cyanovirin-N (CV-N), a protein with potent antiviral activity, was solved at 1.5 A resolution by molecular replacement using as the search model the solution structure previously determined by NMR. The crystals belong to the space group P3221 with one monomer of CV-N in each asymmetric unit.

Solution structure of the 40,000 Mr phosphoryl transfer complex between the N-terminal domain of enzyme I and HPr.

The solution structure of the first protein-protein complex of the bacterial phosphoenolpyruvate: sugar phosphotransferase system between the N-terminal domain of enzyme I (EIN) and the histidine-containing phosphocarrier protein HPr has been determined by NMR spectroscopy, including the use of residual dipolar couplings that provide long-range structural information. The complex between EIN and HPr is a classical example of surface complementarity, involving an essentially all helical interface, comprising helices 2, 2', 3 and 4 of the alpha-subdomain of EIN and helices 1 and 2 of HPr, that requires virtually no changes in conformation of the components relative to that in their respective free states. The specificity of the complex is dependent on the correct placement of both van der Waals and electrostatic contacts.

Is human thioredoxin monomeric or dimeric?

We have examined the molecular weight and rotational correlation time of human thioredoxin by analytical ultracentrifugation and NMR spectroscopy, respectively. Two variants of human thioredoxin were studied, namely human thioredoxin identical in amino acid sequence to the one whose NMR structure we previously determined (C62A, C69A, C73A, M74T) and human thioredoxin (C62A, C69A, C73A, M74) containing the wild-type amino acid methionine at position 74. In both cases, the experimental data indicate that the predominant species is monomeric and we find no evidence for the existence of a well-defined dimeric form as was observed in the recently reported crystal structure (Weichsel et al.

3D NMR experiments for measuring 15N relaxation data of large proteins: application to the 44 kDa ectodomain of SIV gp41.

A suite of 3D NMR experiments for measuring 15N-¿1H¿ NOE, 15N T1, and 15N T1rho values in large proteins, uniformly labeled with 15N and 13C, is presented. These experiments are designed for proteins that exhibit extensive spectral overlap in the 2D 1H-15N HSQC spectrum. The pulse sequences are readily applicable to perdeuterated samples, which increases the spectral resolution and signal-to-noise ratio, thereby permitting the characterization of protein dynamics to be extended to larger protein systems.

Disordered water within a hydrophobic protein cavity visualized by x-ray crystallography.

Water in the hydrophobic cavity of human interleukin 1beta, which was detected by NMR spectroscopy but was invisible by high resolution x-ray crystallography, has been mapped quantitatively by measurement and phasing of all of the low resolution x-ray diffraction data from a single crystal. Phases for the low resolution data were refined by iterative density modification of an initial flat solvent model outside the envelope of the atomic model. The refinement was restrained by the condition that the map of the difference between the electron density distribution in the full unit cell and that of the atomic model be flat within the envelope of the well ordered protein structure.

Solution structure of the His12 --> Cys mutant of the N-terminal zinc binding domain of HIV-1 integrase complexed to cadmium.

The solution structure of His12 --> Cys mutant of the N-terminal zinc binding domain (residues 1-55; IN(1-55)) of HIV-1 integrase complexed to cadmium has been solved by multidimensional heteronuclear NMR spectroscopy. The overall structure is very similar to that of the wild-type N-terminal domain complexed to zinc. In contrast to the wild-type domain, however, which exists in two interconverting conformational states arising from different modes of coordination of the two histidine side chains to the metal, the cadmium complex of the His12 --> Cys mutant exists in only a single form at low pH.

NMR structure determination of proteins and protein complexes larger than 20 kDa.

Recent advances in multidimensional nuclear magnetic resonance methodology to obtain 1H, 15N and 13C resonance assignments, interproton distance and torsion angle restraints, and restraints that characterize long-range order, coupled with new methods of structure refinement and novel methods for reducing linewidths, have permitted three-dimensional solution structures of single chain proteins in excess of 250 residues and multimeric protein in excess of 40 kDa to be solved. These developments may permit the determination by nuclear magnetic resonance of macromolecular structures up to molecular weights in the 50-60 kDa range, thereby bringing into reach numerous systems of considerable biological interest, including a large variety of protein-protein and protein-nucleic acid complexes.

Solution structure of the cellular factor BAF responsible for protecting retroviral DNA from autointegration.

The solution structure of the human barrier-to-autointegration factor, BAF, a 21,000 Mr dimer, has been solved by NMR, including extensive use of dipolar couplings which provide a priori long range structural information. BAF is a highly evolutionarily conserved DNA binding protein that is responsible for inhibiting autointegration of retroviral DNA, thereby promoting integration of retroviral DNA into the host chromosome. BAF is largely helical, and each subunit is composed of five helices.

Determination of three-bond 1H3'-31P couplings in nucleic acids and protein-nucleic acid complexes by quantitative J correlation spectroscopy.

A new sensitive two-dimensional quantitative J correlation experiment is described for measuring 3JH3'-P couplings in nucleic acids and protein-nucleic acid complexes. The method is based on measuring the change in intensity of the 1H-1H cross peaks in a constant-time 1H-1H COSY experiment which occurs in the presence and absence of 3JH3'-P dephasing during the constant-time evolution period. For protein-nucleic acid complexes where the protein is 13C-labeled but the nucleic acid is not, 12C-filtering is readily achieved by the application of a series of 13C purge pulses during the constant time evolution period without any loss of signal-to-noise of the nucleic acid cross peaks.

Three-dimensional solution structure of the 44 kDa ectodomain of SIV gp41.

The solution structure of the ectodomain of simian immunodeficiency virus (SIV) gp41 (e-gp41), consisting of residues 27-149, has been determined by multidimensional heteronuclear NMR spectroscopy. SIV e-gp41 is a symmetric 44 kDa trimer with each subunit consisting of antiparallel N-terminal (residues 30-80) and C-terminal (residues 107-147) helices connected by a 26 residue loop (residues 81-106). The N-terminal helices of each subunit form a parallel coiled-coil structure in the interior of the complex which is surrounded by the C-terminal helices located on the exterior of the complex.

Solution structure of cyanovirin-N, a potent HIV-inactivating protein.

The solution structure of cyanovirin-N, a potent 11,000 Mr HIV-inactivating protein that binds with high affinity and specificity to the HIV surface envelope protein gp120, has been solved by nuclear magnetic resonance spectroscopy, including extensive use of dipolar couplings which provide a priori long range structural information. Cyanovirin-N is an elongated, largely beta-sheet protein that displays internal two-fold pseudosymmetry. The two sequence repeats (residues 1-50 and 51-101) share 32% sequence identity and superimpose with a backbone atomic root-mean-square difference of 1.

A robust method for determining the magnitude of the fully asymmetric alignment tensor of oriented macromolecules in the absence of structural information.

It has recently been shown that the degree of alignment of macromolecules in an aqueous dilute liquid crystalline medium of bicelles is sufficient to permit accurate values of residual 15N-1H, 13C-1H, and 13Calpha-C' dipolar couplings to be obtained on a routine basis, thereby providing potentially unique long-range structural information. To make use of this information in macromolecular structure determination, the magnitude of the axial and rhombic components of the molecular alignment tensor must be determined. This can be achieved by taking advantage of the fact that different, fixed-distance internuclear vector types are differently distributed relative to the alignment tensor.

Minor groove-binding architectural proteins: structure, function, and DNA recognition.

To date, high-resolution structures have been solved for five different architectural proteins complexed to their DNA target sites. These include TATA-box-binding protein, integration host factor (IHF), high mobility group I(Y)[HMG I(Y)], and the HMG-box-containing proteins SRY and LEF-1. Each of these proteins interacts with DNA exclusively through minor groove contacts and alters DNA conformation.

New methods of structure refinement for macromolecular structure determination by NMR.

Recent advances in multidimensional NMR methodology have permitted solution structures of proteins in excess of 250 residues to be solved. In this paper, we discuss several methods of structure refinement that promise to increase the accuracy of macromolecular structures determined by NMR. These methods include the use of a conformational database potential and direct refinement against three-bond coupling constants, secondary 13C shifts, 1H shifts, T1/T2 ratios, and residual dipolar couplings.

The solution structure of the Leu22-->Val mutant AREA DNA binding domain complexed with a TGATAG core element defines a role for hydrophobic packing in the determination of specificity.

The seemingly innocuous leucine-to-valine mutation at position 22 of the AREA DNA binding domain results in dramatic changes in the in vivo expression profile of genes controlled by this GATA transcription factor. This is associated with a preference of the Leu22-->Val mutant for TGATAG sites over (A/C)GATAG sites. Quantitative gel retardation assays confirm this observation and show that the Leu22-->Val mutant AREA DNA binding domain has a approximately 30-fold lower affinity than the wild-type domain for a 13 base-pair oligonucleotide containing the wild-type CGATAG target.

The solution structure of a fungal AREA protein-DNA complex: an alternative binding mode for the basic carboxyl tail of GATA factors.

The solution structure of a complex between the DNA binding domain of a fungal GATA factor and a 13 base-pair oligonucleotide containing its physiologically relevant CGATAG target sequence has been determined by multidimensional nuclear magnetic resonance spectroscopy. The AREA DNA binding domain, from Aspergillus nidulans, possesses a single Cys2-Cys2 zinc finger module and a basic C-terminal tail, which recognize the CGATAG element via an extensive network of hydrophobic interactions with the bases in the major groove and numerous non-specific contacts along the sugar-phosphate backbone. The zinc finger core of the AREA DNA binding domain has the same global fold as that of the C-terminal DNA binding domain of chicken GATA-1.

Direct structure refinement against residual dipolar couplings in the presence of rhombicity of unknown magnitude.

Residual dipolar couplings arising from small degrees of alignment of molecules in a magnetic field provide unique long-range structural information. The potential of this approach for structure refinement has recently been demonstrated for a protein-DNA complex in which the magnetic susceptibility tensor was axially symmetric. For most macromolecules and macromolecular complexes, however, axial symmetry cannot be assumed.

An efficient and cost-effective isotope labeling protocol for proteins expressed in Escherichia coli.

A cost-effective protocol for uniform 15N and/or 13C isotope labeling of bacterially expressed proteins is presented. Unlike most standard protocols, cells are initially grown in a medium containing nutrients at natural abundance and isotopically labeled nutrients are only supplied at the later stages of growth and during protein expression. This permits the accumulation of a large cell mass without the need to employ expensive isotopically labeled nutrients.

Tautomeric state and pKa of the phosphorylated active site histidine in the N-terminal domain of enzyme I of the Escherichia coli phosphoenolpyruvate:sugar phosphotransferase system.

The phosphorylated form of the N-terminal domain of enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system of Escherichia coli has been investigated by one-bond and long-range 1H-15N correlation spectroscopy. The active site His 189 is phosphorylated at the Nepsilon2 position and has a pKa of 7.3, which is one pH unit higher than that of unphosphorylated His 189.

Determining the structures of large proteins and protein complexes by NMR.

Recent advances in multidimensional NMR methodology to obtain 1H, 15N and 13C resonance assignments, interproton-distance and torsion-angle restraints, and restraints that characterize long-range order have, coupled with new methods of structure refinement, permitted solution structure of proteins in excess of 250 residues to be solved. These developments may permit the determination by NMR of the structures of macromolecules up to 50-60kDa, thereby bringing into reach numerous systems of considerable biological interest, including a large variety of protein-protein and protein-nucleic-acid complexes.

Solution structure of the Mu end DNA-binding ibeta subdomain of phage Mu transposase: modular DNA recognition by two tethered domains.

The phage Mu transposase (MuA) binds to the ends of the Mu genome during the assembly of higher order nucleoprotein complexes. We investigate the structure and function of the MuA end-binding domain (Ibetagamma). The three-dimensional solution structure of the Ibeta subdomain (residues 77-174) has been determined using multidimensional NMR spectroscopy.

Correction of the NMR structure of the ETS1/DNA complex.

The ETS family of transcription factors consists of a group of proteins that share a highly conserved 85 amino acid DNA-binding domain (DBD). This family recognizes a consensus sequence rich in purine bases with a central GGAA motif. A comparison of the published three-dimensional structures of the DBD/DNA complexes of ETS1 by NMR [Werner et al.

Design of an expression system for detecting folded protein domains and mapping macromolecular interactions by NMR.

Two protein expression vectors have been designed for the preparation of NMR samples. The vectors encode the immunoglobulin-binding domain of streptococcal protein G (GB1 domain) linked to the N-terminus of the desired proteins. This fusion strategy takes advantage of the small size, stable fold, and high bacterial expression capability of the GB1 domain to allow direct NMR spectroscopic analysis of the fusion protein by 1H-15N correlation spectroscopy.