Backbone and side-chain assignment of the lipidated and non-lipidated forms of the meningococcal outer membrane protein LP2086.

LP2086 is a lipidated outer membrane protein from Neisseria meningitidis that elicits bactericidal antibodies and represents a promising vaccine candidate against meningococcal infections. Here we report the backbone and side-chain assignment for two forms of LP2086: non-lipidated in aqueous buffer and the lipidated protein in micellar solution.

Solution structure of N-TRADD and characterization of the interaction of N-TRADD and C-TRAF2, a key step in the TNFR1 signaling pathway.

TRADD is a multifunctional signaling adaptor protein that is recruited to TNFR1 upon ligand binding. The C-terminal of TRADD comprises the "death domain" that is responsible for association of TNFR1 and other death domain-containing proteins such as FADD and RIP. The N-terminal domain (N-TRADD) promotes the recruitment of TRAF2 to TNFR1 by binding to the C-terminal of TRAF2, leading to the activation of JNK/AP1 and NF-kappa B. The solution structure of N-TRADD was determined, revealing a novel protein fold. A combination of NMR, BIAcore, and mutagenesis experiments was used to help identify the site of interaction of N-TRADD with C-TRAF2, providing a framework for future attempts to selectively inhibit the TNF signaling pathways.

The three-dimensional structure of the vnd/NK-2 homeodomain-DNA complex by NMR spectroscopy.

The three-dimensional solution structure obtained by NMR of the complex formed between the uniformly singly15N and doubly13C/15N-labeled vnd/NK-2 homeodomain and its consensus 16 base-pair DNA binding sequence was determined. This work was carried out using the accepted repertoire of experiments augmented with a novel implementation of the water flipback technique to enhance signals from exchangeable amide protons. The results using this new technique confirm the existence of hydrogen bonding between the invariant Asn51 and the second adenine of the DNA binding sequence, as seen in crystal structures of other homeodomain-DNA complexes, but never before detected by NMR. Hydrogen bonding by Arg5 and Lys3 in the minor groove of the DNA appears to be responsible for two unusually upfield-shifted ribose H1' resonances. The DNA duplex is nearly straight and its structure is primarily that of B -DNA. A detailed comparison is presented for all available homeodomain-DNA structures including the vnd/NK-2 DNA complex, which demonstrates that homology is maintained in the protein structure, whereas for the orientation of the homeodomain relative to DNA, small but significant variations are observed. Interactions are described involving certain residues in specific positions of the homeodomain, namely Leu7, Thr41, and Gln50 of vnd/NK-2, where single amino acid residue mutations lead to dramatic developmental alterations. The availability of our previously determined three- dimensional structure of the vnd/NK-2 homeodomain in the absence of DNA allows us to assess structural changes in the homeodomain induced by DNA binding.

Site-directed mutations in the vnd/NK-2 homeodomain. Basis of variations in structure and sequence-specific DNA binding.

Secondary structures, DNA binding properties, and thermal denaturation behavior of six site-directed mutant homeodomains encoded by the vnd/NK-2 gene from Drosophila melanogaster are described. Three single site H52R, Y54M, and T56W mutations, two double site H52R/T56W and Y54M/T56W mutations, and one triple site H52R/Y54M/T56W mutation were investigated. These positions were chosen based on their variability across homeodomains displaying differences in secondary structure and DNA binding specificity. Multidimensional NMR, electrophoretic mobility shift assays, and circular dichroism spectropolarimetry studies were carried out on recombinant 80-amino acid residue proteins containing the homeodomain. Position 56, but more importantly position 56 in combination with position 52, plays an important role in determining the length of the recognition helix. The H52R mutation alone does not affect the length of this helix but does increase the thermal stability. Introduction of site mutations at positions 52 and 56 in vnd/NK-2 does not modify their high affinity binding to the 18-base pair DNA fragment containing the vnd/NK-2 consensus binding sequence, CAAGTG. Site mutations involving position 54 (Y54M, Y54M/T56W, and H52R/Y54M/T56W) all show a decrease of 1 order of magnitude in their binding affinity. The roles in structure and sequence specificity of individual atom-atom interactions are described.

Interactions of the vnd/NK-2 homeodomain with DNA by nuclear magnetic resonance spectroscopy: basis of binding specificity.

The interactions responsible for the nucleotide sequence-specific binding of the vnd/NK-2 homeodomain of Drosophila melanogaster to its consensus DNA binding site have been identified. A three-dimensional structure of the vnd/NK-2 homeodomain-DNA complex is presented, with emphasis on the structure of regions of observed protein-DNA contacts. This structure is based on protein-DNA distance restraints derived from NMR data, along with homology modeling, solvated molecular dynamics, and results from methylation and ethylation interference experiments. Helix III of the homeodomain binds in the major groove of the DNA and the N-terminal arm binds in the minor groove, in analogy with other homeodomain-DNA complexes whose structures have been reported. The vnd/NK-2 homeodomain recognizes the unusual DNA consensus sequence 5'-CAAGTG-3'. The roles in sequence specificity and strength of binding of individual amino acid residues that make contact with the DNA are described. We show, based primarily on the observed protein-DNA contacts, that the interaction of Y54 with the DNA is the major determinant of this uncommon nucleotide binding specificity in the vnd/NK-2 homeodomain-DNA complex.

The three-dimensional solution structure of the NK-2 homeodomain from Drosophila.

We describe the NMR determination of the three-dimensional structure of a 77 amino acid residue protein, which consists of the 60 residue NK-2 homeodomain from Drosophila melanogaster and adjacent amino acid residues. The NK-2 homeodomain protein is part of a 723 amino acid residue protein which is expressed early in embryonic development in part of the central nervous system. NK-2 was characterized using both a natural abundance and a uniformly 15N enriched sample by two-dimensional and three-dimensional NMR experiments. The average root-mean-square deviation for 30 structures for residues 8 to 53 is 0.40 A for the backbone heavy-atoms and 0.72 A for the backbone and side-chain heavy-atoms. These structures were obtained from 986 NOE-derived upper and lower bound restraints. The three-dimensional structure contains three helices which consist of homeodomain amino acid residues 10 to 22, 28 to 38 and 42 to 52, as well as a turn between helix II and III, characteristic of homeodomains. Residues 53 to 60 of the DNA recognition helix are not fully ordered in the absence of DNA. In the free state this segment adopts a flexible but helix-like structure between residues 53 and 56 and is disordered from residues 57 to 60 although, as shown previously, the helix elongates by eight residues upon binding to DNA. The role of variable residues 52, 54 and 56 in determining the structure and flexibility of the recognition helix, as well as the stability of the NK-2 homeodomain as manifested by its thermal denaturation, are discussed.

Elongation of helix III of the NK-2 homeodomain upon binding to DNA: a secondary structure study by NMR.

The secondary structure of the homeodomain encoded by the NK-2 gene from Drosophila melanogaster, in both the free and DNA-bound states, was determined in solution using two- and three-dimensional (2D and 3D) NMR spectroscopy. Proton and 15N studies were carried out on a 77 amino acid residue protein that contains the homeodomain, which was synthesized in Escherichia coli. On the basis of NOE connectivities, vicinal coupling constants, and proton-deuterium exchange behavior, three helical segments were found that consist of homeodomain amino acid residues 10-22, 28-38, and 42-52 for the protein in the absence of DNA. The major structural differences between free NK-2 and other homeodomains are the increased internal mobility of the second helix and the shorter length of the third helix, also termed the recognition helix. Despite this shorter helix, NK-2 exhibits high-affinity binding to DNA compared to other homeodomains (kD = 2.0 x 10(-10) M; L.-H. Wang and M. Nirenberg, unpublished results). The formation of the complex of NK-2 with the duplex DNA (TGTGTCAAGTG-GCTGT) significantly increases the thermal stability of the protein. The Tm increases from 25 degrees C (free NK-2) to > 47 degrees C (DNA-bound NK-2). Also, a dramatic increase in the length of helix III is observed. In the absence of DNA, the DNA recognition helix is 11 amino acid residues long (residues 42-52), whereas in the presence of DNA, the length of this helix extends to 19 amino acids (residues 42-60).(ABSTRACT TRUNCATED AT 250 WORDS)

Spectroscopic studies of arsenic(III) binding to Escherichia coli RI methyltransferase and to two mutants, C223S and W183F.

The interactions of an arsenic (III) reagent, (CH3)2AsSCH2CONH2, with two Escherichia coli RI methyltransferase mutants, W183F and C223S, have been studied by phosphorescence, optically detected magnetic resonance, and fluorescence spectroscopy. The phosphorescence spectrum of the W183F mutant containing only one tryptophan at position 225 reveals a single 0,0-band that is red-shifted by 9.8 nm upon binding of As(III). Fluorescence titration of W183F with (CH3)2AsSCH2CONH2 produces a large tryptophan fluorescence quenching. Analysis of the quenching data points to a single high-affinity As(III) binding site that is associated with the fluorescence quenching. Triplet-state kinetic measurements performed on the perturbed tryptophan show large reductions in the lifetimes of the triplet sublevels, especially that of the T chi sublevel. As(III) binding to the enzyme at a site very close to the Trp225 residue induces an external heavy-atom effect, showing that the perturber atom is in van der Waals contact with the indole chromophore. In the case of the C223S mutant, a single tryptophan 0,0-band also is observed in the phosphorescence spectrum, but no change occurs upon addition of the As(III) reagent. Fluorescence titration of C223S with As(III) shows essentially no quenching of tryptophan fluorescence, in contrast with W183F. These results, along with previous triplet-state and biochemical studies on the wild-type enzyme [Tsao, D. H.H., & Maki, A. H. (1991) Biochemistry 30, 4565-4572], show that As(III) binds with high affinity to the Cys223 residue and that the Trp225 side chain is located close enough to that of Cys223 to produce a heavy-atom perturbation when As(III) is bound.

Optically detected magnetic resonance study of the interaction of an arsenic(III) derivative of cacodylic acid with EcoRI methyl transferase.

The interaction of the enzyme Escherichia coli RI methyl transferase (methylase) with an arsenic(III) derivative of cacodylic acid has been investigated by optical detection of triplet-state magnetic resonance (ODMR) spectroscopy in zero applied magnetic field. The reactive derivative (CH3)2AsSR is formed by the reduction of cacodylate by a thiol. The As(III) derivative binds to the enzyme by mercaptide exchange with a cysteine (Cys) residue located close to a tryptophan (Trp) site. The arsenical binding selectively induces an external heavy-atom effect, perturbing the nearby Trp residue in the enzyme. Zero-field splittings (ZFS) and total decay rate constants of the individual triplet-state sublevels of the Trp residue in the presence and absence of perturbation by As(III) have been determined. The perturbed Trp shows a large reduction in the overall decay lifetime compared with unperturbed Trp residue, exhibiting a high selectively for the Tx sublevel. This selectivity suggests that the As atom lies in the xz plane of the principal magnetic axis system of Trp, but not directly along the z (out-of-plane) axis. The accessibility of this enzyme binding site to the arsenical is decreased upon forming a ternary complex of methylase with sinefungin and a DNA oligomer, d[GCGAA(BrU)(BrU)CGC], containing two 5-bromouracil (BrU) bases in place of thymine within the hexadeoxynucleotide recognition sequence. This result indicates that the arsenical binding site in methylase which produces the Trp heavy-atom effect is protected from this ligand by ternary complex formation or the enzyme undergoes a conformation change, removing the Cys from the Trp site. This protection is also observed in fluorescence quenching experiments.(ABSTRACT TRUNCATED AT 250 WORDS)

Energy transfer in complexes of E. coli single-stranded DNA-binding protein with single-stranded poly-(2-thiouridylic acid).

The complexes of point-mutated Escherichia coli single-stranded DNA-binding protein (Eco SSB) with poly-(2-thiouridylic acid) (poly S2U) have been studied by optical detection of magnetic resonance spectroscopy (ODMR). Previous work has determined that two of four tryptophan (Trp) residues in Eco SSB undergo stacking interactions with nucleic acid bases. Selective photoexcitation of S2U bases was performed and subsequent triplet----triplet energy transfer from S2U to nearby Trp residues in the protein took place. The zero-field splitting (ZFS) parameters and sublevel kinetics were determined for each Trp residue sensitized by S2U. The sublevel lifetimes of the two sensitized residues are similar to those of normal Trp. The ZFS parameters, on the other hand, show a dramatic reduction relative to those of the uncomplexed protein, implying a more polarizable environment for the sensitized Trp residues and/or charge transfer interactions with the S2U bases.

Triplet state properties of tryptophan residues in complexes of mutated Escherichia coli single-stranded DNA binding proteins with single-stranded polynucleotides.

Complexes of point-mutated E. coli single-stranded DNA-binding protein (Eco SSB) with homopolynucleotides have been investigated by optical detection of magnetic resonance (ODMR) of the triplet state of tryptophan (Trp) residues. Investigation of the individual sublevel kinetics of the lowest triplet state of Trp residues 40 and 54 in the poly (dT) complex of Eco SSB-W88F,W135F (a mutant protein whose Trp residues at positions 88 and 135 have been substituted by Phe) shows that Trp 54 is the most affected residue upon stacking with thymine bases, confirming previous results based on SSB mutants having single Trp----Phe substitutions. (Zang, L. H., A. H. Maki, J. B. Murphy, and J. W. Chase. 1987. Biophys. J. 52:867-872). The Tx sublevel of Trp 54 shows a fourfold increase in the decay rate constant, as well as an increase in its populating rate constant by selective spin-orbit coupling. The two nonradiative sublevels show no change in lifetime, relative to unstacked Trp. For Trp 40, a weaker perturbation of Tx by thymine results in a sublevel lifetime about one-half that of normal Trp. Trp54 displays a 2[E]transition of negative polarity in the double mutant SSB complex with Poly (dT), but gives a vanishingly weak [D] - [E] signal, thus implying that the steady-state sublevel populations of Tx and Tz are nearly equal in this residue. Poly (5-BrU) induces the largest red-shift of the Eco SSB-W88F,W135F Trp phosphorescence 0,0-band of all polynucleotides investigated. Its phosphorescence decay fits well to two exponential components of 1.02 and 0.12 s, with no contribution from long-lived Trp residues. This behavior provides convincing evidence that both Trp 40 and 54 are perturbed by stacking with brominated uridine. The observed decrease in the Trp [D] values further confirms the stacking of the Trp residues with 5-BrU. Wave-length-selected ODMR experiments conducted on the [D[ + [E] transition of Eco SSB-W88F,W135F complexed with poly(5HgU) indicate the presence of multiple heavy atom-perturbed sites. Measurements made on poly (5-HgU) which each of its 4 Trp residues has been replaced in turn by Phe demonstrate that Trp 40 and 54 are the only Trp residues undergoing stacking with nucleotide bases, as previously proposed.

Variation of hinge interocclusal clearance and modifying mechanisms.

On the basis of Newtonian principles of applied mechanics, rotation around the mandibular hinge axis has been explored by separating this rotation from translation of the mandibular hinge axis. After quantitative comparison, it appears that hinge rotation is the primary physiologic movement of the mandible, and that the Hanau quint provides compensatory factors in facilitating hinge jaw movement. However, an unguided opening and closing of the mouth usually consists of rotation and translation that are six-dimensional in nature and very difficult to solve quantitatively without idealization and differentiation. With an accurate three-dimensional image-measuring system, such as computerized axial tomography, it should be possible to apply this hypothesis clinically.

Measurability of radiographic images.

Projective distortion has been recognized since the first attempts were made to measure images on x-ray films. However, the nature of this distortion has not been thoroughly investigated by the dental profession. Part of the difficulty in addressing the problem is the necessity of the researcher's having knowledge and training in nonmetric mathematical thinking. To demonstrate the nonmetric nature of projective transformation, seven precision line gauges were made of glass tubes filled with steel balls 1/8 inch in diameter and were attached to a skull at various locations. Cephalometric x-ray films of the prepared skull with gauges in place were taken to simulate lateral and other views. The image lengths of the gauges were directly measured from the x-ray films. The results showed that the image length can be longer, shorter, or the same as the object gauge and cannot be predicted, corrected, or compensated for from the images alone. Linear projective transformation measured in this study ranged from 7.32 percent elongation to 69.63 percent foreshortening. Thus, it is illogical to measure radiographic images without restrictions. The basic limitation of measuring radiographic images on x-ray film is that the parallel relation must be established between the object line (or plane) and the image line (or plane). Technical restrictions should be established as a convention by those who have had the most experience in using radiographic measurements.

Relationship of the incisive papilla to the maxillary central incisors.

The average distance between the most anterior point of the maxillary central incisors and the most posterior point of the incisive papilla was 12.454 mm with a standard deviation of 3.867 mm. This distance was measured when these two points were projected on a plane which was parallel to the reference plane formed by the tips of three interdental papillae; i.e., the papilla between two central incisors (A), between the first and second molars on the right side (R), and on the left side (L). The average error incurred due to inconsistency of the method employed was less than 3% or less than 0.372 mm for the position of the central incisor. It is believed that the application of this anatomic relation can provide a reliable point for arranging and checking the position of the anterior maxillary teeth for complete dentures.

Geometric analysis of tooth arrangement.

Based on the principles of solid geometry and projection geometry, a mathematical system can be used to indicate any positional change of tooth arrangement on a trial denture. To summarize: 1. When you move a tooth, you have to know whether you move the tooth toward the patient's left side or right side (x), upward or downward (y), anteriorly or posteriorly (z), and how many millimeters in each component dimension. If rotatory movements are involved, you must know whether the tooth rotates around the mesiodistal axis (+/-M), around the faciolingual axis (+/-F), or around the gingivo-occlusal axis (+/-G). You must know the degrees of rotation around each of the component axes and whether the movement is clockwise or counterclockwise. Most students will easily follow this systemic approach and readily understand the complexity of the problem.