Biophysical consequences of remodeling the neutral side chains of rhamnogalacturonan I in tubers of transgenic potatoes

Two lines of transgenic potato (Solanum tuberosum L.) plants modified in their cell wall structure were characterized and compared to wild type with regard to biomechanical properties in order to assign functional roles to the particular cell wall polysaccharides that were targeted by the genetic changes. The targeted polymer was rhamnogalacturonan I (RG-I), a complex pectic polysaccharide comprised of mainly neutral oligosaccharide side chains attached to a backbone of alternating rhamnosyl and galacturonosyl units. Tuber rhamnogalacturonan I molecules from the two transformed lines are reduced in linear galactans and branched arabinans, respectively. The transformed tuber tissues were found to be more brittle when subjected to uniaxial compression and the side-chain truncation was found to be correlated with the physical properties of the tissue. Interpretation of the force–deflection curves was aided by a mathematical model that describes the contribution of the cellulose microfibrils, and the results lead to the proposition that the pectic matrix plays a role in transmitting stresses to the load-bearing cellulose microfibrils and that even small changes to the rheological properties of the matrix have consequences for the biophysical properties of the wall.     

Determination of 3J(H infi supN,C infi sup′ ) coupling constants in proteins with the C′-FIDS method

Summary We introduce the C-FIDS-¹H,¹⁵N-HSQC experiment, a new method for the determination of ³J(H _infi ^supN ,C _infi ^sup ) coupling constants in proteins, yielding information about the torsional angle . It relies on the ¹H,¹⁵N-HSQC or HNCO experiment, two of the the most sensitive heteronuclear correlation experiments for isotopically labeled proteins. A set of three ¹H,¹⁵N-HSQC or HNCO spectra are recorded: a reference experiment in which the carbonyl spins are decoupled during t₁ and t₂, a second experiment in which they are decoupled exclusively during t₁ and a third one in which they are coupled in t₁ as well as t₂. The last experiment yields an E.COSY-type pattern from which the ²J(H _infi ^supN ,C _infi-1 ^sup ) and ¹J(N_i,C _infi-1 ^sup ) coupling constants can be extracted. By comparison of the coupled multiplet (obtained from the second experiment) with the decoupled multiplet (obtained from the first experiment) convoluted with the ²J(H _infi ^supN ,C _infi-1 ^sup ) coupling, the ³J(H _infi ^supN ,C _infi ^sup ) coupling can be found in a one-parameter fitting procedure. The method is demonstrated for the protein rhodniin, containing 103 amino acids. Systematic errors due to differential relaxation are small for ⁿJ(H^N,C) couplings in biomacromolecules of the size currently under NMR spectroscopic investigation.     

A competitive labelling method for determining the ionization constants and reactivity of individual histidine residues in proteins. The histidines of α-chymotrypsin

A competitive labelling method (Kaplan et al., 1971), using tritiated 1-fluoro-2,4-dinitrobenzene as the labelling reagent, is described for determining the ionization constants and reactivities of individual histidine residues in proteins. When this method was applied to the two histidines of alpha-chymotrypsin, histidine-57 was found to have pK(a) 6.8 and a reactivity ten times that of alpha-N-acetyl-l-histidine. Histidine-40 had pK(a) 6.7 and a reactivity approximately six times that of alpha-N-acetyl-l-histidine. Between pH7.5 and 8 the reactivities of both histidines decrease simultaneously to approximately that of alpha-N-acetyl-l-histidine. The high reactivities of the histidines are attributed to hydrogen bonding, which increases the nucleophilicity of the imidazole ring. The sharp decrease in reactivity between pH7.5 and 8 is attributed to a conformational change that disrupts the hydrogen bonding by these residues. The reactivity data support the proposal of a charge-relay mechanism involving histidine-57 (Blow et al., 1969), which makes serine-195 more nucleophilic but indicates that this system is fully operative only in the enzyme-substate complex.     

Alternative E.COSY techniques for the measurement of 3J(C i ′ −1,C i β ) and 3 J(H i N ,C i β ) coupling constants in proteins

Experiments are proposed for the measurement of the vicinal coupling constants between -carbons and either amide protons of the same or carbonyl carbons of the preceding amino acid residue in 13C/15N-labeled proteins. Both couplings depend on the backbone torsional angle . The three-dimensional pulse sequences give rise to E.COSY-like multiplet patterns in which heteronuclear one-bond couplings separate the doublet components corresponding to the two spin states of the respective passive nuclei. Thus, in contrast to previously published pulse schemes which employed the homonuclear 1J(C,C) interaction, difficulties due to overlap of spectral regions of active and passive spins are avoided. A major drawback of the novel sequences is their limited sensitivity. Nevertheless, application to Desulfovibrio vulgaris flavodoxin yielded coupling constants for more than 85% of all non-glycine and non-proline residues.     

A method for the estimation of χ1 torsion angles in proteins

Summary A method for estimating CH-CH coupling constants from the shape and fine structure of NH-CH fingerprint-region cross peaks of COSY spectra is presented. Spectral simulations have been used to analyse the effect of variations in ³J_NH-CH, ³J_CH-CH, linewidths and digital resolution on the appearance of NH-CH COSY cross peaks. On the basis of these simulations a set of rules for broadly categorising experimental NH-CH cross peaks according to CH-CH coupling constants has been devised. The method has been applied to the analysis of NH-CH cross peaks of hen lysozyme. The results are compared to previous measurements of CH-CH coupling constants using E.COSY techniques.     

How do side chains orient globally in protein structures?

An angle Omega is defined to serve as a metric for global side-chain orientations, which reflects the orientation of the side chain relative to the radial vector from the center of the protein to an amino acid. The side-chain orientations of buried residues exhibit characteristically different orientations than do exposed residues, in both monomeric and dimeric structures. Overall, buried side chains point mostly inward, whereas surface side chains tend to point outward from the surface. This difference in behavior also correlates well with the residue hydrophobicity; so a global side-chain orientation can be viewed as a direct structural manifestation of hydrophobicity. When various solvent-accessible layers are considered, the behavior is relatively continuous between centrally located and exposed residues. In the case of interfacial residues between subunits, there are statistically significant differences between exposed residues and interface residues for ALA, ARG, ASN, ASP, GLU, HIS, LYS, THR, VAL, MET, PRO, and overall the interface residues have an increased tendency to point inward. Presumably, these substantial differences in orientations of side chains may be a manifestation of hydrophobic forces.     

Mutations that replace aromatic side chains promote aggregation of the Alzheimer's Aβ peptide

The aggregation of polypeptides into amyloid fibrils is associated with a number of human diseases. Because these fibrils--or intermediates on the aggregation pathway--play important roles in the etiology of disease, considerable effort has been expended to understand which features of the amino acid sequence promote aggregation. One feature suspected to direct aggregation is the π-stacking of aromatic residues. Such π-stacking interactions have also been proposed as the targets for various aromatic compounds that are known to inhibit aggregation. In the case of Alzheimer's disease, the aromatic side chains Phe19 and Phe20 in the wild-type amyloid beta (Aβ) peptide have been implicated. To explicitly test whether the aromaticity of these side chains plays a role in aggregation, we replaced these two phenylalanine side chains with leucines or isoleucines. These residues have similar sizes and hydrophobicities as Phe but are not capable of π-stacking. Thioflavin-T fluorescence and electron microscopy demonstrate that replacement of residues 19 and 20 by Leu or Ile did not prevent aggregation, but rather enhanced amyloid formation. Further experiments showed that aromatic inhibitors of aggregation are as effective against Ile- and Leu-substituted versions of Aβ42 as they are against wild-type Aβ. These results suggest that aromatic π-stacking interactions are not critical for Aβ aggregation or for the inhibition of Aβ aggregation.     

NMR detection of side chain–side chain hydrogen bonding interactions in 13C/15N-labeled proteins

We describe the direct observation of side chain–side chain hydrogen bonding interactions in proteins with sensitivity-enhanced NMR spectroscopy. Specifically, the remote correlation between the guanidinium nitrogen ¹⁵N of arginine 71, which serves as the hydrogen donor, and the acceptor carboxylate carbon ¹³CO₂ of aspartate 100 in a 12 kDa protein, human FKBP12, is detected via the trans-hydrogen bond ^3h J _{N CO2} coupling by employing a novel HNCO-type experiment, soft CPD-HNCO. The ^3h J _{N CO2} coupling constant appears to be even smaller than the average value of backbone ^3h J _NC couplings, consistent with more extensive local dynamics in protein side chains. The identification of trans-hydrogen bond J-couplings between protein side chains should provide useful markers for monitoring hydrogen bonding interactions that contribute to the stability of protein folds, to alignments within enzyme active sites and to recognition events at macromolecular interfaces.     

Quantitative J correlation methods for the accurate measurement of 13C′-13Cαdipolar couplings in proteins

Methods are described for the precise and accurate measurement of one-bond dipolar (13)C'-(13)C(alpha) couplings in weakly aligned proteins. The experiments are based on the principle of quantitative J correlation, where (1)J(C'C(alpha)) (or (1)J(C'C(alpha)) + 1D(C'C(alpha)) is measured from the relative intensity of two interleaved 3D TROSY-HN(CO)CA or 3DTROSY-HNCO spectra recorded with dephasing intervals of zero (reference spectrum) and approximately 3/(2(1)J(C'C(alpha)) (attenuated spectrum). In analogy to other quantitative J correlation techniques, the random error in the measured (1)J(C'C(alpha)) value is inversely proportional to the signal-to-noise ratio in the reference spectrum. It is shown that for weakly aligned proteins, with the magnitude of the alignment tensor of D(a)(NH) < or = 10-15 Hz, the systematic errors are typically negligible. The methods are demonstrated for the third IgG-binding domain of protein G (GB3) and a-synuclein in complex with a detergent micelle, where errors in (1)D(C'C(alpha)) of less than 0.1 Hz and ca. 0.2 Hz,respectively, are estimated. Remarkably, the dipolar couplings determined for GB3 are in even better agreement with the recently refined 1.1-angstroms X-ray structure than the input (13)C'-(13)C(alpha) couplings used for the refinement.     

Measurement of two-bond JCOHα coupling constants in proteins uniformly enriched with13C

Summary A simple E.COSY type technique is described for measurement of two-bond J_COH coupling constants in proteins that are uniformly enriched with¹³C. The method has been used to measure²J_COH for 132 residues in the proteins calmodulin and staphylococcal nuclease having non-overlapping H–C correlations. Measured²J_COH coupling constants fall in the 0 to –9.5 Hz range. A separate experiment, measuring the accuracy of these values, indicates a root-mean-square error of 1 Hz. Comparison of the J couplings with the dihedral back bone angles from crystallographic studies confirms a weak but statistically significant correlation between the dihedral angle and the magnitude of²J_COH, but also indicates that parameters other than have a significant effect on the value of the coupling.     

Characterization of the insertase for β-barrel proteins of the outer mitochondrial membrane

The TOB–SAM complex is an essential component of the mitochondrial outer membrane that mediates the insertion of β-barrel precursor proteins into the membrane. We report here its isolation and determine its size, composition, and structural organization. The complex from Neurospora crassa was composed of Tob55–Sam50, Tob38–Sam35, and Tob37–Sam37 in a stoichiometry of 1:1:1 and had a molecular mass of 140 kD. A very minor fraction of the purified complex was associated with one Mdm10 protein. Using molecular homology modeling for Tob55 and cryoelectron microscopy reconstructions of the TOB complex, we present a model of the TOB–SAM complex that integrates biochemical and structural data. We discuss our results and the structural model in the context of a possible mechanism of the TOB insertase.     

Immobilization of cellulase through its carbohydrate side chains — A rationale for its recovery and reuse

The major types of components of cellulase [see 1,4-(1, 3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] have been adsorbed onto concanavalin A immobilized on Sepharose 4B, suggesting that they are glycoproteins. These components were covalently coupled to cyanogen bromide-activated Sepharose after aminoalkylation of their periodate-oxidized carbohydrate side chains to provide additional points of attachment of the enzyme to the support. Although there was only a 9% recovery of starting avicelase activity, the immobilized enzyme catalysed the hydrolysis of insoluble cellulose to glucose with greater efficiency than did free cellulase.     

A model for the lateral diffusion of “stiff” chains in a lipid bilayer

We present random walk models for the diffusive motion of lipid probe molecules in a lipid bilayer and calculate the diffusion constants for probes spanning the entire bilayer and for probes extending through one lipid layer only. The stiffness of such molecules can explain the observed value of 2/3 for the ratio of these diffusion constants.     

Direct correlation of consecutive C′–N groups in proteins: a method for the assignment of intrinsically disordered proteins

Two novel 3D ¹³C-detected experiments, hNcocaNCO and hnCOcaNCO, are proposed to facilitate the resonance assignment of intrinsically disordered proteins. The experiments correlate the ¹⁵N and ¹³C′ chemical shifts of two consecutive amide moieties without involving other nuclei, thus taking advantage of the good dispersion shown by the ¹⁵N–¹³C′ correlations, even for proteins that lack a well defined tertiary structure. The new pulse sequences were successfully tested using Nupr1, an intrinsically disordered protein of 93 residues.     

Measurement of 2J(H,C)- and 3J(H,C)-coupling constants by α/β selective HC(C)H-TOCSY

A new heteronuclear NMR pulse sequence for the measurement of ⁿJ(C,H) coupling constants, the /selective HC(C)H-TOCSY, is described. It is shown that the S³E element (Meissner et al., 1997a,b) can be used to obtain spin state selective coherence transfer in molecules, in which adjacent CH moieties are labeled with ¹³C. Application of the / selective HC(C)H-TOCSY to a 10nt RNA tetraloop 5-CGCUUUUGCG-3, in which the four uridine residues are ¹³C labeled in the sugar moiety, allowed measurement of two bond and three bond J(C,H) coupling constants, which provide additional restraints to characterize the sugar ring conformation of RNA in cases of conformational averaging.