Internal packing conditions and fluctuations of amino acid residues in globular proteins

In order to investigate the environmental conditions of amino acid residues in protein molecules, four kinds of packing studies (atomic, geometric, hydrophobic and hydration) were formulated and tested on two proteins; bovine pancreatic trypsin inhibitor (BPTI) and bovine pancreatic ribonuclease S (RNase S). The inter-relationship of these packings on the fluctuations of amino acid residues was analysed by comparing the packing results with the dynamical studies, such as the root-mean-square-deviation values of atomic displacements obtained from the trajectories of molecular dynamics simulation, temperature factor information from crystal structures and residue fluctuations in proteins from continuum model. These analyses yield information about the most fluctuating and most stabilizing residue sites. Comparison of the results obtained by these methods indicate a good agreement, specifying an inverse correlation between the residue packing and fluctuations. This kind of study is helpful in identifying the specific residue sites such as nucleation, receptor binding and antigenic determining sites which in a way indirectly correlates with the functional residues in protein molecules.     

Reaction of osmium reagents with amino acids and proteins. Reactivity of amino acid residues and peptide bond cleavage

We report a study of the relative reactivity of the common amino acids and of their residues in lysozyme with osmium tetroxide, the osmium tetroxide-pyridine reagent, and with the oxo-osmium(VI)-pyridine reagent. With free amino acids, the osmium(VIII) reagents are most reactive with Met, Cys, His, Thr, Ser, Trp, Lys, and Pro; the osmium(VI) reagent only reacts significantly with His, Met, Cys, Thr, and Ser. In lysozyme, only Cys, Met, and Trp react extensively with the osmium(VIII) reagents; with the osmium(VI) reagent, Cys and Met are most reactive. We also note evidence both for cross-linking of proteins and for peptide bond cleavage, which appears to have considerable specificity for tryptophanyl residues.     

Measurement of the beta-sheet-forming propensities of amino acids

Several model systems have been used to evaluate the alpha-helical propensities of different amino acids. In contrast, experimental quantitation of beta-sheet preferences has been addressed in only one model system, a zinc-finger peptide. Here we measure the relative propensity for beta-sheet formation of the twenty naturally occurring amino acids in a variant of the small, monomeric, beta-sheet-rich, IgG-binding domain from protein G. Amino-acid substitutions were made at a guest site on the solvent-exposed surface of the beta-sheet. Several criteria were used to establish that the mutations did not cause significant structural changes: binding to the Fc domain of IgG, calorimetric unfolding and NMR spectroscopy. Characterization of the terminal stabilities of these proteins leads to a thermodynamic scale for beta-sheet propensities that spans a range of approximately 2 kcal mol-1 for the naturally occurring amino acids, excluding proline. The magnitude of the differences suggests that beta-sheet preferences can be important determinants of protein stability.     

Hydrolysis and amino acid composition of proteins

Amino acid composition analysis is a classical protein analysis method, which finds a wide application in medical and food science research and is indispensable for protein quantification. It is a complex technique, comprising two steps, hydrolysis of the substrate and chromatographic separation and detection of the residues. A properly performed hydrolysis is a prerequisite of a successful analysis. The most significant developments of the technology in the last decade consist in the (i) reduction of the hydrolysis time by the use of microwave radiation energy; (ii) improvement in the sensitivity of the residue detection, the quantification of the sensitive residues and separation of the enantiomeric forms of the amino acids; (iii) application of amino acid analysis in the large-scale protein identification by database search; and (iv) gradual replacement of the original ion exchange residue separation by reversed-phase high-performance liquid chromatography. Amino acid analysis is currently facing an enormous competition in the determination of the identity of proteins and amino acid homologs by the essentially faster mass spectrometry techniques. The amino acid analysis technology needs further simplification and automation of the hydrolysis, chromatography and detection steps to withstand the pressure exerted by the other technologies.     

A kinetic model for the competitive reactions of ozone with amino acid residues in proteins in reverse micelles

Lysozyme and 10 other proteins are solubilized in reverse micelles formed by 0.1 M sodium di-2-ethyl-hexylsulfosuccinate and 2.0-2.5 M water (pH 7.4) in isooctane solvent. Exposure of the protein-containing reverse micellar solutions to ozone causes oxidative damage to the proteins, as assessed by the oxidation of tryptophan residues. The oxidation product of the protein-bound tryptophan has a molar absorption coefficient of 3275 +/- 81 M-1 cm-1 (mean +/- S.D., n = 6) at 320 nm. The product is suggested to be a Criegee ozonide or a tautomer of the Criegee ozonide and not N-formylkynurenine. Ozonation of lysozyme in reverse micelles results in the formation of hydrogen peroxide in yields of only approximately 0.07 mol/mol of tryptophan residues oxidized. The recovery of hydrogen peroxide added as an internal standard to the lysozyme-containing reverse micellar solutions ranges from 84 to 88%, whether or not the samples are subjected to ozonation. This suggests that hydrogen peroxide is neither destroyed during the process of ozonation nor consumed by the protein to a significant extent in an adventitious reaction. A kinetic model for the overall reaction of ozone with the proteins is developed, taking into account the concentrations and the reactivities of individual amino acid residues toward ozone. The model predicts the fractional reaction of ozone with tryptophan residues in the proteins, despite differences in amino acid composition, molecular weight, and tertiary structures. The lack of influence of protein structure is confirmed further by the observation that the native lysozyme (with and without external S-carboxymethylcysteine) and S-carboxymethylated lysozyme give identical values of the fractional reaction of ozone with tryptophan residues. The kinetic equations for the competitive reactions of ozone with amino acid residues in proteins, with some minor modification, are applicable to ozonations on complex mixtures of lipids, proteins, and antioxidants.     

Disallowed Ramachandran conformations of amino acid residues in protein structures

An analysis of the nature and distribution of disallowed Ramachandran conformations of amino acid residues observed in high resolution protein crystal structures has been carried out. A data set consisting of 110 high resolution, non-homologous, protein crystal structures from the Brookhaven Protein Data Bank was examined. The data set consisted of a total of 18,708 non-Gly residues, which were characterized on the basis of their backbone dihedral angles (phi, psi). Residues falling outside the defined broad allowed limits on the Ramachandran map were chosen and the reported B-factor value of the alpha-carbon atom was used to further select well defined disallowed conformations. The conformations of the selected 66 disallowed residues clustered in distinct regions of the Ramachandran map indicating that specific phi, psi angle distortions are preferred under compulsions imposed by local constraints. The distribution of various amino acid residues in the disallowed residue data set showed a predominance of small polar/charged residues, with bulky hydrophobic residues being infrequent. As a further check, for all the 66 cases non-hydrogen van der Waals short contacts in the protein structures were evaluated and compared with the ideal Ala-dipeptide constructed using disallowed dihedral angle (phi, psi) values. The analysis reveals that short contacts are eliminated in most cases by local distortions of bond angles. An analysis of the conformation of the identified disallowed residues in related protein structures reveals instances of conservation of unusual stereochemistry.     

Identification of amino acid residues important for ligand binding to Fas

OBJECTIVE: An autoantibody to a nucleolar RNA helicase protein (Gu) was recently discovered in a patient with gastric antral vascular ectasia or watermelon stomach, a disorder that is increasingly being described in systemic sclerosis (SSc). The present study was undertaken to determine whether anti-Gu antibodies occur in connective tissue diseases (CTD) and, if so, to determine their frequencies and any clinical or immunogenetic associations. METHODS: Anti-Gu antibodies were determined by Western blotting of glutathione-purified glutathione S transferase-Gu fusion proteins against consecutive antinucleolar antibody-positive sera (HEp-2 cell substrate) collected over a 5-year period in a rheumatology antinuclear antibody (ANA) testing laboratory. RESULTS: Anti-Gu antibodies were found in 11 (10%) of 108 antinucleolar antibody-positive sera. The subjects with anti-Gu antibodies included 3 of 46 patients with SSc (7%), 3 of 17 patients with systemic lupus erythematosus (18%), 4 of 9 patients with undifferentiated CTD (44%), and 1 healthy relative of an SSc patient. None of the anti-Gu-positive patients had any symptoms suggestive of watermelon stomach. Increased frequencies of both HLA-DQA1*0501 and DQB1*0301 were found, but only DQB1*0301 maintained statistical significance after correction. CONCLUSION: Anti-Gu (nucleolar RNA helicase) antibodies occur in low frequencies in patients with CTDs who have antinucleolar antibodies by ANA testing, but they are not specific for SSc or the watermelon stomach lesion.     

Identification of amino acid residues in a class I ubiquitin-conjugating enzyme involved in determining specificity of conjugation of ubiquitin to proteins

The ubiquitin pathway is a major system for selective proteolysis in eukaryotes. However, the mechanisms underlying substrate selectivity by the ubiquitin system remain unclear. We previously identified isoforms of a rat ubiquitin-conjugating enzyme (E2) homologous to the Saccharomyces cerevisiae class I E2 genes, UBC4/UBC5. Two isoforms, although 93% identical, show distinct features. UBC4-1 is expressed ubiquitously, whereas UBC4-testis is expressed in spermatids. Interestingly, although these isoforms interacted similarly with some ubiquitin-protein ligases (E3s) such as E6-AP and rat p100 and an E3 that conjugates ubiquitin to histone H2A, they also supported conjugation of ubiquitin to distinct subsets of testis proteins. UBC4-1 showed an 11-fold greater ability to support conjugation of ubiquitin to endogenous substrates present in a testis nuclear fraction. Site-directed mutagenesis of the UBC4-testis isoform was undertaken to identify regions of the molecule responsible for the observed difference in substrate specificity. Four residues (Gln-15, Ala-49, Ser-107, and Gln-125) scattered on surfaces away from the active site appeared necessary and sufficient for UBC4-1-like conjugation. These four residues identify a large surface of the E2 core domain that may represent an area of binding to E3s or substrates. These findings demonstrate that a limited number of amino acid substitutions in E2s can dictate conjugation of ubiquitin to different proteins and indicate a mechanism by which small E2 molecules can encode a wide range of substrate specificities.     

Design, synthesis, and biological activities of four angiotensin II receptor ligands with gamma-turn mimetics replacing amino acid residues 3-5

Disulfide cyclization is a powerful method for reducing the conformational space of a peptide. This in turn may enable the study of its bioactive conformation. Several analogues of angiotensin II (Ang II) containing a disulfide bridge between amino acids 3 and 5 have been reported. Among these the cyclic octapeptides c[Hcy3,5]-Ang II, c[Cys3,5]-Ang II, and c[Pen 3,5]-Ang II showed significant activity at Ang II receptors. We have performed conformational analysis studies using theoretical calculations and 1H-NMR spectroscopy on tripeptide model compounds of these cyclic octapeptides which show that the cyclic moieties of c[Cys3,5]-Ang II and c[Pen3,5]-Ang II preferentially assume an inverse gamma-turn conformation. On the basis of these results, we substituted amino acid residues 3-5 in Ang II with two different gamma-turn mimetics giving four diastereomeric Ang II analogues. Interestingly, two of these are equipotent to Ang II in binding to AT1 receptors. In the contractile test using rabbit aorta rings, one of the analogues is an agonist with full contractile activity approximately equipotent to c[Pen3,5]-Ang II but 300-fold less potent than Ang II. This low potency may suggest that Ang II does not adopt a gamma-turn in the 3-5 region when interacting with the receptor.     

Functional heterodimeric amino acid transporters lacking cysteine residues involved in disulfide bond

Sera of 125 patients with sexually transmitted diseases (syphilis, gonorrhoea, chlamydiosis, HPV and HIV infections) were investigated for presence of 3 markers of HBV infection; they were found in 41 (33%) patients. Anti-HBc was present in sera of 35 (28%) patients, in 3 of them antigen HBs was found and in 28 anti-HBs was found as well. Antigen HBs alone was present in sera of 6 other patients but they were not reactive in test for anti-HBc. Moreover in this group of 125 patients anti-HCV were discovered in 4 (3%); in 3 of them occurrence of markers of HBV infection was found.     

Selection of amino acid parameters for Fourier transform-based analysis of proteins

Fourier analysis of the parametric profile of a sequence for the detection and localization of the structural motifs that are characteristic for biologically related proteins has been proposed. In order to select parameters that are most appropriate for this analysis, the informational capacity of 226 physicochemical, thermodynamic, structural and statistical amino acid parameters was analyzed. Based on the results, obtained for the four functionally unrelated protein model groups (lysozyme c, HIV-1 gp120, tubulin and tau proteins, and steroid hormone receptors), the electron-ion interaction potential has been selected as the unique amino acid property that can be used in Fourier transform-based analysis of proteins, independently of their biological function.     

Negative ion postsource decay time-of-flight mass spectrometry of peptides containing acidic amino acid residues

Acidic peptides have been studied by negative ion postsource decay (PSD) matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry. The peptides contained from 5 to 16 residues and were chosen on the basis of their patterns of the acidic residues. Using typical MALDI sample preparation techniques employing an acidic matrix, gastrin I (1-14), and epidermal mitosis inhibiting pentapeptide yielded much larger deprotonated ion signals, [M - H]-, than protonated ions, [M + H]+. This may be due to their absence of basic residues, coupled with their arrays of acidic residues. The PSD fragmentation of the peptide negative ions showed that an array of acidic residues, as in gastrin I (1-14), yielded simple spectra containing mainly backbone cleavage ions from the C-terminus. Hirudin (54-65), which contains two sets of two consecutive Glu residues, and fibrinopeptide A and fibrinopeptide B, with isolated acidic residues, also showed backbone cleavages as common fragment ions. In addition, the two sets of isolated consecutive amino acid residues in Cys(Bzl)84-CD4 (81-92) and hirudin (54-56) yielded internal ions from the cleavages at the (O=C)-NH bond between the acidic residues. Also observed were ions with unique side chain losses, such as the loss of C6H4O from a tyrosine residue and SCH2C6H5 and CH2C6H5 from a benzylated cysteine residue. Compared to the positive mode, the negative-ion PSD yielded fewer fragments which usually involved only one type of backbone cleavage (e.g., [Yn - H2O]-). These simple spectra aided interpretation. Overall, the acidic peptides studied yielded negative ion PSD spectra that were useful for peptide sequencing.     

Large-scale identification of proteins of Haemophilus influenzae by amino acid composition analysis

Two-dimensional protein maps of microorganisms are useful tools for elucidation and detection of target proteins, a process essential in the development of new pharmaceutical products. We applied amino acid composition analysis, following separation by two-dimensional gel electrophoresis, for large-scale identification of proteins of Haemophilus influenzae. H. influenzae is a bacterium of pharmaceutical interest of which the entire genome, comprising approximately 1700 open reading frames, has been sequenced. For amino acid analysis, we used both precolumn derivatization of amino acids followed by reversed-phase chromatography of the derivatized residues and post-column derivatization of the residues previously separated on an ion exchanger. The composition analyses derived from both methods allowed the identification of 110 protein spots. The proteins were identified using the AACompldent software on the ExPASy server accessible via the World Wide Web with a success rate of 52%. In some cases, introduction of the analysis data of 12 residues was sufficient for a correct identification. Proteins which contained an unusually high percentage of one residue could be unambiguously identified. Amino acid composition analysis proved to be an error-robust, efficient method for protein identification. The method can be practically established in every biochemical laboratory and, complementary to mass spectrometry, represents an important analytical tool for the mapping of the proteomes of organisms of interest.     

Second messengers, trafficking-related proteins, and amino acid residues that contribute to the functional regulation of the rat brain GABA transporter GAT1

Recent evidence indicates that several members of the Na+-coupled transporter family are regulated, and this regulation in part occurs by redistribution of transporters between intracellular locations and the plasma membrane. We elucidate components of this process for both wild-type and mutant GABA transporters (GAT1) expressed in Xenopus oocytes using a combination of uptake assays, immunoblots, and electrophysiological measurements of membrane capacitance, transport-associated currents, and GAT1-specific charge movements. At low GAT1 expression levels, activators of protein kinase C (PKC) induce redistribution of GAT1 from intracellular vesicles to the plasma membrane; at higher GAT1 expression levels, activators of PKC fail to induce this redistribution. However, coinjection of total rat brain mRNA with GAT1 permits PKC-mediated modulation at high transporter expression levels. This effect of brain mRNA on modulation is mimicked by coinjection of syntaxin 1a mRNA and is eliminated by injecting synaptophysin or syntaxin antisense oligonucleotides. Additionally, botulinum toxins, which inactivate proteins involved in vesicle release and recycling, reduce basal GAT1 expression and prevent PKC-induced translocation. Mutant GAT1 proteins, in which most or all of a leucine heptad repeat sequence was removed, display altered basal distribution and lack susceptibility to modulation by PKC, delineating one region of GAT1 necessary for its targeting. Thus, functional regulation of GAT1 in oocytes occurs via components common to transporters and to trafficking in both neural and non-neural cells, and suggests a relationship between factors that control neurotransmitter secretion and the components necessary for neurotransmitter uptake.     

Identification of amino acid residues contributing to the pore of a P2X receptor

P2X receptors are ion channels opened by extracellular ATP. The seven subunits currently known are encoded by different genes. It is thought that each subunit has two transmembrane domains, a large extracellular loop, and intracellular N- and C-termini, a topology which is fundamentally different from that of other ligand-gated channels such as nicotinic acetylcholine or glutamate receptors. We used the substituted cysteine accessibility method to identify parts of the molecule that form the ionic pore of the P2X2 receptor. Amino acids preceding and throughout the second hydrophobic domain (316-354) were mutated individually to cysteine, and the DNAs were expressed in HEK293 cells. For three of the 38 residues (I328C, N333C, T336C), currents evoked by ATP were inhibited by extracellular application of methanethiosulfonates of either charge (ethyltrimethylammonium, ethylsulfonate) suggesting that they lie in the outer vestibule of the pore. For two further substitutions (L338C, D349C) only the smaller ethylamine derivative inhibited the current. L338C was accessible to cysteine modification whether or not the channel was opened by ATP, but D349C was inhibited only when ATP was concurrently applied. The results indicate that part of the pore of the P2X receptor is formed by the second hydrophobic domain, and that L338 and D349 are on either side of the channel 'gate'.     

Delineation of amino acid residues within hTSHr 256-275 that participate in hormone binding

The amino acid sequence 256-275 of the human thyrotropin (TSH) receptor extracellular domain has previously been shown to participate in a high affinity TSH binding site by a synthetic peptide approach as well as by site-directed mutagenesis. To further investigate this binding site, we synthesized a series of peptides with alanine substitutions for each residue in the native sequence. Peptides were also synthesized containing truncations or deletions of the native sequence. Each peptide was tested for its ability to inhibit 125I-bTSH binding to porcine thyroid membrane preparations, and the concentration at which 50% inhibition of binding occurred was determined (EC50). Alanine substitution at residues Tyr258, Cys262, Cys263, Phe265, Lys266, Asn267, Lys269, Lys270, and Arg272 all resulted in statistically significant decreases in activity when compared to the native sequence (p < 0.05). Alanine substitution of the remaining residues did not alter their activity. Comparison of this sequence with the corresponding sequences of the remaining glycoprotein hormone receptors (human lutropin and human follitropin receptors) reveals that these residues lie within one of the most highly conserved regions of the extracellular domain. We conclude that 9 specific amino acids within the sequence 256-275 of hTSHr (-Y--CC-FKN-KK-R--) participate in the interaction of the hTSHr-extracellular domain with TSH. This may represent a site in which the nonconserved residues are involved in the binding of the beta-subunit and the conserved residues are involved in the binding of the common alpha-subunit or a region of the beta-subunit that is common to all glycoprotein hormones.