Three-dimensional model of the α-subunit of bacterial luciferase

The predicted secondary structure of both subunits of bacterial luciferase is in accordance with a regular 8-fold α/β-barrel structure. The 3D profile^1,2 confirmed that luciferase subunits are compatible with the α/β-barrel despite the absence of sequence similarity with any α/β-barrel protein. The three-dimensional structure of 260 residues of the α-chain of luciferase was modeled from coordinates of glycolate oxidase and then energy minimized. The model obtained satisfies the criteria for the structure of a globular protein and is in accordance with known experimental data. From the model it is possible to predict active site residues involved in binding and catalysis. These predictions, and thus also the model, can be tested by protein engineering experiments. © 1995 Wiley-Liss, Inc.     

Mutagenesis of beryllium-specific TCRs suggests an unusual binding topology for antigen recognition

Unconventional Ags, such as metals, stimulate T cells in a very specific manner. To delineate the binding landscape for metal-specific T cell recognition, alanine screens were performed on a set of Be-specific TCRs derived from the lung of a chronic beryllium disease patient. These TCRs are HLA-DP2-restricted and express nearly identical TCR Vβ5.1 chains coupled with different TCR α-chains. Site-specific mutagenesis of all amino acids comprising the CDRs of the TCRA and TCRB genes showed a dominant role for Vβ5.1 residues in Be recognition, with little contribution from the TCR α-chain. Solvent-exposed residues along the α-helices of the HLA-DP2 α- and β-chains were also mutated to alanine. Two β-chain residues, located near the proposed Be binding site of HLA-DP2, played a dominant role in T cell recognition with no contribution from the HLA-DP2 α-chain. These findings suggest that Be-specific T cells recognize Ag using an unconventional binding topology, with the majority of interactions contributed by TCR Vβ5.1 residues and the HLA-DP2 β1-chain. Thus, unusual docking topologies are not exclusively used by autoreactive T cells, but also for the recognition of unconventional metal Ags, such as Be.     

Primary structure of hemoglobin β-chain fromColumba livia (gray wild pigeon)

Primary structure of β-chain of pigeon is presented. It was determined by amino acid sequence analysis of intact β-chain and its peptides obtained by the enzymatic and chemical cleavage. Comparison of amino acid sequence of the chain with other available data shows β 14 Ile, β61 Lys, and β113 Ile as residues specific to pigeon. One important replacement at α₁β₁ contact is β55 Met→Ser.     

Primary structure of hemoglobin α-chain from Cuckoo (Eudynamys scolopaceae,Cuculiformes)

The complete amino acid sequence of the α^A-chain of major hemoglobin component from Cuckoo (Eudynamys scolopaceae) is presented. Separation of the polypeptide subunits was achieved by ion exchange chromatography in the presence of 8 M urea. The sequence was studied by automatic Edman degradation of the native chain and its tryptic fragments in a gas-phase sequencer. Comparison with other avian hemoglobins shows residues α21, α30, α96, α110, and α114 as being specific to Cuckoo. The functional significance of these is discussed.     

Complete primary structure of the alpha 1-chain of human basement membrane (type IV) collagen

We have determined the primary structure of the alpha 1(IV)-chain of human type IV collagen by nucleotide sequencing of overlapping cDNA clones that were isolated from a human placental cDNA library. The present data provide the sequence of 295 amino acids not previously determined. Altogether, the alpha 1(IV)-chain contains 1642 amino acids and has a molecular mass of 157625 Da. There are 1413 residues in the collagenous domain and 229 amino acids in the carboxy-terminal globular domain. The human alpha 1(IV)-chain contains a total of 21 interruptions in the collagenous Gly-X-Y repeat sequence. These interruptions vary in length between two and eleven residues. The alpha 1(IV)-chain contains four cysteine residues in the triple-helical domain, four cysteines in the 15-residue long noncollagenous sequence at the amino-terminus and 12 cysteines in the carboxy-terminal NC-domain.     

Primary structure of the hemolglobin β-chain of Rose-ringed Parakeet (Psittacula krameri)

The primary structure of Rose-ringed Parakeet hemoglobin β-chain was established, completing the analysis of this hemoglobin. Comparisons with other avian β-chains show variations smaller than those for the corresponding α-chains. There are 11 amino acid exchanges in relationship to the only other characterized psittaciform β-chain, and a total of 35 positions are affected by differences among all avian β-chains analyzed (versus 61 for the α-chains). At three positions, the Psittacula β-chain has residues unique to this species. Three α₁β₁ contacts are modified, by substitutions at positions β51, β116, and β125.     

Primary structure of the hemoglobin α-chain of rose-ringed parakeet (Psittacula krameri)

The structure of the hernoglobin α-chain of Rose-ringed Parakeet was determined by sequence degradations of the intact subunit, the CNBr fragments, and peptides obtained by digestion with staphylococcal Glu-specific protease and trypsin. Using this analysis, the complete α-chain structure of 21 avian species is known, permitting comparisons of the protein structure and of avian relationships. The structure exhibits differences from previously established avian α-chains at a total of 61 positions, five of which have residues unique to those of the parakeet (Ser-12, Gly-65, Ser-67, Ala-121, and Leu-134). The analysis defines hemoglobin variation within an additional avian order (Psittaciformes), demonstrates distant patterns for evaluation of relationships within other avian orders, and lends support to taxonomic conclusions from molecular data.     

A photoaffinity ligand of the acetylcholine-binding site predominantly labels the region 179–207 of the α-subunit on native acetylcholine receptor from Torpedo marmorata

Regions of the Torpedo marmorata acetylcholine receptor (AChR) α-subunit involved in the binding of acetylcholine were probed with two different covalent ligands. The sulfhydryl-directed affinity reagent 4-(N-maleimido)phenyltrimethylammonium iodide labeled a single α-subunit cyanogen bromide fragment on the reduced AChR which was identified as α 179–207. The novel photoaffinity ligand p-(N,N-dimethylamino)-benzenediazonium fluoroborate, on the other hand, labeled three distinct α-chain cyanogen bromide fragments on the unmodified AChR in a carbamylcholine-protectable manner. The major radiolabeled species was purified and identified by sequence analysis as α 179–207. The acetylcholine-binding site on the native AChR may thus involve several distinct portions of the α-chain, with the region α 179–207 making a major contribution to the site.     

Quantitative assessment of the association of the α-I fragment of spectrin with oligomers of intact spectrin

• 1.1. The α-I fragment of human spectrin that carries the binding site on the α-chain of spectrin for the β -chain has been purified from limited trypsin digests of spectrin by means of FPLC.
• 2.2. The self-association of spectrin and the binding of the α-I fragment to spectrin heterodimers and to tetramers have been quantified through the use of gel electrophoresis, staining with Coomassie Blue, and quantification of the bound dye following elution with pyridine.
• 3.3. The parameters of self-association were found to be consistent with those estimated from sedimentation equilibrium analysis.
• 4.4. The data were consistent with a model in which both self-association and the binding of the α-I fragment are considered to occur through an intermediate in which the α-β interface is initially dissociated. The α-β interface in the heterodimer was found to be less stable than that of higher oligomers by approx. 3 kJ/mol.

     

Primary structure of hemoglobin α-chain ofColumba livia (gray wild pigeon)

Primary structure of hemoglobin of α-chain ofColumba livia is presented. The separation of α-chain was obtained from globin by ion-exchange chromatography (CMC-52) and reversed-phase HPLC (RP-2 column). Amino acid sequence of intact as well as tryptic digested chain was determined on gas-phase sequencer. Structure is aligned homologously with 21 other species. Among different exchanges, positions α24 (Tyr→Leu), α26 (Ala→Gly), α32 (Met→Leu), α64 (Asp→Glu), α113 (Leu→Phe), and α129 (Leu→Val) are unique to pigeon hemoglobin. The various exchanges in α-chain are discussed with reference to evolution and phylogeny. The results show that the order Columbiformes is evolutionarily closer to the order Anseriformes. Since the pigeon is homogeneous, having HbA (α^A-chain) and lacks α^D-chain, its phylogenetic placement could be established among birds having single hemoglobin components.     

The Effect of Stabilizing Mutations in the Central Part of α-Chain of Tropomyosin on the Bending Stiffness of Reconstructed Thin Filaments that Contain Its αβ-Heterodimers

We studied the effect of the replacement of two highly conserved noncanonical residues in the α-chain of tropomyosin, that is, Asp137 and Gly126, with the canonical residues, Leu and Arg, on the mechanical properties of reconstructed thin filaments that contain αβ-heterodimers of tropomyosin. For this purpose, the reconstructed thin filaments that contain fibrillar actin, tropomyosin, and troponin were stretched with an optical trap. The resulting strain–force diagrams were analyzed using a mathematical model proposed previously in order to estimate the bending stiffness. It was shown that the thin filaments that contain αβ-heterodimers of tropomyosin with α-chains of the pseudo-wild type, i.e., that contain the C190A substitution, have approximately the same bending stiffness as the filament with αα-homodimers of tropomyosin. The stabilizing substitution D137L in the α-chain of tropomyosin did not cause a statistically significant change in the bending stiffness of the filaments that contain αβ-heterodimers of tropomyosin, whereas the G126R and G126R/D137L substitutions led to a moderate increase in this stiffness. This increase in stiffness was, however, much less pronounced than that for the filaments that contain αα-homodimers of tropomyosin with these substitutions in both α-chains. The relationship between the results obtained in this study and the previously published data on the effects of these stabilizing substitutions in the α-chain of tropomyosin on the structural and functional properties of thin filaments with αβ-heterodimers of tropomyosin is discussed.     

The effects of stabilizing mutations in the central part of the α-chain of tropomyosin on the structural and functional properties of αβ-tropomyosin heterodimers

The effects of the D137L/G126R double mutation in the central part of the tropomyosin α-chain via the simultaneous replacement of two highly conserved non-canonical residues, viz., Asp137 and Gly126, by canonical residues Leu and Arg, respectively, on the properties of the αβ-tropomyosin heterodimer have been studied. It has been shown using circular dichroism that this mutation substantially increases the thermal stability of αβ-tropomyosin heterodimers, which, nevertheless, remains lower than that of αα-tropomyosin homodimers with these mutations in both α-chains. The stability of tropomyosin complexes with F-actin has also been studied by measuring the temperature dependences of their dissociation, which is detected by a decrease in light scattering. It has been revealed that αβ-tropomyosin heterodimers carrying the D137L/G126R mutation in the α-chain dissociate from the surface of actin filaments at a higher temperature than ββ-homodimers but at a lower temperature than αα-homodimers with these mutations in both α-chains. It has also been shown using the in vitro motility assay that D137L/G126R substitution in the α-chain increases the sliding velocity of regulated actin filaments in the case of αα-homodimers, while it noticeably decreases the velocity in the case of αβ-tropomyosin heterodimers. Thus, we can conclude that mutations in one of the chains of the tropomyosin dimeric molecule may have different effects on the properties of tropomyosin homodimers and heterodimers.     

Information contained in the amino acid sequence of theα1(I)-chain of collagen and its consequences upon the formation of the triple helix,of fibrils and crosslinks

The molecule of type I collagen from skin consists of two alpha1(I)-chains and one alpha2-chain. The sequence of the entire alpha1-chain comprising 1052 residues is summarily presented and discussed. Apart from the 279 residues of alpha1(I)-CB8 whose sequence has been established for rat skin collagen, all sequences have been determined for calf skin collagen. In order to facilitate sequence analysis, the alpha1-chain was cleaved into defined fragments by cyanogen bromide or hydroxylamine or limited collagenase digestion. Most of the sequence was established by automated stepwise Edman degradation. The alpha1-chain contains two basically different types of sequences: the triple helical region of 1011 amino acid residues in which every third position is occupied by glycine and the N- and C-terminal regions not displaying this type of regularity. Both of these non-triple helical regions carry oxidizable lysine or hydroxylysine residues as functional sites for the intermolecular crosslink formation. Implications of the amino acid sequence for the stability of the triple helix and the fibril as well as for formation of crosslinks are discussed. Evaluation of the sequence in connection with electron microscopical investigations yielded the parameters of the axial arrangement of the molecules within the fibrils. Axial stagger of the molecules by a distance D = 670 angstrom = 233 amino acid residues results in maximal interaction of polar sequence regions of adjacent molecules and similarly of regions of hydrophobic residues. Ordered aggregation of molecules into fibrils is, therefore, regulated by electrostatic and electrophobic forces. Possible loci of intermolecular crosslinks between the alpha1-chains of adjacent molecules may be deduced from the dimensions of the axial aggregation of molecules.     

Evidence of homology between the β-chain of human haptoglobin and the chymotrypsin family of serine proteases

Amino acid sequences from the β-chain of human haptoglobin are compared with those sequences known for the serine proteases of the chymotrypsin family. In a comparison of some 171 residues of the haptoglobin β-chain (approximately 60% of the protein molecule), approximately 30% of these are identical to residues occurring in sequences of either bovine trypsin, bovine chymotrypsin A, bovine chymotrypsin B, porcine elastase, or bovine thrombin B-chain, and an additional 10% are chemically similar. A combined comparison of the haptoglobin β-chain with the above five serine proteases gave an identity of 56% and a chemical similarity of 11%. Similarity of primary structure is also striking around two of the five half-cystinyl residues so far characterized in long lengths of sequence. These data provide substantial evidence that the β-chain of haptoglobin is homologous to the chymotrypsin family of serine proteases. Proposals are also presented to explain the occurrence of internal homology in the N-terminal region of the β-chain.     

The covalent structure of collagen. The amino-acid sequence of alpha2-CB4 from calf-skin collagen.

Sequencing of chymotrypsin, trypsin, collagenase- and hydroxylamine-derived peptides, using the automated Edman degradation procedure, yielded the complete amino acid sequence of alpha2-CB4 from calf skin collagen (321 residues). Together with the data from earlier work, an uninterrupted sequence in the helical region of the alpha2-chain from residues 1-393 is now known. Glycine is found in every third position of the peptide. Hydroxylation of proline and lysine occurs only in the Y-position of the triplet Gly-X-Y and is not complete in every position. Some residues, such as glutamic acid, leucine, phenylalanine and arginine, are distributed non-randomly between the X and Y-positions and this non-random distribution is different in the alpha1 and alpha2-chains. Comparison of the N-terminal 393 residues from the helical region of the alpha1 and alpha2-chains revealed a nearly identical distribution of charged polar residues arginine, lysine, glutamic and aspartic acids. The distribution of the triplet Gly-Pro-Hyp is simialr in both chains. The remaining residues in the alpha2-chain exhibit a high degree of substitutions when compared with those in the alpha1-chain. Approximately one in every two residues in both the X and Y-positions are substituted.     

The tryptic peptides of coyote (Canis latrans) hemoglobin

The tryptic peptides from α- and β-chains of coyote (Canis latrans) hemoglobin have been isolated and their amino acid compositions determined. The compositions are identical to those previously found for dog hemoglobin in all respects except one: the αT-13 peptide of coyote has only threonine at residue 130 of the chain. This indicates only one α-chain in coyote instead of two as in dog, which has one α-chain with threonine and one α-chain with alanine at this position. The α-chain from wolf (Canis lupus) is like that from coyote in having only threonine at residue 130.     

Hemoglobin of mice with radiation-induced mutations at the hemoglobin loci.

Chemical analyses were done on the abnormal hemoglobins of five (101 × SEC)F₁ offspring of X-irradiated adult SEC mice to determine which hemoglobin genes were expressed in each hemoglobin variant. Three offspring of irradiated SEC males did not express either of the two kinds of α-chains normally found in all SEC mice. The deficient α-chain synthesis caused these mice to exhibit an α-thalassemia similar to human α-thalassemia. Scanning electron microscopy was used to show that many erythrocytes of mice with α-thalassemia have bizarre shapes; e.g. many erthrocytes appeared flattened or had thorny projections (acanthocytes). One mutant with a tandem duplication of a segment of chromosome 7 (site of locus determining β-chain structure) produced twice as much SEC as 101 β-chain polypeptides. One mutant that probably arose by non-disjunction of chromosome 7's in its unirradiated 101 mother and loss of chromosome 7 from the gamete of its irradiated SEC father did not express the SEC β-chain gene.     

Isolation, structural elucidation and synthesis of a tetradecapeptide with in vitro ACTH-releasing activity corresponding to residues 33-46 of the alpha-chain of porcine hemoglobin.

A peptide found in acetic acid extracts of porcine hypothalami and capable of stimulating the release of ACTH in vitro was isolated in pure state, structurally identified as Phe-Leu-Gly-Phe-Pro-Thr-Thr-Lys-Thr-Tyr-Pre-Pro-His-Phe and synthesized. This tetradecapeptide, which corresponds to amino acid residues no. 33–46 in the sequence of the α-chain of porcine hemoglobin, probably represents an artefact of extraction or isolation procedures. Since this peptide stimulates ACTH release from rat pituitary fragments and from monolayer cultures of pituitary cells, but not $\text{in vivo}$, caution must be exercised in interpreting the results of $\text{in vitro}$ assays for corticotropin releasing factor.     

Carboxy terminal fragment of human alpha-1-antitrypsin from hydroxylamine cleavage: homology with antithrombin III.

Human α-1-antitrypsin (AT) was reacted with hydroxylamine at pH 9.0 giving cleavage at an Asn-Gly bond. A fragment of molecular weight 8,500 was released and this was isolated and sequenced. The fragment had the same carboxy terminal amino acid sequence as intact AT. The 80 residue polypeptide contained the Z variant mutation site and a portion of sequence identical to that found by others for the reactive site, inferring the presence in AT of two active sites. This sequence combined with prviously published work gives a continuous sequence of 152 amino acid residues from the carboxy terminal end of the AT molecule, including the mutation site of the S variant. The sequence shows strong homology with human antithrombin III.     

Acetylation and glycation of fibrinogen in vitro occur at specific lysine residues in a concentration dependent manner: a mass spectrometric and isotope labeling study

Aspirin may exert part of its antithrombotic effects through platelet-independent mechanisms. Diabetes is a condition in which the beneficial effects of aspirin are less prominent or absent - a phenomenon called "aspirin resistance". We investigated whether acetylation and glycation occur at specific sites in fibrinogen and if competition between glucose and aspirin in binding to fibrinogen occurs. Our hypothesis was that such competition might be one explanation to "aspirin resistance" in diabetes. After incubation of fibrinogen in vitro with aspirin (0.8 mM, 24 h) or glucose (100 mM, 5-10 days), we found 12 modified sites with mass spectrometric techniques. Acetylations in the α-chain: αK191, αK208, αK224, αK429, αK457, αK539, αK562, in the β-chain: βK233, and in the γ-chain: γK170 and γK273. Glycations were found at βK133 and γK75, alternatively γK85. Notably, the lysine 539 is a site involved in FXIII-mediated cross-linking of fibrin. With isotope labeling in vitro, using [(14)C-acetyl]salicylic acid and [(14)C]glucose, a labeling of 0.013-0.084 and 0.12-0.5 mol of acetylated and glycated adduct/mol fibrinogen, respectively, was found for clinically (12.9-100 μM aspirin) and physiologically (2-8 mM glucose) relevant plasma concentrations. No competition between acetylation and glycation could be demonstrated. Thus, fibrinogen is acetylated at several lysine residues, some of which are involved in the cross-linking of fibrinogen. This may mechanistically explain why aspirin facilitates fibrin degradation. We find no support for the idea that glycation of fibrin(ogen) interferes with acetylation of fibrinogen.