Fusion of trpB and trpA of Escherichia coli yields a partially active tryptophan synthetase polypeptide

The separate alpha and beta polypeptides of the tryptophan synthetase of bacteria are represented in fungi by a fusion polypeptide in which the first third is homologous to bacterial alpha chains and the remainder is homologous to bacterial beta chains. In the yeast polypeptide, a short nonhomologous "connector" joins the two homologous segments. The chromosomal order of all bacterial genes that specify tryptophan synthetase beta and alpha chains, respectively, is trpB-trpA. Fusion of these genes in their present arrangement would result in the synthesis of a polypeptide with a segmental order, N-beta-alpha-C, opposite that observed in fungi. To investigate possible explanations for the apparent transposition that occurred in the evolution of the fungal gene we have made two fusions of trpB and trpA of Escherichia coli in their natural orientation. We find that the fusion proteins are synthesized but both are less active catalytically than the wild type bacterial protein. In addition, the fusion proteins associate abnormally, they are activated only slightly by wild type alpha or beta 2, and they are less sensitive than the wild type protein to inhibition by antibodies to alpha or beta 2. The fusion proteins have normal substrate affinities. Our findings suggest that the altered structures of the fusion proteins affect catalytic ability and the locations of the alpha and/or beta chain combining sites. This structural distortion may have prevented the natural selection of direct gene fusions during the course of the fungal gene's evolution.     

A detailed unfolding pathway of a (beta/alpha)8-barrel protein as studied by molecular dynamics simulations

The (beta/alpha)(8)-barrel is the most common protein fold. Similar structural properties for folding intermediates of (beta/alpha)(8)-barrel proteins involved in tryptophan biosynthesis have been reported in a number of experimental studies; these intermediates have the last two beta-strands and three alpha-helices partially unfolded, with other regions of the polypeptide chain native-like in conformation. To investigate the detailed folding/unfolding pathways of these (beta/alpha)(8)-barrel proteins, temperature-induced unfolding simulations of N-(5'-phosphoribosyl)anthranilate isomerase from Escherichia coli were carried out using a special-purpose parallel computer system. Unfolding simulations at five different temperatures showed a sequential unfolding pathway comprised of several events. Early events in unfolding involved disruption of the last two strands and three helices, producing an intermediate ensemble similar to those detected in experimental studies. Then, denaturation of the first two betaalpha units and separation of the sixth strand from the fifth took place independently. The remaining central betaalphabetaalphabeta module persisted the longest during all simulations, suggesting an important role for this module as the incipient folding scaffold. Our simulations also predicted the presence of a nucleation site, onto which several hydrophobic residues condensed forming the foundation for the central betaalphabetaalphabeta module.     

A proposed structure of bacteriophage T4 gene product 22--a major prohead scaffolding core protein

Gene 22 of bacteriophage T4 encodes a major prohead scaffolding core protein of 269 amino acid residues. From its nucleotide sequence the gene product (gp) 22 has a predicted Mr of 29.9 and a pI of 4.3. The protein is rich in charged residues (glutamic acid and lysine) and contains low amounts of proline and glycine and no cysteine residues. We suggest that gp22 undergoes limited proteolytic processing which eliminates the short C-terminal piece from the molecule during the early steps of prohead assembly. Most amino acid residues of the gp22 polypeptide chain (80%) have an alpha-helical conformation and form seven peculiar alpha-helices. A model suggesting the spatial organization of gp22 is presented. Three long alpha-helices numbered 1 (1A and 1B), 3, and 5 (5A and 5B) are packed in an antiparallel fashion along the major axis of the road-shaped molecule. Two rather short alpha-helices (2 and 4) are located at the distal and proximal ends of the protein molecule, respectively. Helix number 2, which is a proteolytic fragment of gp22 found in mature T4 heads, is packed with helices 1A and 3, similar to a novel element of supersecondary structure, the alpha alpha-corner. Helix number 4 probably interacts with the gp20 connector of the prohead. The implications of the structure of the gp22 molecule for the assembly of the prohead core are discussed.     

The structure and function of the 6-hydroxymethyl-7,8-dihydropterin pyrophosphokinase from Haemophilus influenzae

The gene encoding the 6-hydroxymethyl-7,8-dihydropterin pyrophosphokinase of Haemophilus influenzae has been cloned and expressed in Escherichia coli. A complex of the purified protein with a substrate analog has been crystallized and its structure solved by multiple anomalous dispersion using phase information obtained from a single crystal of selenomethione-labeled protein. The enzyme folds into a four-stranded antiparallel beta-sheet flanked on one side by two alpha-helices and on the other by three consecutive alpha-helices, giving a novel beta1alpha1beta2beta3alpha2beta4alpha3alpha4alpha5 polypeptide topology. The three-dimensional structure of a binary complex has been refined at 2.1 A resolution. The location of the substrate analog and a sulfate ion gives important insight into the molecular mechanism of the enzyme.     

The distribution of alpha-helix propensity along the polypeptide chain is not conserved in proteins from the same family.

We address the question of whether the distribution of secondary structure propensities of the residues along the polypeptide chain (denominated here as secondary structure profiles) is conserved in proteins throughout evolution, for the particular case of alpha-helices. We have analyzed by CD the conformation of peptides corresponding to the five alpha-helices of two alpha/beta parallel proteins (ComA and Ara). The large alpha-helical population of peptide ComA-4 detected by CD in aqueous solution has been confirmed by NMR. These proteins are members of the CheY and P21-ras families, respectively, which have been studied previously in the same way (Muñoz V, Jiménez MA, Rico M, Serrano L, 1995, J Mol Biol 245:275-296). Comparison of the helical content of equivalent peptides reveals that protein alpha-helix propensity profiles are not conserved. Some equivalent peptides show very different helical populations in solution and this is especially evident in very divergent proteins (ComA and CheY). However, all the peptides analyzed so far adopted an important population of helical conformations in the presence of 30% trifluoroethanol, indicating that there could be a conserved minimal requirement for helical propensity.     

Identification and characterization of a novel high-molecular-weight form of the integrin alpha 3 subunit.

The integrin alpha 3 beta 1 is a multiligand extracellular matrix receptor found on many cell types. Immunoprecipitations of 125I-surface-labeled prostate carcinoma cell lines, DU145 and PC-3, with the anti-alpha 3 integrin monoclonal antibodies J143 or PIB5, resulted in the coimmunoprecipitation, along with the expected alpha 3 beta 1 heterodimer, of a polypeptide with a molecular mass of 225 kDa. This protein could also be copurified with the 155-kDa alpha 3 and 115-kDa beta 1 subunits upon affinity chromatography of 125I-surface-labeled cell extracts on anti-alpha 3 antibody-Sepharose columns. Upon reduction, this 225-kDa protein generated 130- and 95-kDa polypeptides, while the 155-kDa alpha 3 subunit generated 130- and 25-kDa polypeptides. The 225-kDa protein did not generate a 25-kDa polypeptide. Deglycosylation and reduction of the 225-kDa protein resulted in the generation of 110- and 95-kDa polypeptides, while deglycosylation and reduction of the 155-kDa alpha 3 resulted in a 110-kDa polypeptide identical in size to the 110-kDa polypeptide generated from the 225-kDa protein. Peptide maps generated from the 110-kDa components of the 225-kDa polypeptide and the 155-kDa alpha 3 integrin subunit were identical, as were their N-terminal amino acid sequences. An antibody directed against the cytoplasmic domain of the alpha 3 subunit immunoprecipitated the 225-kDa polypeptide in addition to the 155-kDa alpha 3 subunit. Furthermore, Northern blot analysis of RNA from DU145 and PC-3 cells with a human alpha 3 cDNA probe identified an mRNA species of 6.2 kb in addition to a major mRNA species of 4.3 kb. The larger mRNA species, which is of an appropriate size for encoding a polypeptide of approximately 220-kDa, was not detectable in cells which did not express the 225-kDa protein. These data demonstrate that the 225-kDa polypeptide represents a novel integrin alpha 3 subunit consisting of the alpha 3 integrin heavy chain disulfide-bonded to a 95-kDa polypeptide which may represent an alternative "light" chain to the 25-kDa light chain of the alpha 3 subunit.     

Standard conformations of a polypeptide chain in irregular protein regions

A detailed stereochemical analysis of known protein structures has been made which shows that: (1) irregular regions of proteins consist of a limited number of standard structures formed by three, four of more residues; (2) an amino acid residue of a protein can adopt one of the six sterically allowed conformations designated here as alpha, alpha L, beta, gamma, delta, and epsilon. It is shown that there are two allowed conformations of a polypeptide chain at the N-end of an alpha-helix, beta alpha n- and beta gamma alpha n-conformations, where n is a number of residues in the alpha-helix. At the C-end of the alpha-helix there are two conformations as well, alpha n gamma beta- and alpha n gamma alpha L beta-ones. Two beta-strands in a beta-hairpin can be joined, for example, by standard structures with beta beta alpha L beta-, beta alpha gamma alpha L beta-, beta alpha alpha gamma alpha L beta-conformations which are referred to as turns. In the regions where a polypeptide chain passes from one layer to another there are standard structures with beta gamma beta-, beta alpha beta beta-, beta alpha gamma beta-conformations etc., referred to as cross-overs. A structure of any protein irregular region can be represented as a combination of these and other standard turns and cross-overs considered in the paper. The major part of the turns and cross-overs has residues in alpha L- or epsilon-conformations which must be glycine or other residues with small or flexible side chains. Massive hydrophobic residues must not occupy the first beta-positions of the most standard structures. The results obtained can be successfully applied for prediction of the location of the turns and cross-overs in proteins from their amino acid sequences and for interpretation of electron density maps.     

Cloning and expression of human haptoglobin subunits in Escherichia coli: delineation of a major antioxidant domain

Human plasma haptoglobin (Hp) comprises alpha and beta subunits. The alpha subunit is heterogeneous in size, therefore isolation of Hp and its subunits is particularly difficult. Using Escherichia coli, we show that alpha1, alpha2, beta, and alpha2beta chain was abundantly expressed and primarily present in the inclusion bodies consisting of about 30% of the cell-lysate proteins. Each cloned subunit retained its immunoreactivity as confirmed using antibodies specific to alpha or beta chain. By circular dichroism, the structure of each expressed subunit was disordered as compared to the native Hp. The antioxidant activity was found to be associated with both alpha and beta chains when assessed by Cu(2+)-induced oxidation of low density lipoprotein (LDL). Of remarkable interest, the antioxidant activity of beta chain was extremely potent and markedly greater than that of native Hp (3.5x), alpha chain (10x) and probucol (15x). The latter is a clinically proved potent compound used for antioxidant therapy. The "unrestricted" structure of beta subunit may therefore render its availability for free-radical scavenge, which provides a utility for the future design of a "mini-Hp" in antioxidant therapy. It may also provide a new insight in understanding the mechanism involved in the antioxidant nature of Hp.     

An automatic search for similar spatial arrangements of alpha-helices and beta-strands in globular proteins

A fast search algorithm to reveal similar polypeptide backbone structural motifs in proteins is proposed. It is based on the vector representation of a polypeptide chain fold in which the elements of regular secondary structures are approximated by linear segments (Abagyan and Maiorov, J. Biomol. Struct. Dyn. 5, 1267-1279 (1988)). The algorithm permits insertions and deletions in the polypeptide chain fragments to be compared. The fast search algorithm implemented in FASEAR program is used for collecting beta alpha beta supersecondary structure units in a number of alpha/beta proteins of Brookhaven Data Bank. Variation of geometrical parameters specifying backbone chain fold is estimated. It appears that the conformation of the majority of the fragments, although almost all of them are right-handed, is quite different from that of standard beta alpha beta units. Apart from searching for specific type of secondary structure motif, the algorithm allows automatically to identify new recurrent folding patterns in proteins. It may be of particular interest for the development of tertiary template approach for prediction of protein three-dimensional structure as well for constructing artificial polypeptides with goal-oriented conformation.     

Pex, analytical tools for PDB files. II. H-Pex: noncanonical H-bonds in alpha-helices

We use the H-Pex (Thomas et al., this issue) to analyze the main chain interactions in 131 proteins. In antiparallel beta-sheets, the geometry of the N...O bond is: median N...O distances, 2.9 SA, C==O...N angles at 154 degrees and the C alpha--C==O...H angles are dispersed around 3 degrees. In some instances, the other side of the C==O axis is occupied by a HC alpha. As recently supported by Vargas et al. (J Am Chem Soc 2000;122:4750-4755) C alpha H...O and NH...O could cooperate to sheet stability. In alpha-helices, the main chain C==O interact with the NH of their n + 4 neighbor on one side, and with a C beta H or C gamma H on the other side. The median O...N distance (3.0 A) and C==N angle (147 degrees) suggest a canonical H-bond, but the C alpha--C==O...H dihedral angle invalidates this option, since the hydrogen attacks the oxygen at 122 degrees, i.e., between the sp(2) and pi orbitals. This supports that the H-bond is noncanonical. In many instances, the C gamma H or the C beta H of the n + 4 residue stands opposite to the NH with respect to the oxygen. Therefore, we propose that, in alpha-helices, the C gamma H or C beta H and the NH of the n + 4 residue hold the oxygen like an electrostatic pincher. Proteins 2001;43:37-44.     

Interaction of the RNA-binding domain of the hnRNP C proteins with RNA.

The hnRNP C proteins are among the most abundant and avid pre-mRNA-binding proteins and they contain a consensus sequence RNA-binding domain (RBD) that is found in a large number of RNA-binding proteins. The interaction of the RBD of the hnRNP C proteins with an RNA oligonucleotide [r(U)8] was monitored by nuclear magnetic resonance (NMR). 15N and 13C/15N-labelled hnRNP C protein RBD was mixed with r(U)8 and one- and two-dimensional (1D and 2D) NMR spectra were recorded in a titration experiment. NMR studies of the uncomplexed 93 amino acid hnRNP C RBD (Wittekind et al., 1992) have shown that it has a compact folded structure (beta alpha beta beta alpha beta), which is typical for the RBD of this family of proteins and which is comprised of a four-stranded antiparallel beta-sheet, two alpha-helices and relatively unstructured amino- and carboxy-terminal regions. Sequential assignments of the polypeptide main-chain atoms of the hnRNP C RBD-r(U)8 complex revealed that these typical structural features are maintained in the complex, but significant perturbations of the chemical shifts of amide group atoms occur in a large number of residues. Most of these residues are in the beta-sheet region and especially in the terminal regions of the RBD. In contrast; chemical shifts of the residues of the well conserved alpha-helices, with the exception of Lys30, are not significantly perturbed. These observations localize the candidate residues of the RBD that are involved in the interaction with the RNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

NMR structure of the human doppel protein

The NMR structure of the recombinant human doppel protein, hDpl(24-152), contains a flexibly disordered "tail" comprising residues 24-51, and a globular domain extending from residues 52 to 149 for which a detailed structure was obtained. The globular domain contains four alpha-helices comprising residues 72-80 (alpha1), 101-115 (alpha2(a)), 117-121 (alpha2(b)), and 127-141 (alpha3), and a short two-stranded anti-parallel beta-sheet comprising residues 58-60 (beta1) and 88-90 (beta2). The fold of the hDpl globular domain thus coincides nearly identically with the structure of the murine Dpl protein. There are close similarities with the human prion protein (hPrP) but, similar to the situation with the corresponding murine proteins, hDpl shows marked local differences when compared to hPrP: the beta-sheet is flipped by 180 degrees with respect to the molecular scaffold formed by the four helices, and the beta1-strand is shifted by two residues toward the C terminus. A large solvent-accessible hydrophobic cleft is formed on the protein surface between beta2 and alpha3, which has no counterpart in hPrP. The helix alpha2 of hPrP is replaced by two shorter helices, alpha2(a) and alpha2(b). The helix alpha3 is shortened by more than two turns when compared with alpha3 of hPrP, which is enforced by the positioning of the second disulfide bond in hDpl. The C-terminal peptide segment 144-149 folds back onto the loop connecting beta2 and alpha2. All but four of the 20 conserved residues in the globular domains of hPrP and hDpl appear to have a structural role in maintaining a PrP-type fold. The conservation of R76, E96, N110 and R134 in hDpl, corresponding to R148, E168, N183 and R208 in hPrP suggests that these amino acid residues might have essential roles in the so far unknown functions of PrP and Dpl in healthy organisms.     

Cyanobacterial phycobilisomes. Role of the linker polypeptides in the assembly of phycocyanin

The phycocyanin-containing segments of the rod substructures of Anabaena variabilis phycobilisomes consist of complexes of phycocyanin with "linker" polypeptides of 27,000 and 32,500 daltons (Yu, M.-H., Glazer, A. N., and Williams, R. C. (1981) J. Biol. Chem. 256, 13130-13136). Complexes (alpha beta)3.27,000, (alpha beta)3.32,500, (alpha beta)6.27,000, [(alpha beta)6.32,500]n, (alpha beta)6.27,000 - (alpha beta)6.32,500 were prepared, where alpha beta represents a monomer of phycocyanin, and 27,000 and 32,500 represent the 27,000- and 32,500-dalton polypeptides, respectively. Tryptic digestion of (alpha beta)3.32,500 leads to a stable (alpha beta)3.28,000 complex which does not form higher aggregates. The 32,500 polypeptide is stable to trypsin in the [(alpha beta)6.32,500]n and (alpha beta)6.27,000 - [(alpha beta)6.32,500]n=1.2 aggregates. Upon trypsin treatment of all 27,000 still assembled into higher aggregates, (alpha beta)6.21,0900 and (alpha beta)6.21,000 - (alpha beta)6.32,500. The spectroscopic properties of phycocyanin-linker polypeptide complexes were not modified by the tryptic cleavages. These results show that the 32,500 polypeptide has two distinct functional domains, a 28,000 portion necessary to the stabilization of a trimeric phycocyanin complex and a 4,500 domain which links consecutive phycocyanin hexamers in the rod substructure. The 27,000 polypeptide likewise has two distinct functional domains: a 21,000 domain stabilizes a trimeric phycocyanin complex, a 6,000 domain is exposed in all of the assembly forms examined. From these and earlier studies, it is concluded that the 6,000 domain functions in the attachment of the rod substructures to the core of the phycobilisome.     

A critical cytoplasmic domain of the interleukin-5 (IL-5) receptor alpha chain and its function in IL-5-mediated growth signal transduction.

Interleukin-5 (IL-5) regulates the production and function of B cells, eosinophils, and basophils. The IL-5 receptor (IL-5R) consists of two distinct membrane proteins, alpha and beta. The alpha chain (IL-5R alpha) is specific to IL-5. The beta chain is the common beta chain (beta c) of receptors for IL-3 and granulocyte-macrophage colony-stimulating factor (GM-CSF). The cytoplasmic domains of both alpha and beta chains are essential for signal transduction. In this study, we generated cDNAs of IL-5R alpha having various mutations in their cytoplasmic domains and examined the function of these mutants by expressing them in IL-3-dependent FDC-P1 cells. The membrane-proximal proline-rich sequence of the cytoplasmic domain of IL-5R alpha, which is conserved among the alpha chains of IL-5R, IL-3R, and GM-CSF receptor (GM-CSFR), was found to be essential for the IL-5-induced proliferative response, expression of nuclear proto-oncogenes such as c-jun, c-fos, and c-myc, and tyrosine phosphorylation of cellular proteins including JAK2 protein-tyrosine kinase. In addition, analysis using chimeric receptors which consist of the extracellular domain of IL-5R alpha and the cytoplasmic domain of beta c suggested that dimerization of the cytoplasmic domain of beta c may be an important step in activating the IL-5R complex and transducing intracellular growth signals.     

Role of the interleukin 5 receptor system in hematopoiesis: molecular basis for overlapping function of cytokines.

Interleukin 5 (IL-5) is a kind of peptide hormone released from T lymphocytes of mammals infected with microorganisms or parasites. It is an acidic glycoprotein with a molecular mass of 40 to 50 kDa that consists of a homodimer of polypeptides. It controls hematopoiesis so that it increases natural immunity. In the mouse, IL-5 acts on committed B cells to induce differentiation into Ig-producing cells and on common progenitors for CD5+ pre-B cells and CD5+ macrophages to support their survival. The antibodies secreted by CD5+ B cells seem to be responsible for the primary protection against the infection with microorganisms or parasites. It also supports the growth and/or differentiation of eosinophil precursor and mature eosinophils, which can be effective for the removal of parasites in combination with the antibodies against them. Murine IL-5 receptor (IL-5R) consists of two different polypeptide chains; alpha chain and beta chain. The IL-5R alpha chain is 60 kDa protein that binds IL-5 with low affinity. The IL-5R beta chain is a 130 kDa protein which does not bind IL-5 by itself but is necessary to form the high affinity IL-5R. The beta chain was identified by using one of the anti-IL-5R mAb and anti-IL-3R mAb as the IL-3R homologue. This beta chain is also used as the beta chain of GM-CSF receptor. This fact suggests that there is a common signaling mechanism among these cytokines and efficient cooperation among them. At the same time, these findings may explain the overlapping role of these cytokines in the development of granulocytes.     

Characterization of the two heavy chains of the T3 complex on the surface of human T lymphocytes

The T3 complex has been defined by a group of monoclonal antibodies which react with all human peripheral blood T lymphocytes and a subpopulation of thymocytes. This membrane structure includes glycoproteins of 44 (alpha), 37 (beta), 25 (gamma), and 20 kDa (delta) as well as a nonglycosylated polypeptide of 20 kDa (epsilon). The characterization of the alpha and beta chains has been of particular interest because they may constitute the T cell receptor for antigen. Here we show that the T3 complex prepared by immunoprecipitation from T lymphocytes of a leukemic patient (Sezary syndrome) displays an unusually strong association of the alpha and beta chains with the 20/25-kDa T3 proteins. The alpha and beta chains (48 and 44 kDa) were co-precipitated by anti-20-kDa T3 monoclonal antibodies as a disulfide-linked 90-kDa heterodimer. A minor 220-kDa multimer composed of proteins similar to the alpha and beta chains was also present in these immunoprecipitates. This multimer could be independently precipitated with a new monoclonal antibody WT-31, which detects the larger polypeptide chains of the T3 complex on all human T lymphocytes. After removal of N-linked oligosaccharides, both the alpha and beta chain were found to have 33-kDa peptide backbones with distinct isoelectric points. Using a monoclonal reagent T40/25, a 90-kDa heterodimer, consisting of 40- and 49-kDa chains with peptide backbones of 34 kDa was found to be T3-associated on the T leukemic cell line HPB-ALL. When the alpha and beta chains from the Sezary patient were compared with the corresponding chains from HPB-ALL by peptide mapping, large differences were observed. Taken together, the data presented here provide strong evidence that the T cell receptor for antigen is part of the T3 complex on the surface of human T lymphocytes.     

Three-dimensional structure of a highly thermostable enzyme, 3-isopropylmalate dehydrogenase of Thermus thermophilus at 2.2 A resolution.

The three-dimensional structure of the highly thermostable 3-isopropylmalate dehydrogenase (IPMDH) from Thermus thermophilus has been determined by the multiple isomorphous replacement method and refined to 2.2 A resolution. The final R-factor is 0.185 for 20,307 reflections. The crystal asymmetric unit has one subunit consisting of 345 amino acid residues. The polypeptide chain of this subunit is folded into two domains (first and second domains) with parallel alpha/beta motifs. The domains are similar in their conformations and folding topologies, but differ from those of the NAD-binding domains of such well-known enzymes as the alcohol and lactate dehydrogenases. A beta-strand that is a part of the long arm-like polypeptide protruding from the second domain comes into contact with another subunit and contributes to the formation of an isologous dimer with a crystallographic 2-fold symmetry. Close subunit contacts are also present at two alpha-helices in the second domain. These helices strongly interact hydrophobically with the corresponding helices of the other subunit to form a hydrophobic core at the center of the dimer. Two large pockets that exist between the first domain of one subunit and the second domain of the other include the amino acid residues responsible for substrate binding. These results indicate that the dimeric form is essential for the IPMDH to express enzymatic activity and that the close subunit contact at the hydrophobic core is important for the thermal stability of the enzyme.     

Amino acid sequences of the aplpha and beta chains of adult hemoglobin of the tupai, Tupaia glis.

Globin prepared from hemoglobin of adult tupai (Tupaia glis) was separated into alpha and beta polypeptide chains by CM-cellulose column chromatography. The S-aminoethylated alpha polypeptide chain and S-carboxymethylated beta polypeptide chain were each digested with trypsin, and the sequences of all the peptides thus obtained were established. The ordering of these tryptic peptides in the alpha and beta polypeptide chains was deduced from the homology of their primary structures with that of human adult hemoglobin. In this way the primary structures of the alpha and beta polypeptide chains of tupai hemoglobin were established; 27 amino acids in the alpha polypeptide chain and 26 in the beta chain differ from those in human adult hemoglobin.