Crystal structure of the N-terminal region of human Topoisomerase IIβ binding protein 1

Human DNA Topoisomerase IIβ binding protein 1 (TopBP1) is a modulating protein that plays an essential role in the response to DNA damage. The N-terminal region of TopBP1, which contains predicted BRCA1-carboxy terminal (BRCT) domains 1 and 2, binds to Rad9, a component of the cell cycle checkpoint clamp Rad9-Hus1-Rad1 complex. Here, we report the crystal structure of the TopBP1 N-terminal region (residues 1-290) at 2.4 Å resolution. Interestingly, in addition to the predicted tandem BRCT1-2 repeats (residues 103-284), residues 7-98 form a previously unreported BRCT domain (here, BRCT0). In contrast to both BRCT1 and BRCT2, which possess the conventional phosphopeptide binding residues within a surface pocket, the corresponding pocket in BRCT0 is largely hydrophobic. Structural comparisons together with peptide binding studies indicate that the tandem BRCT1-2 domains are the binding region for phosphorylated Ser387 in Rad9.     

Revisiting the NMR structure of the ultrafast downhill folding protein gpW from bacteriophage λ

GpW is a 68-residue protein from bacteriophage λ that participates in virus head morphogenesis. Previous NMR studies revealed a novel α+β fold for this protein. Recent experiments have shown that gpW folds in microseconds by crossing a marginal free energy barrier (i.e., downhill folding). These features make gpW a highly desirable target for further experimental and computational folding studies. As a step in that direction, we have re-determined the high-resolution structure of gpW by multidimensional NMR on a construct that eliminates the purification tags and unstructured C-terminal tail present in the prior study. In contrast to the previous work, we have obtained a full manual assignment and calculated the structure using only unambiguous distance restraints. This new structure confirms the α+β topology, but reveals important differences in tertiary packing. Namely, the two α-helices are rotated along their main axis to form a leucine zipper. The β-hairpin is orthogonal to the helical interface rather than parallel, displaying most tertiary contacts through strand 1. There also are differences in secondary structure: longer and less curved helices and a hairpin that now shows the typical right-hand twist. Molecular dynamics simulations starting from both gpW structures, and calculations with CS-Rosetta, all converge to our gpW structure. This confirms that the original structure has strange tertiary packing and strained secondary structure. A comparison of NMR datasets suggests that the problems were mainly caused by incomplete chemical shift assignments, mistakes in NOE assignment and the inclusion of ambiguous distance restraints during the automated procedure used in the original study. The new gpW corrects these problems, providing the appropriate structural reference for future work. Furthermore, our results are a cautionary tale against the inclusion of ambiguous experimental information in the determination of protein structures.     

Crystal structure of the central coiled-coil domain from human liprin-β2

Liprins are a conserved family of scaffolding proteins important for the proper regulation and development of neuronal synapses. Humans have four liprin-αs and two liprin-βs which all contain long coiled-coil domains followed by three tandem SAM domains. Complex interactions between the coiled-coil and SAM domains are thought to create liprin scaffolds, but the structural and biochemical properties of these domains remain largely uncharacterized. In this study we find that the human liprin-β2 coiled-coil forms an extended dimer. Several protease-resistant subdomains within the liprin-β1 and liprin-β2 coiled-coils were also identified. A 2.0 ? crystal structure of the central, protease-resistant core of the liprin-β2 coiled-coil reveals a parallel helix orientation. These studies represent an initial step toward determining the overall architecture of liprin scaffolds and understanding the molecular basis for their synaptic functions.     

Quantitative analysis of the bacteriophage Qβ infection cycle

In this study, the infection cycle of bacteriophage Qβ was investigated. Adsorption of bacteriophage Qβ to Escherichia coli is explained in terms of a collision reaction, the rate constant of which was estimated to be 4 × 10^− 10 ml/cells/min. In infected cells, approximately 130 molecules of β-subunit and 2 × 10⁵ molecules of coat protein were translated in 15 min. Replication of Qβ RNA proceeded in 2 steps—an exponential phase until 20 min and a non-exponential phase after 30 min. Prior to the burst of infected cells, phage RNAs and coat proteins accumulated in the cells at an average of up to 2300 molecules and 5 × 10⁵ molecules, respectively. An average of 90 infectious phage particles per infected cell was released during a single infection cycle up to 105 min.     

Crystal structure of the single cystathionine β-synthase domain-containing protein CBSX1 from Arabidopsis thaliana

The single cystathionine β-synthase (CBS) pair proteins from Arabidopsis thaliana have been identified as being a redox regulator of the thioredoxin (Trx) system. CBSX1 and CBSX2, which are two of the six Arabidopsis cystathione β-synthase domain-containing proteins that contain only a single CBS pair, have close sequence similarity. Recently, the crystal structure of CBSX2 was determined and a significant portion of the internal region was disordered. In this study, crystal structures of full-length CBSX1 and the internal loop deleted (Δloop) form are reported at resolutions of 2.4 and 2.2 Å, respectively. The structures of CBSX1 show that they form anti-parallel dimers along their central twofold axis and have a unique ～155° bend along the side. This is different from the angle of CBSX2, which is suggestive of the flexible nature of the relative angle between the monomers. The biochemical data that were obtained using the deletion as well as point mutants of CBSX1 confirmed the importance of AMP-ligand binding in terms of enhancing Trx activity.     

Crystal structure of the C-terminal globular domain of oligosaccharyltransferase from Archaeoglobus fulgidus at 1.75 Å resolution

Protein N-glycosylation occurs in the three domains of life. Oligosaccharyltransferase (OST) transfers glycan to asparagine in the N-glycosylation sequon. The catalytic subunit of OST is called STT3 in eukaryotes, AglB in archaea, and PglB in eubacteria. The genome of a hyperthermophilic archaeon, Archaeoglobus fulgidus, encodes three AglB paralogs. Two of them are the shortest AglBs across all domains of life. We determined the crystal structure of the C-terminal globular domain of the smallest AglB to identify the minimal structural unit. The Archaeoglobus AglB lacked a β-barrel-like structure, which had been found in other AglB and PglB structures. In agreement, the deletion in a larger Pyrococcus AglB confirmed its dispensability for the activity. By contrast, the Archaeoglobus AglB contains a kinked helix bearing a conserved motif, called DK/MI motif. The lysine and isoleucine residues in the motif participate in the Ser/Thr recognition in the sequon. The Archaeoglobus AglB structure revealed that the kinked helix contained an unexpected insertion. A revised sequence alignment based on this finding identified a variant type of the DK motif with the insertion. A mutagenesis study of the Archaeoglobus AglB confirmed the contribution of this particular type of the DK motif to the activity. When taken together with our previous results, this study defined the classification of OST: one group consisting of eukaryotes and most archaea possesses the DK-type Ser/Thr pocket, and the other group consisting of eubacteria and the remaining archaea possesses the MI-type Ser/Thr pocket. This classification provides a useful framework for OST studies.     

Crystal structure of the signaling helix coiled-coil domain of the β1 subunit of the soluble guanylyl cyclase

Background  

The soluble guanylyl cyclase (sGC) is a heterodimeric enzyme that, upon activation by nitric oxide, stimulates the production of the second messenger cGMP. Each sGC subunit harbor four domains three of which are used for heterodimerization: H-NOXA/H-NOBA domain, coiled-coil domain (CC), and catalytic guanylyl cyclase domain. The CC domain has previously been postulated to be part of a larger CC family termed the signaling helix (S-helix) family. Homodimers of sGC have also been observed but are not functionally active yet are likely transient awaiting their intended heterodimeric partner.     

The binding site for coat protein on bacteriophage Qβ RNA

The site of interaction of phage Qβ coat protein with Qβ RNA was determined by ribonuclease T₁ degradation of complexes of coat protein and [^{3 2}P]-RNA obtained by codialysis of the components from urea into buffer solutions. The degraded complexes were recovered by filtration through nitrocellulose filters, and bound [^{3 2}P] RNA fragments were extracted and separated by polyacrylamide gel electrophoresis. Fingerprinting and further sequence analysis established that the three main fragments obtained (chain lengths 88, 71 and 27 nucleotides) all consist of sequences extending from the intercistronic region to the beginning of the replicase cistron. These results suggest that in the replication of Qβ, as in the case of R17, coat protein acts as a translational repressor by binding to the ribosomal initiation site of the replicase cistron.     

Secondary structure of Qβ RNA

The complete set of possible secondary structures of a variant Qβ RNA sequenced by Schaffner has been found using a computer program which allows G-U pairing as well as the usual Watson-Crick A-U and G-C pairing. Of special interest are those secondary structures with the highest double-strandedness. Omitting G-U pairing, we find the structure with the maximum double-strandedness has a pairing of 62% and exhibits a similarity to the clover leaf structure of tRNA. Including G-U pairing, the complementary strands of RNA are asymmetrical. We find maximum pairings of 71% for both the plus and minus strands. These structures also exhibit a cloverleaf structure. A similar analysis has been carried out for the secondary structure of a larger Qβ variant sequenced by Mills, Kramer and Spiegelman, but in this case there are a large number of secondary structures with the same maximum number of pairs and it is therefore not possible to select a unique structure with the maximum double-strandedness.     

Effects on protein structure and function of replacing tryptophan with 5-hydroxytryptophan: Single-tryptophan mutants of the N-terminal domain of the bacteriophage λ repressor

Conformational energy computations have been carried out on the N-acetyl-N′-methylamide of 5-hydroxytryptophan (5OH-Trp) using ECEPP/3. As observed with tryptophan (Trp), the most preferred conformation about theC ^α ?C ^β bond of the side chain isg ⁺ ort. This preference is reduced to only thet conformational state when 5-hydroxyTrp is in the middle of a right-handed poly(l-alanine)α-helix. A similar result has been obtained with Trp [Pielaet al. (1987),Biopolymers 1987, 1273–1286]. These results suggest that replacement of Trp by its analog 5-hydroxyTrp may be tolerated in anα-helix. To test this hypothesis, we have replaced Trp by 5OH-Trp in the fifth helices of two functionally active mutants of the N-terminal domain of the bacteriophage λ repressor. Computations on the packing of these helices have shown that no significant structural changes result from the replacement of Trp by 5OH-Trp. The DNA-binding activity of these mutants, as assessed indirectly through geometrical parameters, is also unaltered.     

Crystal structure of the sweet-tasting protein thaumatin II at 1.27Å

Thaumatin, an intensely sweet-tasting protein, elicits a sweet taste sensation at 50 nM. Here the X-ray crystallographic structure of one of its variants, thaumatin II, was determined at a resolution of 1.27 ?. Overall structure of thaumatin II is similar to thaumatin I, but a slight shift of the Cα atom of G96 in thaumatin II was observed. Furthermore, the side chain of residue 67 in thaumatin II is highly disordered. Since residue 67 is one of two residues critical to the sweetness of thaumatin, the present results suggested that the critical positive charges at positions 67 and 82 are disordered and the flexibility and fluctuation of these side chains would be suitable for interaction of thaumatin molecules with sweet receptors.     

The solution structure of the human retinoic acid receptor-β DNA-binding domain

Summary The three-dimensional structure of the DNA-binding domain of the human retinoic acid receptor- (hRAR-) has been determined by nuclear magnetic resonance spectroscopy in conjunction with distance geometry, restrained molecular dynamics and iterative relaxation matrix calculations. A total of 1244 distance restraints were obtained from NOE intensities, of which 448 were intra-residue and 796 inter-residue restraints. In addition 23 and 30 dihedral angle restraints were obtained from J-coupling data. The two zinc-finger regions of the 80-amino acid residue protein are followed by two -helices that cross each other perpendicularly. There is a short stretch of b-sheet near the N-terminus. The -helical core of the protein is well determined with a backbone root-mean-square deviation (r.m.s.d.) with respect to the average of 0.18 Å and 0.37 Å when the side chains of residues 31, 32, 36, 61, 62, 65 and 69 are included. The r.m.s.d. for the backbone of residues 5–80 is 0.76 Å. For the first finger (residues 8–28), the r.m.s.d. of the backbone is 0.79 Å. For the second finger (residues 44–62) the r.m.s.d. is 0.64 Å. The overall structure is similar to that of the corresponding domain of the glucocorticoid receptor, although the C-terminal part of the protein is different. The second -helix is two residues shorter and is followed by a well-defined region of extended backbone structure.     

A computational tool to predict the evolutionarily conserved protein–protein interaction hot-spot residues from the structure of the unbound protein

Identifying hot-spot residues – residues that are critical to protein–protein binding – can help to elucidate a protein’s function and assist in designing therapeutic molecules to target those residues. We present a novel computational tool, termed spatial-interaction-map (SIM), to predict the hot-spot residues of an evolutionarily conserved protein–protein interaction from the structure of an unbound protein alone. SIM can predict the protein hot-spot residues with an accuracy of 36–57%. Thus, the SIM tool can be used to predict the yet unknown hot-spot residues for many proteins for which the structure of the protein–protein complexes are not available, thereby providing a clue to their functions and an opportunity to design therapeutic molecules to target these proteins.     

Primary structure of elongation factor 1β from Artemia

cDNA complementary to mRNA coding for the elongation factor EF-1β has been cloned. A γgt 11 cDNA library has been screened with an antiserum against EF-1β which exchanges GDP bound to EF-1α with exogenous GTP during protein synthesis. The derived amino acid sequence corresponds to 208 amino acids including the N-terminal methionine which is absent in the mature protein. About sixty percent of the protein was sequenced by direct protein sequence analysis. Comparison of Artemis salina EF-1β with Escherichia coli EF-Ts shows no evident homology.     

The β1 domain of protein G can replace the chorismate mutase domain of the T-protein

T-protein is composed of chorismate mutase (AroQ(T)) fused to the N-terminus of prephenate dehydrogenase (TyrA). Here, we report the replacement of AroQ(T) with the β1-domain of protein G (Gβ1). The TyrA domain shows a strong dehydrogenase activity within the context of this fusion, and our data indicate that Gβ1-TyrA folds into a dimeric conformation. Amino acid substitutions in the Gβ1 domain of Gβ1-TyrA identified residues involved in stabilizing the TyrA dimeric conformation. Gβ1 substitutions in the N-terminal β-hairpin eliminated Gβ1-TyrA expression, whereas Gβ1-TyrA tolerated Gβ1 substitutions in the C-terminal β-hairpin and in the α-helix. All of the characterized variants folded into a dimeric conformation. The importance of the β2-strand in forming a Gβ1 homo-dimerization interface explains the relevance of the first-β-hairpin in stabilizing the dimeric TyrA protein.     

Crystal structure of the 30 K protein from the silkworm Bombyx mori reveals a new member of the β-trefoil superfamily

The hemolymph of the fifth instar larvae of the silkworm Bombyx mori contains a group of homologous proteins with a molecular weight of approximately 30 kDa, termed B. mori low molecular weight lipoproteins (Bmlps), which account for about 5% of the total plasma proteins. These so-called "30 K proteins" have been reported to be involved in the innate immune response and transportation of lipid and/or sugar. To elucidate their molecular functions, we determined the crystal structure of a 30 K protein, Bmlp7, at 1.91?. It has two distinct domains: an all-α N-terminal domain (NTD) and an all-β C-terminal domain (CTD) of the β-trefoil fold. Comparative structural analysis indicates that Bmlp7 represents a new family, adding to the 14 families currently identified, of the β-trefoil superfamily. Structural comparison and simulation suggest that the NTD has a putative lipid-binding cavity, whereas the CTD has a potential sugar-binding site. However, we were unable to detect the binding of either lipid or sugar. Therefore, further investigations are needed to characterize the molecular function of this protein.     

The incorporation of the A2 protein to produce novel Qβ virus-like particles using cell-free protein synthesis

Virus-like particles (VLPs) have been employed for a number of nanometric applications because they self-assemble, exhibit a high degree of symmetry, and can be genetically and chemically modified. However, high symmetry does not allow for a single unique modification site on the VLP. Here, we demonstrate the co-expression of the cytotoxic A2 protein and the coat protein of the bacteriophage Qβ to form a nearly monodispersed population of novel VLPs. Cell-free protein synthesis allows for direct access and optimization of protein-synthesis and VLP-assembly. The A2 is shown to be incorporated at high efficiency, approaching a theoretical maximum of one A2 per VLP. This work demonstrates de novo production of a novel VLP, which contains a unique site that has the potential for future nanometric engineering applications.     

Crystal structure of the complex mAb 17.2 and the C-terminal region of Trypanosoma cruzi P2β protein: implications in cross-reactivity

Patients with Chronic Chagas'' Heart Disease possess high levels of antibodies against the carboxyl-terminal end of the ribosomal P2ß protein of Trypanosoma cruzi (TcP2ß). These antibodies, as well as the murine monoclonal antibody (mAb) 17.2, recognize the last 13 amino acids of TcP2ß (called the R13 epitope: EEEDDDMGFGLFD) and are able to cross-react with, and stimulate, the ß1 adrenergic receptor (ß1-AR). Indeed, the mAb 17.2 was able to specifically detect human β1-AR, stably transfected into HEK cells, by flow cytometry and to induce repolarisation abnormalities and first degree atrioventricular conduction block after passive transfer to naïve mice. To study the structural basis of this cross-reactivity, we determined the crystal structure of the Fab region of the mAb 17.2 alone at 2.31 Å resolution and in complex with the R13 peptide at 1.89 Å resolution. We identified as key contact residues on R13 peptide Glu3, Asp6 and Phe9 as was previously shown by alanine scanning. Additionally, we generated a model of human β1-AR to elucidate the interaction with anti-R13 antibodies. These data provide an understanding of the molecular basis of cross-reactive antibodies induced by chronic infection with Trypanosoma cruzi.