The controlling roles of Trp60 and Trp95 in beta2-microglobulin function, folding and amyloid aggregation properties

Amyloidosis associated to hemodialysis is caused by persistently high β₂-microglobulin (β₂m) serum levels. β₂m is an intrinsically amyloidogenic protein whose capacity to assemble into amyloid fibrils in vitro and in vivo is concentration dependent; no β₂m genetic variant is known in the human population. We investigated the roles of two evolutionary conserved Trp residues in relation to β₂m structure, function and folding/misfolding by means of a combined biophysical and functional approach. We show that Trp60 plays a functional role in promoting the association of β₂m in class I major histocompatibility complex; it is exposed to the solvent at the apex of a protein loop in order to accomplish such function. The Trp60 → Gly mutation has a threefold effect: it stabilizes β₂m, inhibits β₂m amyloidogenic propensity and weakens the interaction with the class I major histocompatibility complex heavy chain. On the contrary, Trp95 is buried in the β₂m core; the Trp95 → Gly mutation destabilizes the protein, which is unfolded in solution, yielding nonfibrillar β₂m aggregates. Trp60 and Trp95 therefore play differential and complementary roles in β₂m, being relevant for function (Trp60) and for maintenance of a properly folded structure (Trp95) while affecting in distinct ways the intrinsic propensity of wild-type β₂m towards self-aggregation into amyloid fibrils.     

Solution Structure of the Catalytic Domain of the Mitochondrial Protein ICT1 That Is Essential for Cell Vitality

The ICT1 protein was recently reported to be a component of the human mitoribosome and to have codon-independent peptidyl-tRNA hydrolysis activity via its conserved GGQ motif, although little is known about the detailed mechanism. Here, using NMR spectroscopy, we determined the solution structure of the catalytic domain of the mouse ICT1 protein that lacks an N-terminal mitochondrial targeting signal and an unstructured C-terminal basic-residue-rich extension, and we examined the effect of ICT1 knockdown (mediated by small interfering RNA) on mitochondria in HeLa cells using flow cytometry. The catalytic domain comprising residues 69-162 of the 206-residue full-length protein forms a structure with a β1-β2-α1-β3-α2 topology and a structural framework that resembles the structure of GGQ-containing domain 3 of class 1 release factors (RFs). Half of the structure, including the GGQ-containing loop, has essentially the same sequence and structure as those in RFs, consistent with the peptidyl-tRNA hydrolysis activity of ICT1 on the mitoribosome, which is analogous to RFs. However, the other half of the structure differs in shape from the corresponding part of RF domain 3 in that in ICT1, an α-helix (α1), instead of a β-turn, is inserted between strand β2 and strand β3. A characteristic groove formed between α1 and the three-stranded antiparallel β-sheet was identified as a putative ICT1-specific functional site by a structure-based alignment. In addition, the structured domain that recognizes stop codons in RFs is replaced in ICT1 by a C-terminal basic-residue-rich extension. It appears that these differences are linked to a specific function of ICT1 other than the translation termination mediated by RFs. Flow cytometry analysis showed that the knockdown of ICT1 results in apoptotic cell death with a decrease in mitochondrial membrane potential and mass. In addition, cytochrome c oxidase activity in ICT1 knockdown cells was decreased by 35% compared to that in control cells. These results indicate that ICT1 function is essential for cell vitality and mitochondrial function.     

Conformational Ensemble and Biological Role of the TCTP Intrinsically Disordered Region: Influence of Calcium and Phosphorylation

The translationally controlled tumor protein (TCTP) is a multifunctional protein that may interact with many other biomolecules, including itself. The experimental determinations of TCTP structure revealed a folded core domain and an intrinsically disordered region, which includes the first highly conserved TCTP signature, but whose role in the protein functions remains to be elucidated. In this work, we combined NMR experiments and MD simulations to characterize the conformational ensemble of the TCTP intrinsically disordered loop, in the presence or not of calcium ions and with or without the phosphorylation of Ser46 and Ser64. Our results show that these changes in the TCTP electrostatic conditions induce significant shifts of its conformational ensemble toward structures more or less extended in which the disordered loop is pulled away or folded against the core domain. Particularly, these conditions impact the transient contacts between the two highly conserved signatures of the protein. Moreover, both experimental and theoretical data show that the interface of the non-covalent TCTP dimerization involves its second signature which suggests that this region might be involved in protein–protein interaction. We also show that calcium hampers the formation of TCTP dimers, likely by favoring the competitive binding of the disordered loop to the dimerization interface. All together, we propose that the TCTP intrinsically disordered region is involved in remodeling the core domain surface to modulate its accessibility to its partners in response to a variety of cellular conditions.     

Crystal structure of cce_0566 from Cyanothece 51142, a protein associated with nitrogen fixation in the DUF269 family

The crystal structure for cce_0566 (171 aa, 19.4 kDa), a DUF269 annotated protein from the diazotrophic cyanobacterium Cyanothece sp. ATCC 51142, was determined to 1.60 Å resolution. Cce_0566 is a homodimer with each molecule composed of eight α-helices folded on one side of a three strand anti-parallel β-sheet. Hydrophobic interactions between the side chains of largely conserved residues on the surface of each β-sheet hold the dimer together. The fold observed for cce_0566 may be unique to proteins in the DUF269 family, hence, the protein may also have a function unique to nitrogen fixation. A solvent accessible cleft containing conserved charged residues near the dimer interface could represent the active site or ligand-binding surface for the protein’s biological function.Structured summary of protein interactionsDUF269 and DUF269 bind by x-ray crystallography (View interaction)     

TcR Recognition of the MHC-Peptide Dimer: Structural Properties of a Ternary Complex

We have developed a method that utilizes site-specific mutation data, sequence analysis, immunological data and free-energy minimization, to determine structural features of the ternary complex formed by the T-cell receptor (TcR) and the class I major histocompatibility complex (MHC) molecule bound by peptide. The analysis focuses on the mouse K^dMHC system, for which a large set of clones with sequenced T-cell receptors is available for specific peptides.The general philosophy is to reduce the uncertainties and computation time in a free-energy minimization procedure by identifying and imposing experimental constraints. In addition to assessing compatibility with various kinds of immunological data, we are particularly interested in differentiating the structural features peculiar to this particular system from generic features, and in ascertaining the robustness of the structure; i.e. determining, in so far as possible, the variations in the structure that leave its compatibility with experiment unaltered from those that do not. This last is equivalent to recognizing that certain features of the model are presented with a reasonable degree of confidence, while others remain highly tentative.The central conclusion in the former category is a placement of the TcR on the K^dpeptide complex, which has its β₂, β₃and α₃loops (i.e. the second and third complementarity-determining region of the TcR β chain, and the third complementarity-determining region of the α chain) covering the peptide; the α₁and α₂loops covering the MHC α₁helix; the α₂loop interacting with residues on the MHC β sheet; and the β₁and (part of) the β₂loops covering the α₂MHC helix. More specifically, our findings include the following.(1) A highly conserved histidine residue in the first complementarity- determining region of the TcR β chain (β:CDR1) points outward and inter- acts with highly conserved side-chains on the MHC α₂helix. (2) The amino-terminal portion of the β₂loop interacts with the carboxyl portion of the peptide. A particularly important interaction is K4 of the loop interacting with E8 of the peptide. (3) Charged side-chains of the 11-residue TcR α₂loop interact with conserved charged side-chains at positions 44, 58, 61 and 68 on the MHC. (4) The TcR β₃loop interacts with the amino-terminal part of the peptide, up through position 4. (5) the TcR α₃loop interacts with the central portion of the peptide and stacks against the β₂loop. (6) Because of the interaction between the β₂loop and the peptide, and stacking of β₂on α₃, α₃gene andV_βgene selection can be correlated. (7) Using the topology of the recently solved TcR α chain we predict that the α₂loop interacts with the loop on the MHC β sheet floor, which encompasses residues 42 to 44.     

Horse Prion Protein NMR Structure and Comparisons with Related Variants of the Mouse Prion Protein

The NMR structure of the horse (Equus caballus) cellular prion protein at 25 °C exhibits the typical PrP^C [cellular form of prion protein (PrP)] global architecture, but in contrast to most other mammalian PrP^Cs, it contains a well-structured loop connecting the β2 strand with the α2 helix. Comparison with designed variants of the mouse prion protein resulted in the identification of a single amino acid exchange within the loop, D167S, which correlates with the high structural order of this loop in the solution structure at 25 °C and is unique to the PrP sequences of equine species. The β2-α2 loop and the α3 helix form a protein surface epitope that has been proposed to be the recognition area for a hypothetical chaperone, “protein X,” which would promote conversion of PrP^C into the disease-related scrapie form and thus mediate intermolecular interactions related to the transmission barrier for transmissible spongiform encephalopathies (TSEs) between different species. The present results are evaluated in light of recent indications from in vivo experiments that the local β2-α2 loop structure affects the susceptibility of transgenic mice to TSEs and the fact that there are no reports on TSE in horses.     

Ligand Binding Reveals a Role for Heme in Translationally-Controlled Tumor Protein Dimerization

The translationally-controlled tumor protein (TCTP) is a highly conserved, ubiquitously expressed, abundant protein that is broadly distributed among eukaryotes. Its biological function spans numerous cellular processes ranging from regulation of the cell cycle and microtubule stabilization to cell growth, transformation, and death processes. In this work, we propose a new function for TCTP as a “buffer protein” controlling cellular homeostasis. We demonstrate that binding of hemin to TCTP is mediated by a conserved His-containing motif (His⁷⁶His⁷⁷) followed by dimerization, an event that involves ligand-mediated conformational changes and that is necessary to trigger TCTP''s cytokine-like activity. Mutation in both His residues to Ala prevents hemin from binding and abrogates oligomerization, suggesting that the ligand site localizes at the interface of the oligomer. Unlike heme, binding of Ca²⁺ ligand to TCTP does not alter its monomeric state; although, Ca²⁺ is able to destabilize an existing TCTP dimer created by hemin addition. In agreement with TCTP''s proposed buffer function, ligand binding occurs at high concentration, allowing the “buffer” condition to be dissociated from TCTP''s role as a component of signal transduction mechanisms.     

Solution structure of β2-microglobulin and insights into fibrillogenesis

The solution structure of human β₂-microglobulin (β₂-m) was determined by ¹H NMR spectroscopy and restrained modeling calculations. Compared to the crystal structure of type I major histocompatibility complex (MHC-I), where the protein is associated to the heavy-chain component, several differences are observed, i.e., increased separation between strands A and B, displacements of strand C′ and loop DE, shortening of strands D and E. These modifications can be considered as the prodromes of the amyloid transition. Even minor charge changes in response to pH, as is the case with H31 imidazole protonation, trigger the transition that starts with unpairing of strand A. The same mechanism accounts for the partial unfolding and fiber formation subsequent to Cu²⁺ binding which is shown to occur primarily at H31. Solvation of the protected regions in MHC-I decreases the tertiary packing by breaking the contiguity of the surface hydrophobic patches via surface charge cluster. Mutants or truncated forms of β₂-m can be designed to remove the instability from H31 titration or to enhance the instability through surface charge suppression. By monitoring the conformational evolution of wild-type protein and variants thereof, either in response or absence of external perturbation, valuable insights into intermediate structure and fibrillogenesis mechanisms are gained.     

Characterization of human β,β-carotene-15,15′-monooxygenase (BCMO1) as a soluble monomeric enzyme

The formal first step in in vitamin A metabolism is the conversion of its natural precursor β,β-carotene (C40) to retinaldehyde (C20). This reaction is catalyzed by the enzyme β,β-carotene-15,15′-monooxygenase (BCMO1). BCMO1 has been cloned from several vertebrate species, including humans. However, knowledge about this protein’s enzymatic and structural properties is scant. Here we expressed human BCMO1 in Spodoptera frugiperda 9 insect cells. Recombinant BCMO1 is a soluble protein that displayed Michaelis–Menten kinetics with a K_M of 14 μM for β,β-carotene. Though addition of detergents failed to increase BCMO1 enzymatic activity, short chain aliphatic detergents such as C₈E₄ and C₈E₆ decreased enzymatic activity probably by interacting with the substrate binding site. Thus we purified BCMO1 in the absence of detergent. Purified BCMO1 was a monomeric enzymatically active soluble protein that did not require cofactors and displayed a turnover rate of about 8 molecules of β,β-carotene per second. The aqueous solubility of BCMO1 was confirmed in mouse liver and mammalian cells. Establishment of a protocol that yields highly active homogenous BCMO1 is an important step towards clarifying the lipophilic substrate interaction, reaction mechanism and structure of this vitamin A forming enzyme.     

Crystal structure of the YdjC-family protein TTHB029 from Thermus thermophilus HB8: structural relationship with peptidoglycan N-acetylglucosamine deacetylase

The YdjC-family protein is widely distributed, from human to bacteria, but so far no three-dimensional structure and functional analysis of this family of proteins has been reported. We determined the three-dimensional structure of the YdjC homolog TTHB029 at a resolution of 2.9 Å. The overall structure of the monomer consists of (βα)-barrel fold forming a homodimer. Asp21, His60, and His127 residues coordinate to Mg²⁺ as a possible active site. TTHB029 shows structural similarity to the peptidoglycan N-acetylglucosamine deacetylase from Streptococcus pneumoniae (SpPgdA). The active site groove of SpPgdA includes the Zn²⁺ coordinated to Asp276, His326, and His330. Despite the low sequence identity, metal-binding residues of Asp-His-His were conserved among the two enzymes. There were definitive differences, however, in that one of the histidines of the metal-binding site was substituted for the other histidine located on the other loop. Moreover, these important metal-binding residues and the residues of the presumed active site are fully conserved in YdjC-family protein.     

Solution structure and activation mechanism of ubiquitin-like small archaeal modifier proteins

In archaea, two ubiquitin-like small archaeal modifier protein (SAMPs) were recently shown to be conjugated to proteins in vivo. SAMPs display homology to bacterial MoaD sulfur transfer proteins and eukaryotic ubiquitin-like proteins, and they share with them the conserved C-terminal glycine-glycine motif. Here, we report the solution structure of SAMP1 from Methanosarcina acetivorans and the activation of SAMPs by an archaeal protein with homology to eukaryotic E1 enzymes. Our results show that SAMP1 possesses a β-grasp fold and that its hydrophobic and electrostatic surface features are similar to those of MoaD. M. acetivorans SAMP1 exhibits an extensive flexible surface loop between helix-2 and the third strand of the β-sheet, which contributes to an elongated surface groove that is not observed in bacterial ubiquitin homologues and many other SAMPs. We provide in vitro biochemical evidence that SAMPs are activated in an ATP-dependent manner by an E1-like enzyme that we have termed E1-like SAMP activator (ELSA). We show that activation occurs by formation of a mixed anhydride (adenylate) at the SAMP C-terminus and is detectable by SDS-PAGE and electrospray ionization mass spectrometry.     

Prion Protein mPrP[F175A](121-231): Structure and Stability in Solution

The three-dimensional structures of prion proteins (PrPs) in the cellular form (PrP^C) include a stacking interaction between the aromatic rings of the residues Y169 and F175, where F175 is conserved in all but two so far analyzed mammalian PrP sequences and where Y169 is strictly conserved. To investigate the structural role of F175, we characterized the variant mouse prion protein mPrP[F175A](121-231). The NMR solution structure represents a typical PrP^C-fold, and it contains a 3₁₀-helical β2-α2 loop conformation, which is well defined because all amide group signals in this loop are observed at 20 °C. With this “rigid‐loop PrP^C” behavior, mPrP[F175A](121-231) differs from the previously studied mPrP[Y169A](121-231), which contains a type I β-turn β2-α2 loop structure. When compared to other rigid‐loop variants of mPrP(121-231), mPrP[F175A](121-231) is unique in that the thermal unfolding temperature is lowered by 8 °C. These observations enable further refined dissection of the effects of different single-residue exchanges on the PrP^C conformation and their implications for the PrP^C physiological function.     

A sequence predicted to form a stem–loop is proposed to be required for formation of an RNA–protein complex involving the 3'UTR of β-subunit F0F1-ATPase mRNA

ATP-synthase assembly requires coordinated control of ATP mRNA translation; this may e.g. occur through the formation of mRNA–protein complexes. In this study we aim to identify sequences in the 3'UTR of the β-subunit F₁-ATPase mRNA necessary for RNA–protein complex formation. We examined the interaction between a brain cytoplasmic protein extract and in vitro-synthesized β-subunit 3'UTR probes containing successive accumulative 5'- and 3'-deletions, as well as single subregion deletions, with or without poly(A) tail. Using electrophoretic mobility shift assays we found that two major RNA–protein complexes (here called RPC1 and RPC2) were formed with the full-length 3'UTR. The RPC2 complex formation was fully dependent on the presence of both the poly(A) tail and one subregion directly adjacent to it. For RPC1 complex formation, a 3'UTR sequence stretch (experimentally divided into three subregions) adjacent to but not including the poly(A) tail was necessary. This sequence stretch includes a conserved 40-nucleotide region that, according to the structure prediction program mfold, is able to fold into a characteristic stem–loop structure. Since the formation of the RPC1 complex was not dependent on a conventional sequence motif in the 3'UTR of the β-subunit mRNA but rather on the presence of the predicted stem–loop-forming region as such, we hypothetize that this RNA region, by forming a stem–loop in the 3'UTR β-subunit mRNA, is necessary for formation of the RNA–protein complex.     

The structural analysis and the role of calcium binding site for thermal stability in mannanase

Mannanase is an important enzyme involved in the degradation of mannan, production of bioactive oligosaccharides, and biobleaching of kraft pulp. Mannanase must be thermostable for use in industrial applications. In a previous study, we found that the thermal stability of mannanase from Streptomyces thermolilacinus (StMan) and Thermobifida fusca (TfMan) is enhanced by calcium. Here, we investigated the relationship between the three-dimensional structure and primary sequence to identify the putative calcium-binding site. The results of site-directed mutagenesis experiments indicated that Asp-285, Glu-286, and Asp-287 of StMan (StDEDAAAdC) and Asp-264, Glu-265, and Asp-266 of TfMan (TfDEDAAAdC) were the key residues for calcium binding affinity. Isothermal titration calorimetry revealed that the catalytic domain of StMan and TfMan (StMandC and TfMandC, respectively) bound calcium with a K_a of 3.02 × 10⁴ M⁻¹ and 1.52 × 10⁴ M⁻¹, respectively, both with stoichiometry consistent with one calcium-binding site per molecule of enzyme. Non-calcium-binding mutants (StDEDAAAdC and TfDEDAAAdC) did not show any calorimetric change. From the primary structure alignment of several mannanases, the calcium-binding site was found to be highly conserved in GH5 bacterial mannanases. This is the first study indicating enhanced thermal stability of GH5 bacterial mannanases by calcium binding.     

Molecular structure and metal-binding properties of the periplasmic CopK protein expressed in Cupriavidus metallidurans CH34 during copper challenge

The copK gene is localized on the pMOL30 plasmid of Cupriavidus metallidurans CH34 within the complex cop cluster of genes, for which 21 genes have been identified. The expression of the corresponding periplasmic CopK protein is strongly upregulated in the presence of copper, leading to a high periplasmic accumulation. The structure and metal-binding properties of CopK were investigated by NMR and mass spectrometry. The protein is dimeric in the apo state with a dissociation constant in the range of 10^- 5 M estimated from analytical ultracentrifugation. Mass spectrometry revealed that CopK has two high-affinity Cu(I)-binding sites per monomer with different Cu(I) affinities. Binding of Cu(II) was observed but appeared to be non-specific. The solution structure of apo-CopK revealed an all-β fold formed of two β-sheets in perpendicular orientation with an unstructured C-terminal tail. The dimer interface is formed by the surface of the C-terminal β-sheet. Binding of the first Cu(I)-ion induces a major structural modification involving dissociation of the dimeric apo-protein. Backbone chemical shifts determined for the 1Cu(I)-bound form confirm the conservation of the N-terminal β-sheet, while the last strand of the C-terminal sheet appears in slow conformational exchange. We hypothesize that the partial disruption of the C-terminal β-sheet is related to dimer dissociation. NH-exchange data acquired on the apo-protein are consistent with a lower thermodynamic stability of the C-terminal sheet. CopK contains seven methionine residues, five of which appear highly conserved. Chemical shift data suggest implication of two or three methionines (Met54, Met38, Met28) in the first Cu(I) site. Addition of a second Cu(I) ion further increases protein plasticity. Comparison of the structural and metal-binding properties of CopK with other periplasmic copper-binding proteins reveals two conserved features within these functionally related proteins: the all-β fold and the methionine-rich Cu(I)-binding site.     

The bacterial ribonuclease P holoenzyme requires specific, conserved residues for efficient catalysis and substrate positioning

RNase P is an RNA-based enzyme primarily responsible for 5′-end pre-tRNA processing. A structure of the bacterial RNase P holoenzyme in complex with tRNA^Phe revealed the structural basis for substrate recognition, identified the active site location, and showed how the protein component increases functionality. The active site includes at least two metal ions, a universal uridine (U52), and P RNA backbone moieties, but it is unclear whether an adjacent, bacterially conserved protein loop (residues 52–57) participates in catalysis. Here, mutagenesis combined with single-turnover reaction kinetics demonstrate that point mutations in this loop have either no or modest effects on catalytic efficiency. Similarly, amino acid changes in the ‘RNR’ region, which represent the most conserved region of bacterial RNase P proteins, exhibit negligible changes in catalytic efficiency. However, U52 and two bacterially conserved protein residues (F17 and R89) are essential for efficient Thermotoga maritima RNase P activity. The U52 nucleotide binds a metal ion at the active site, whereas F17 and R89 are positioned >20 Å from the cleavage site, probably making contacts with N₋₄ and N₋₅ nucleotides of the pre-tRNA 5′-leader. This suggests a synergistic coupling between transition state formation and substrate positioning via interactions with the leader.