Project description:The prion protein has garnered considerable interest because of its involvement in prion disease as well as its unresolved cellular function. The octarepeat region in the flexible N-domain is capable of binding copper through multiple coordination modes. Under conditions of low pH and low Cu(2+) concentration, the four octarepeats (ORs) cooperatively coordinate a single copper ion. Based on the average structure of the PHGG and GWGQ portions of a copper-free OR(2) model from molecular dynamics simulations, the starting structures of the OR(4) complex could be constructed by assembling the repeating structure of PHGG and GWGQ fragments. The resulting model contains a preformed site suitable for Cu(2+) coordination. Molecular dynamics simulations of Cu(2+) bound to the assembled OR(4) model (Cu:OR(4)) reveal a close association of specific Trp and Gly residues with the Cu(2+) center. This low Cu(2+)-occupancy form of prion protein is redox-active and can readily initiate cleavage of the OR region, mediated by reactive oxygen species generated by Cu(+). The OR region is known to be required for beta-cleavage, as are the Trp residues within the OR region. The beta-cleaved form of the prion protein accumulates in amyloid fibrils. Hence, the close approach of Trp and Gly residues to the Cu(2+) coordination site in the low Cu(2+)-occupancy form of the OR region may signal an important interaction for the initiation of prion disease.

Project description:An increasing number of proteins are being shown to assemble into amyloid structures that lead to pathological states. Among them, mammalian prions outstand due to their ability to transmit the pathogenic conformation, becoming thus infectious. The structural conversion of the cellular prion protein (PrP(C)), into its misfolded pathogenic form (PrP(Sc)) is the central event of prion-driven pathologies. The study of the structural properties of intracellular amyloid aggregates in general and of prion-like ones in particular is a challenging task. In this context, the evidence that the inclusion bodies formed by amyloid proteins in bacteria display amyloid-like structural and functional properties make them a privileged system to model intracellular amyloid aggregation.Here we provide the first demonstration that recombinant murine PrP and its C-terminal domain (90-231) attain amyloid conformations inside bacteria. Moreover, the inclusions formed by these two PrP proteins display conformational diversity, since they differ in fibril morphology, binding affinity to amyloid dyes, stability, resistance to proteinase K digestion and neurotoxicity.Overall, our results suggest that modelling PrP amyloid formation in microbial cell factories might open an avenue for a better understanding of the structural features modulating the pathogenic impact of this intriguing protein.

Project description:Prion diseases are associated with the misfolding of the prion protein (PrP) from its normal cellular form (PrPC ) to its infectious scrapie form (PrPSc ). Post-translational modifications in PrP in vivo can play an important role in modulating the process of misfolding. To gain more insight into the effects of post-translational modifications in PrP structure and dynamics and to test the hypothesis that such modifications can interact with the protein, we have performed molecular dynamics simulations of diglycosylated human PrPC bound to a lipid bilayer via a glycophosphatidylinositol anchor. Multiple simulations were performed at three different pH ranges to explore pH effects on structure and dynamics. In contrast to simulations of protein-only PrPC , no large effects were observed upon lowering the pH of the system. The protein tilted toward the membrane surface in all of the simulations and the putative PrPSc oligomerization sites became inaccessible, thereby offering a possible protective mechanism against PrPSc -induced misfolding of PrPC .

Project description:TAL (transcriptional activator-like) effectors (TALEs) are DNA-binding proteins, containing a modular central domain that recognizes specific DNA sequences. Recently, the crystallographic studies of TALEs revealed the structure of DNA-recognition domain. In this article, molecular dynamics (MD) simulations are employed to study two crystal structures of an 11.5-repeat TALE, in the presence and absence of DNA, respectively. The simulated results indicate that the specific binding of RVDs (repeat-variable diresidues) with DNA leads to the markedly reduced fluctuations of tandem repeats, especially at the two ends. In the DNA-bound TALE system, the base-specific interaction is formed mainly by the residue at position 13 within a TAL repeat. Tandem repeats with weak RVDs are unfavorable for the TALE-DNA binding. These observations are consistent with experimental studies. By using principal component analysis (PCA), the dominant motions are open-close movements between the two ends of the superhelical structure in both DNA-free and DNA-bound TALE systems. The open-close movements are found to be critical for the recognition and binding of TALE-DNA based on the analysis of free energy landscape (FEL). The conformational analysis of DNA indicates that the 5' end of DNA target sequence has more remarkable structural deformability than the other sites. Meanwhile, the conformational change of DNA is likely associated with the specific interaction of TALE-DNA. We further suggest that the arrangement of N-terminal repeats with strong RVDs may help in the design of efficient TALEs. This study provides some new insights into the understanding of the TALE-DNA recognition mechanism.

Project description:Cytochrome c4 was isolated from cells of Pseudomonas aeruginosa, Pseudomonas stutzeri and Azotobacter vinelandii. The dihaem nature, Mr of approx. 20,000 and ferrohaem spectra in the region of the alpha- and beta-peaks define this family of cytochromes c. The behaviour of the holocytochromes in SDS was atypical, but removal of the haem groups resulted in a normal migration. In all three organisms most of the cytochrome c4 was tightly bound to the membrane, but some free cytochrome was detected. The membrane-attached cytochrome could be extracted with butanol, and this solubilized form was then indistinguishable in properties from the free form. Denitrifying rather than aerobic growth conditions hardly affected the total cytochrome c4 in the two pseudomonads, but there was slightly more free form and less membrane-attached form in denitrifying growth. The nature of the attachment of cytochrome c4 to the membrane is discussed and a model is proposed for the process of solubilization.

Project description:The prion protein (PrP) is responsible for several fatal neurodegenerative diseases via conversion from its normal to disease-related isoform. The recombinant form of the protein is typically studied to investigate the conversion process. This constructs lacks the co- and post-translational modifications present in vivo, there the protein has two N-linked glycans and is bound to the outer leaflet of the plasma membrane via a glycosylphosphatidylinositol (GPI) anchor. The inherent flexibility and heterogeneity of the glycans, the plasticity of the GPI anchor, and the localization of the protein in a membrane make experimental structural characterization of biological constructs of cellular prion protein (PrP(C)) challenging. Yet this characterization is central in determining not only the suitability of recombinant (rec)-PrP(C) as a model for biological forms of the protein but also the potential role of co- and post-translational modifications on the disease process. Here, we present molecular dynamics simulations of three human prion protein constructs: (i) a protein-only construct modeling the recombinant form, (ii) a diglycosylated and soluble construct, and (iii) a diglycosylated and GPI-anchored construct bound to a lipid bilayer. We found that glycosylation and membrane anchoring do not significantly alter the structure or dynamics of PrP(C), but they do appreciably modify the accessibility of the polypeptide surface PrP(C). In addition, the simulations of membrane-bound PrP(C) revealed likely recognition domains for the disease-initiating PrP(C):PrP(Sc) (infectious and/or misfolded form of the prion protein) binding event and a potential mechanism for the observed inefficiency of conversion associated with differentially glycosylated PrP species.

Project description:Prions are self-propagating protein aggregates that act as protein-based genetic elements in fungi. Although prevalent in eukaryotes, prions have not been identified in bacteria. Here we demonstrate that a bacterial protein, transcription terminator Rho of Clostridium botulinum (Cb-Rho), can form a prion. Specifically, we identify a candidate prion-forming domain (cPrD) in Cb-Rho and show that it confers amyloidogenicity on Cb-Rho and can functionally replace the PrD of a yeast prion-forming protein. Furthermore, we show that its cPrD enables Cb-Rho to access alternative conformations in bacteria, a soluble form that terminates transcription efficiently and an aggregated, self-propagating prion form that is functionally compromised, causing genome-wide changes in the transcriptome. Thus, Cb-Rho functions as a protein-based genetic element in bacteria, suggesting that the emergence of prions predates the evolutionary split between eukaryotes and bacteria.

Project description:The lipoprotein Lpp is the most numerically abundant protein in Escherichia coli, has been investigated for over 40 years, and has served as the paradigmatic bacterial lipoprotein since its initial discovery. It exists in two distinct forms: a 'bound-form', which is covalently bound to the cell's peptidoglycan layer, and a 'free-form', which is not. Although it is known that the carboxyl-terminus of bound-form Lpp is located in the periplasm, the precise location of free-form Lpp has never been determined. For decades, it has been widely assumed that free-form Lpp is associated with bound-form. In this work, we show that the free and bound forms of Lpp are not largely associated with each other, but are found in distinct subcellular locations. Our results indicate that free-form Lpp spans the outer membrane and is surface-exposed, whereas bound-form Lpp resides in the periplasm. Thus, Lpp represents a novel example of a single lipoprotein that is able to occupy distinct subcellular locations, and challenges models in which the free and bound forms of Lpp are assumed to be associated with each other.

Project description:A metal-free C-H [5 + 1] annulation reaction of 2-arylanilines with diazo compounds has been achieved, giving rise to two types of prevalent phenanthridines via highly selective C-C cleavage. Compared to the simple N-H insertion manipulation of diazo, this method elegantly accomplishes a tandem N-H insertion/SEAr/C-C cleavage/aromatization reaction, and the synthetic utility of this new transformation is exemplified by the succinct syntheses of trisphaeridine and bicolorine alkaloids.

Project description:Dihydroorotate dehydrogenase (DHODH) is a flavin-binding enzyme essential for pyrimidine biosynthesis, which converts dihydroorotate to orotate. Three-dimensional structures of cytosolic DHODH of parasitic protozoa are of interest in drug discovery for neglected tropical diseases, especially because these enzymes possess significantly different structural and functional properties from the membrane-associated human enzyme. The existing crystal structures of the flavin mononucleotide (FMN)-bound DHODHs reveal a number of interactions stabilizing FMN. However, to understand the binding mechanism correctly, it is necessary to compare the structures of the FMN-bound and FMN-free forms, because the protein moiety of the former is not necessarily the same as the latter. Here, we prepared the FMN-free DHODH of Trypanosoma brucei using an Escherichia coli overexpression system. Although this apoform lacks enzymatic activity, simple incubation with FMN activated the enzyme. It was stable enough to be crystallized, enabling us to determine its structure by X-ray crystallography at 1.6 Å resolution. We also determined the FMN-bound form at 1.8 Å resolution. Although the two structures have essentially the same scaffold, we observed flipping of a peptide-bond plane in the vicinity of the FMN-binding site, accompanied by an alternative hydrogen-bonding pattern. Comparisons of B factors of the protein main chain revealed that binding of FMN decreased flexibility of most of the residues at the FMN-binding site, but increased flexibility of a lid-like loop structure over the active center. This increase was ascribed to a conformational change in an FMN-contacting residue, Asn195, which induced a rearrangement of a hydrogen-bond network of the residues comprising the lid.