37 research outputs found
Supramolecular assembly of pyrene-DNA conjugates: influence of pyrene substitution pattern and implications for artificial LHCs.
The supramolecular self-assembly of pyrene-DNA conjugates into nanostructures is presented. DNA functionalized with different types of pyrene isomers at the 3'-end self-assemble into nano-objects. The shape of the nanostructures is influenced by the type of pyrene isomer appended to the DNA. Multilamellar vesicles are observed with the 1,6- and 1,8-isomers, whereas conjugates of the 2,7-isomer exclusively assemble into spherical nanoparticles. Self-assembled nano-spheres obtained with the 2,7-dialkynyl pyrene isomer were used for the construction of an artificial light-harvesting complex (LHC) in combination with Cy3 as the energy acceptor
Tetraphenylethylene–DNA conjugates: influence of sticky ends and DNA sequence length on the supramolecular assembly of AIE-active vesicles
The supramolecular assembly of DNA conjugates, functionalized with tetraphenylethylene (TPE) sticky ends, into vesicular structures is described. The aggregation-induced emission (AIE) active TPE units allow to monitor the assembly process by fluorescence spectroscopy. The number of TPE modifications in the overhangs of the conjugates influences the supramolecular assembly behavior. A minimum of two TPE residues on each end are required to ensure a well-defined assembly process. The design of the presented DNA-based nanostructures offers tailored functionalization with applications in DNA nanotechnology
Supramolecular Assembly of Pyrene-DNA Conjugates into Columnar Vesicles
This poster describes the supramolecular assembly of DNA conjugates functionalized with pyrene sticky-ends. After hybridization, the 3’-end modified DNA single strands self-assembled into vesicles with diameters of 50–200 nm. Columnar packed aggregated and multilamellar vesicles were observed by cryo-EM
A small ribosome-associated ncRNA globally inhibits translation by restricting ribosome dynamics
Ribosome-associated non-coding RNAs (rancRNAs) have been recognized as an emerging class of regulatory molecules capable of fine-tuning translation in all domains of life. RancRNAs are ideally suited for allowing a swift response to changing environments and are therefore considered pivotal during the first wave of stress adaptation. Previously, we identified an mRNA-derived 18 nucleotides long rancRNA (rancRNA_18) in Saccharomyces cerevisiae that rapidly downregulates protein synthesis during hyperosmotic stress. However, the molecular mechanism of action remained enigmatic. Here, we combine biochemical, genetic, transcriptome-wide and structural evidence, thus revealing rancRNA_18 as global translation inhibitor by targeting the E-site region of the large ribosomal subunit. Ribosomes carrying rancRNA_18 possess decreased affinity for A-site tRNA and impaired structural dynamics. Cumulatively, these discoveries reveal the mode of action of a rancRNA involved in modulating protein biosynthesis at a thus far unequalled precision
Revealing Assembly of a Pore-Forming Complex Using Single-Cell Kinetic Analysis and Modeling
AbstractMany biological processes depend on the sequential assembly of protein complexes. However, studying the kinetics of such processes by direct methods is often not feasible. As an important class of such protein complexes, pore-forming toxins start their journey as soluble monomeric proteins, and oligomerize into transmembrane complexes to eventually form pores in the target cell membrane. Here, we monitored pore formation kinetics for the well-characterized bacterial pore-forming toxin aerolysin in single cells in real time to determine the lag times leading to the formation of the first functional pores per cell. Probabilistic modeling of these lag times revealed that one slow and seven equally fast rate-limiting reactions best explain the overall pore formation kinetics. The model predicted that monomer activation is the rate-limiting step for the entire pore formation process. We hypothesized that this could be through release of a propeptide and indeed found that peptide removal abolished these steps. This study illustrates how stochasticity in the kinetics of a complex process can be exploited to identify rate-limiting mechanisms underlying multistep biomolecular assembly pathways
The Structure and Symmetry of the Radial Spoke Protein Complex in \u3cem\u3eChlamydomonas\u3c/em\u3e Flagella
The radial spoke is a key element in a transducer apparatus controlling the motility of eukaryotic cilia. The transduction biomechanics is a long-standing question in cilia biology. The radial spoke has three regions – a spoke head, a bifurcated neck and a stalk. Although the neck and the stalk are asymmetric, twofold symmetry of the head has remained controversial. In this work we used single particle cryo-electron microscopy (cryo-EM) analysis to generate a 3D structure of the whole radial spoke at unprecedented resolution. We show the head region at 15 Å (1.5 nm) resolution and confirm twofold symmetry. Using distance constraints generated by cross-linking mass spectrometry, we locate two components, RSP2 and RSP4, at the head and neck regions. Our biophysical analysis of isolated RSP4, RSP9, and RSP10 affirmed their oligomeric state. Our results enable us to redefine the boundaries of the regions and propose a model of organization of the radial spoke component proteins
Dissecting Out the Molecular Mechanism of Insecticidal Activity of Ostreolysin A6/Pleurotolysin B Complexes on Western Corn Rootworm
Ostreolysin A6 (OlyA6) is a protein produced by the oyster mushroom (Pleurotus ostreatus). It binds to membrane sphingomyelin/cholesterol domains, and together with its protein partner, pleurotolysin B (PlyB), it forms 13-meric transmembrane pore complexes. Further, OlyA6 binds 1000 times more strongly to the insect-specific membrane sphingolipid, ceramide phosphoethanolamine (CPE). In concert with PlyB, OlyA6 has potent and selective insecticidal activity against the western corn rootworm. We analysed the histological alterations of the midgut wall columnar epithelium of western corn rootworm larvae fed with OlyA6/PlyB, which showed vacuolisation of the cell cytoplasm, swelling of the apical cell surface into the gut lumen, and delamination of the basal lamina underlying the epithelium. Additionally, cryo-electron microscopy was used to explore the membrane interactions of the OlyA6/PlyB complex using lipid vesicles composed of artificial lipids containing CPE, and western corn rootworm brush border membrane vesicles. Multimeric transmembrane pores were formed in both vesicle preparations, similar to those described for sphingomyelin/cholesterol membranes. These results strongly suggest that the molecular mechanism of insecticidal action of OlyA6/PlyB arises from specific interactions of OlyA6 with CPE, and the consequent formation of transmembrane pores in the insect midgut
Monalysin, a Novel Ăź-Pore-Forming Toxin from the Drosophila Pathogen Pseudomonas entomophila, Contributes to Host Intestinal Damage and Lethality
Pseudomonas entomophila is an entomopathogenic bacterium that infects and kills Drosophila. P. entomophila pathogenicity is linked to its ability to cause irreversible damages to the Drosophila gut, preventing epithelium renewal and repair. Here we report the identification of a novel pore-forming toxin (PFT), Monalysin, which contributes to the virulence of P. entomophila against Drosophila. Our data show that Monalysin requires N-terminal cleavage to become fully active, forms oligomers in vitro, and induces pore-formation in artificial lipid membranes. The prediction of the secondary structure of the membrane-spanning domain indicates that Monalysin is a PFT of the Ăź-type. The expression of Monalysin is regulated by both the GacS/GacA two-component system and the Pvf regulator, two signaling systems that control P. entomophila pathogenicity. In addition, AprA, a metallo-protease secreted by P. entomophila, can induce the rapid cleavage of pro-Monalysin into its active form. Reduced cell death is observed upon infection with a mutant deficient in Monalysin production showing that Monalysin plays a role in P. entomophila ability to induce intestinal cell damages, which is consistent with its activity as a PFT. Our study together with the well-established action of Bacillus thuringiensis Cry toxins suggests that production of PFTs is a common strategy of entomopathogens to disrupt insect gut homeostasis
Folding and Structure of the Pore Forming Toxin Aerolysin
The first obstacle encountered by a bacterial pathogen once inside the host is the plasma membrane surrounding the target cells. Throughout evolution bacteria has acquired and maintained genes that upon stimulation express proteins capable of damaging the membrane of other cells. Among these proteins pore forming toxins (PFTs) are a major class of bacterial effectors that are upregulated and secreted during bacterial infections. As their name suggests, pore forming toxins are proteins capable of inserting transmembrane pores in the membranes of the target cells which in turn leads to the lysis of the cell and release of nutrients. The mechanism by which the PFTs function during a bacterial attack has been the subject of extensive research over the years. In most cases PFTs are produced by the bacteria as soluble proteins that require the help of specialized secretion mechanisms to arrive as functional proteins in the external milieu. Once secreted by the producing bacteria these proteins diffuse towards the target cell and bind to the target membrane. Once bound to the plasma membrane of target cells they are capable of initiating a series of structural changes that will eventually lead to the conversion of the water-soluble PFT to a membrane inserted channel. The series of events and the characterization of the different structural changes required for a PFT to convert from a water-soluble protein to a membrane inserted channel is the subject of this thesis. Aerolysin, a PFT produced by Aeromonas hydrophilla, is one of the best candidates for a research into the details of the mode of action of bacterial PFTs. This particular PFT is produced by the bacterium as a soluble periplasmic protein and then secreted outside of the bacterium as a fully folded protein with the help of a type II secretion system. Binding to the target cell is achieved through two high affinity binding sites that recognize sugar modifications which are absent in A. hydrophila, a mechanism that insures that the producing cell is not damaged by its own PFT. Once bound to the target cell aerolysin requires proteolytic activation, a step which cleaves a C-terminal peptide (CTP). Activation is achieved using proteases present on the target cell and the removal of the CTP is thought to initiate the sequence of events leading to pore formation. Following activation aerolysin is able to oligomerize forming heptameric ring-like structures which spontaneously rearrange forming a transmembrane beta-barrel through the membrane. My thesis project, focused on the structural changes required in the mode of action of aerolysin, set off trying to identify the aminoacid sequence involved in the formation of the transmembrane beta-barrel. It was long thought that aerolysin would cross the membrane in a porin like fashin, forming a beta-barrel through the plasma membrane, primarily due to the lack of a hydrophobic patch of aminoacids in its sequence. An initial model proposed in the early '90s postulated that the only region that could form the transmembrane beta-barrel was the Domain 4 of the protein. In this model the removal of the CTP in the activation process would unravel the hydrophobic residues required for the beta-barrel formation and insertion. We and others were able to show however that the fourth domain of the protein is not involved directly in the formation of the pore and we identified a conserved loop in the third domain of the protein which is responsible for the formation of the beta-barrel. This loop presents an alternating pattern of hydrophobic and hydrophilic residues, a requirement for the formation of a transmembrane pore with a hydrophobic exterior and a hydrophilic cavity. Our research led us to propose a sequence of events upon insertion of the aerolysin pore in which a rearrangement of the DIII-loops of the seven monomers in the oligomer forms the initial beta-barrel and generates a hydrophobic tip which drives insertion of the structure through the membrane. Once the bilayer has been crossed the hydrophobic tips folds back on the membrane in a rivet like fashion, anchoring the pore. Following the identification of the DIII-loop as the region that forms the transmembrane pore my researched focused on the structural changes leading to the conversion of a water-soluble protein to a membrane inserted oligomer. While removal of the CTP is the key requirement for this conversion, the role of the CTP in aerolysin mode of action and the sequence of events triggered by its removal is not fully understood. Using a combination of in vivo, in vitro and in silico approaches we were able to show that the CTP plays a wider role in the aerolysin mode of action than previously thought. Indeed our research shows that the CTP is initially required for the correct folding of the soluble protein inside the bacterium, acting as a intramolecular chaperone during the folding of aerolysin. Following folding the CTP binds tightly to a hydrophobic pocket in the fourth domain of the protein locking the PFT in its soluble conformation, a role resembling C-terminal intramolecular chaperones previously described for tail spikes of bacteriophages or fiber forming collagen. This research will be continued with a study on the structural changes triggered by the removal of the CTP and their role in oligomerization and pore formation. The main focus of my thesis project has been however the determination of the structure of the oligomeric form of aerolysin. This part of the project is still ongoing and will be discussed in the final chapter of my thesis. Using 2D and 3D crystallography, AFM and modeling we hope to be able to improve our current understanding of the aerolysin heptameric form and the structural changes required in its formation
Supramolecular assembly of DNA-constructed vesicles
The self-assembly of DNA hybrids possessing tetraphenylethylene sticky ends at both sides into vesicular architectures in aqueous medium is demonstrated. Cryo-electron microscopy reveals the formation of different types of morphologies from the amphiphilic DNA-hybrids. Depending on the conditions, either an extended (sheet-like) or a compact (columnar) alignment of the DNA hybrids is observed. The different modes of DNA arrangement lead to the formation of vesicles appearing either as prolate ellipsoids (type I) or as spheres (type II). The type of packing has a significant effect on the accessibility of the DNA, as evidenced by intercalation and light-harvesting experiments. Only the vesicles exhibiting the sheet-like DNA alignment are accessible for intercalation by ethidium bromide or for the integration of chromophore-labelled DNA via a strand exchange process. The dynamic nature of type I vesicles enables their elaboration into artificial light-harvesting complexes by DNA-guided introduction of Cy3-acceptor chromophores. DNA-constructed vesicles of the kind shown here represent versatile intermediates that are amenable to further modification for tailored nanotechnology applications