Solution structure of a bacterial microcompartment targeting peptide and its application in the construction of an ethanol bioreactor

Targeting of proteins to bacterial microcompartments (BMCs) is mediated by an 18-amino-acid peptide sequence. Herein, we report the solution structure of the N-terminal targeting peptide (P18) of PduP, the aldehyde dehydrogenase associated with the 1,2-propanediol utilization metabolosome from Citrobacter freundii. The solution structure reveals the peptide to have a well-defined helical conformation along its whole length. Saturation transfer difference and transferred NOE NMR has highlighted the observed interaction surface on the peptide with its main interacting shell protein, PduK. By tagging both a pyruvate decarboxylase and an alcohol dehydrogenase with targeting peptides, it has been possible to direct these enzymes to empty BMCs in vivo and to generate an ethanol bioreactor. Not only are the purified, redesigned BMCs able to transform pyruvate into ethanol efficiently, but the strains containing the modified BMCs produce elevated levels of alcohol

Self-assembly, nematic phase formation and organocatalytic behaviour of a proline-functionalized lipopeptide

The self-assembly of the amphiphilic lipopeptide PAEPKI-C16 (P = proline, A = alanine, E = glutamic acid, K = lysine, I = isoleucine, C16 = hexadecyl) was investigated using a combination of spectroscopic, microscopic and scattering methods and compared to C16-IKPEAP with the same (reversed) peptide sequence and the alkyl chain positioned N-terminally and which lacks a free N-terminal proline residue. The catalytic activity of these peptides were then compared using a model aldol reaction system. For PAEPKI-C16, Cryo-TEM images showed the formation of micrometer length fibers, which by Small-angle X-ray scattering (SAXS) were found to have a radius of 2.5 - 2.6 nm. Spectroscopic analysis shows these fibers are built from -sheets. This behaviour is in complete contrast to that of C16-IKPEAP which forms spherical micelles with peptides in a disordered conformation [Hutchinson, J. A. et al. J. Phys. Chem. B 2019, 123, 613]. For PAEPKI-C16, the spontaneous alignment of fibers was observed upon increasing pH, which was accompanied by observed birefringence and anisotropy of SAXS patterns. This shows the formation of a nematic liquids and unprecedented nematic hydrogel formation was also observed these lipopeptides at sufficiently high concentrations. SAXS shows retention of an ultrafine (1.7 nm core radius) fibrillar network within the hydrogel. PAEPKI-C16 with free N-terminal proline shows enhanced anti:syn diastereoselectivity and better conversion compared to C16-IKPEAP. The cytotoxicity of PAEPKI-C16 was also lower than C16-IKPEAP for both fibroblast and cancer cell lines. These results highlight the sensitivity of lipopeptide properties to the presence of a free proline residue. The spontaneous nematic phase formation by PAEPKI-C16 points to the highly anisotropy of its ultrafine fibrillar structure and the formation of such a phase at low concentration in aqueous solution may be valuable for future applications

Smart systems related to polypeptide sequences

Increasing interest for the application of polypeptide-based smart systems in the biomedical field has developed due to the advantages given by the peptidic sequence. This is due to characteristics of these systems, which include: biocompatibility, potential control of degradation, capability to provide a rich repertoire of biologically specific interactions, feasibility to self-assemble, possibility to combine different functionalities, and capability to give an environmentally responsive behavior. Recently, applications concerning the development of these systems are receiving greater attention since a targeted and programmable release of drugs (e.g. anti-cancer agents) can be achieved. Block copolymers are discussed due to their capability to render differently assembled architectures. Hybrid systems based on silica nanoparticles are also discussed. In both cases, the selected systems must be able to undergo fast changes in properties like solubility, shape, and dissociation or swelling capabilities. This review is structured in different chapters which explain the most recent advances on smart systems depending on the stimuli to which they are sensitive. Amphiphilic block copolymers based on polyanionic or polycationic peptides are, for example, typically employed for obtaining pH-responsive systems. Elastin-like polypeptides are usually used as thermoresponsive polymers, but performance can be increased by using techniques which utilize layer-by-layer electrostatic self-assembly. This approach offers a great potential to create multilayered systems, including nanocapsules, with different functionality. Recent strategies developed to get redox-, magnetic-, ultrasound-, enzyme-, light-and electric-responsive systems are extensively discussed. Finally, some indications concerning the possibilities of multi-responsive systems are discussed.Postprint (published version

Global Energy Matching Method for Atomistic-to-Continuum Modeling of Self-Assembling Biopolymer Aggregates

This paper studies mathematical models of biopolymer supramolecular aggregates that are formed by the self-assembly of single monomers. We develop a new multiscale numerical approach to model the structural properties of such aggregates. This theoretical approach establishes micro-macro relations between the geometrical and mechanical properties of the monomers and supramolecular aggregates. Most atomistic-to-continuum methods are constrained by a crystalline order or a periodic setting and therefore cannot be directly applied to modeling of soft matter. By contrast, the energy matching method developed in this paper does not require crystalline order and, therefore, can be applied to general microstructures with strongly variable spatial correlations. In this paper we use this method to compute the shape and the bending stiffness of their supramolecular aggregates from known chiral and amphiphilic properties of the short chain peptide monomers. Numerical implementation of our approach demonstrates consistency with results obtained by molecular dynamics simulations

Biomimetic soft matter

Biomaterials are often soft materials. There is now growing interest in designing, synthesizing and characterising soft materials that mimic the properties of biological materials such as tissue, proteins, DNA or cells. Research on biomimetic soft matter is therefore a developing theme with important emerging applications in biomedicine including tissue engineering, diagnostics, gene therapy, drug delivery and many others. There are also important basic science questions concerning the use of concepts from colloid and polymer science to understand the self-assembly of biomimetic soft materials. This issue of Soft Matter presents a selection of extremely topical articles on a diversity of biomimetic soft matter systems. I thank the contributors for this quite remarkable collection of papers, which report many fascinating discoveries and insights

Structural and biophysical analysis of important biomedical enzymes and nano-architectures

Dopa decarboxylase (DDC) is an important enzyme in the catecholamine biosynthesis pathways. Catecholamines, e.g., dopamine, serotonin, etc. often are the major neuromodulators or neurotransmitters. Hence, DDC plays a key role in regulation of neurodegenerative diseases like Parkinson’s disease (PD). In order to achieve a medicine for PD, a successful inhibitor for DDC, that could reduce the activity of DDC in the blood while making it more effective in brain, is required. An effective design of an inhibitor requires a detailed structural study of human DDC. It was aimed to solve the DDC structure by X-ray crystallography. In order to have enough protein the DDC encoding gene has been cloned in the pET21d vector which was later termed as pET-DDC-His. However, it required numerous trials and errors until a suitable condition for soluble DDC expression was found. Addition of additives like PLP, ethanol, a complex of sorbitol and betaine in the growth medium of the bacteria did not help bring the protein in the soluble part as it formed inclusion bodies. Several soluble protein fusions with DDC, like Thioredoxin and Glutathione-S-transferase were also not quite helpful towards achieving soluble expression of DDC. Finally, a coexpression of DDC along with bacterial chaperone proteins, e.g., GroEL and GroES (after cotransforming both the DDC and Chaperone protein encoding plasmid in the same E.coli cell, used for expression) lead to solubilization of recombinant human DDC. This enzyme was then purified to homogeneity by successively passing the crude bacterial proteins through Ni-chelate-affinity chromatography and Size Exclusion Chromatography. The purified protein (>90 % purity) did not produce a good yield (4mg/ 8L culture), but this was enough to start the initial crystallization trial. Using a scale up to a 50 L culture, quite a good amount of protein was achieved. The homogeneity of DDC was further confirmed by using Multi-Angle Light Scattering and Blue Native PAGE. The dimeric enzyme preparation was then utilized for crystallization using the Hanging Drop Vapor Diffusion method. In a particular condition of the crystal screens trigonal bipyramidal crystals formed. However, these crystals did not show good diffraction when bombarded with X-ray beams. Later, this particular crystallization condition remained irreproducible. The peptide nanoparticle, designed and produced in our lab, could possibly be a very valuable tool in biomedical applications, e.g., in designing vaccines, delivering drugs, bioimaging, serodiagnosis, etc. The design of the peptide nanoparticles is based on the application of the symmetry elements of virus icosahedral capsid on a specially designed building block peptide. The designed peptide building block contains two oligomerization motifs, i.e., a trimeric coiled coil and a pentameric coiled coil joined by a linker region. Sixty such peptide units, upon self-assembly, would produce peptide nanoparticle mimicking a small icosahedral virus particle. The peptide chains in the building block provide flexibility in the design so that an additional peptide could be attached to it at the C-terminus in order to functionalize the peptide nanoparticle for various biomedical applications. First of all, the functional peptide at the C-terminus could be an epitope for the antibody of a life threatening disease like HIV. These peptide nanoparticles can then function as the potent vaccine candidate for that particular disease. In this thesis work, I have attached the two epitopes against the two broadly neutralizing classes of antibody for HIV infection, 2F5 and 4E10, to the peptide nanoparticle. Secondly, another sequence of peptide, which proved to have the capacity of seeding gold on its surface, was attached to the building block peptide unit. The nanoparticle, functionalized with such a peptide, can decorate a gold layer surrounding it. Gold coating on the peptide nanoparticle scaffold can provide a nanostructure, called ‘nanoshells’, which could be very important in the field of therapeutics because of its ability in easy detection and quick treatment of cancer cells. Lastly, I added three peptides; those are recognized in the culture filtrates of M.tuberculosis isolated from TB patients, separately, to the basic peptide construct to form three different nanoparticles. Also, I tried to make a single nanoparticle that displays all the three peptides on its surface. Such a nanoparticle could be a very useful tool in the serodiagnosis or the antibody-based rapid detection of the deadly disease- Tuberculosis. The nanoparticle formation in each of the above-mentioned cases was more or less successful. One of the constructs could successfully even produce gold shells on the peptide nanoparticle