Estudos de vias sintéticas catalíticas para benzociclo-alcanois e análogos: potenciais fármacos para doença de Alzhjeimer

A doença de Alzheimer constitui uma ameaça significativa a nível mundial. Estima-se que, mundialmente existam cerca de 35 milhões de pessoas afetadas por este tipo de demência. Os compostos contendo um esqueleto benzocicloalcanol (que incluem benzofuranos e di-hidrobenzofuranóis) mostram atividades biológicas significativas e possuem muito potencial no tratamento das doenças neurodegenerativas. Nos últimos anos têm havido avanços significativos no campo das reações catalisadas por metais. As reações de adição nucleófila intramolecular e a de Heck intramolecular constituem metodologias importantes para a síntese de benzocicloalcanóis. No âmbito deste trabalho, pretendia-se sintetizar uma biblioteca de compostos contendo um esqueleto benzocicloalcanol. A estratégia adotada para a síntese de dihidrobenzofuranóis envolveu um método de ciclização catalítica de cetonas aril-éteres e para a síntese de benzofuranos, um método de ciclização catalítico de enoatos e enamidas (amidas de Weinreb). Várias condições foram estudadas; Abstract: Studies on Synthetic Catalytic Pathways to Benzocycloalkanols and Derivatives – Potential Drugs for Alzheimer’s Disease Alzheimer's disease constitutes a significant threat worldwide. It is estimated that are about 35 million people worldwide suffering from this type of dementia. The compounds containing a benzocycloalkanol scaffold (including benzofurans and dihydrobenzofurans) show significant biological activity and have great potential in the treatment of neurodegenerative diseases. In recent years there have been many advances in the field of catalyzed reactions by transition-metals. The intramolecular nucleophilic addition and the intramolecular Heck reactions constitute important methods for the synthesis of benzocycloalkanols. Within this work, the main goal was to synthesize a library of compounds containing a benzocycloalkanol scaffold. The adopted strategy for the synthesis of dihydrobenzofurans was the catalytic cyclization of aryl ether ketones and for the synthesis of benzofurans, the catalytic cyclization of enoates and enamides (Weinreb amides). Several conditions were studied

Complete structure of an epithelial keratin dimer: implications for intermediate filament assembly

Keratins are cytoskeletal proteins that hierarchically arrange into filaments, starting with the dimer sub-unit. They are integral to the structural support of cells, in skin, hair and nails. In skin, keratin is thought to play a critical role in conferring the barrier properties and elasticity of skin. In general, the keratin dimer is broadly described by a tri-domain structure: a head, a central rod and a tail. As yet, no atomistic-scale picture of the entire dimer structure exists; this information is pivotal for establishing molecular-level connections between structure and function in intermediate filament proteins. The roles of the head and tail domains in facilitating keratin filament assembly and function remain as open questions. To address these, we report results of molecular dynamics simulations of the entire epithelial human K1/K10 keratin dimer. Our findings comprise: (1) the first three-dimensional structural models of the complete dimer unit, comprising of the head, rod and tail domains; (2) new insights into the chirality of the rod-domain twist gained from analysis of the full domain structure; (3) evidence for tri-subdomain partitioning in the head and tail domains; and, (4) identification of the residue characteristics that mediate non-covalent contact between the chains in the dimer. Our findings are immediately applicable to other epithelial keratins, such as K8/K18 and K5/K14, and to intermediate filament proteins in general.

Self-assembled core-satellite gold nanoparticle networks for ultrasensitive detection of chiral molecules by recognition tunneling current

Chirality sensing is a very challenging task. Here, we report a method for ultrasensitive detection of chiral molecule l/d-carnitine based on changes in the recognition tunneling current across self-assembled core-satellite gold nanoparticle (GNP) networks. The recognition tunneling technique has been demonstrated to work at the single molecule level where the binding between the reader molecules and the analytes in a nanojunction. This process was observed to generate a unique and sensitive change in tunneling current, which can be used to identify the analytes of interest. The molecular recognition mechanism between amino acid l-cysteine and l/d-carnitine has been studied with the aid of SERS. The different binding strength between homo- or heterochiral pairs can be effectively probed by the copper ion replacement fracture. The device resistance was measured before and after the sequential exposures to l/d-carnitine and copper ions. The normalized resistance change was found to be extremely sensitive to the chirality of carnitine molecule. The results suggested that a GNP networks device optimized for recognition tunneling was successfully built and that such a device can be used for ultrasensitive detection of chiral molecules.

Chiroptical spectroscopy of biomolecules using chiral plasmonic nanostructures

This thesis explores the potential of chiral plasmonic nanostructures for the ultrasensitive detection of protein structure. These nanostructures support the generation of fields with enhanced chirality relative to circularly polarised light and are an extremely incisive probe of protein structure. In chapter 4 we introduce a nanopatterned Au film (Templated Plasmonic Substrate, TPS) fabricated using a high through-put injection moulding technique which is a viable alternative to expensive lithographically fabricated nanostructures. The optical and chiroptical properties of TPS nanostructures are found to be highly dependent on the coupling between the electric and magnetic modes of the constituent solid and inverse structures. Significantly, refractive index based measurements of strongly coupled TPSs display a similar sensitivity to protein structure as previous lithographic nanostructures. We subsequently endeavour to improve the sensing properties of TPS nanostructures by developing a high through-put nanoscale chemical functionalisation technique. This process involves a chemical protection/deprotection strategy. The protection step generates a self-assembled monolayer (SAM) of a thermally responsive polymer on the TPS surface which inhibits protein binding. The deprotection step exploits the presence of nanolocalised thermal gradients in the water surrounding the TPS upon irradiation with an 8ns pulsed laser to modify the SAM conformation on surfaces with high net chirality. This allows binding of biomaterial in these regions and subsequently enhances the TPS sensitivity levels. In chapter 6 an alternative method for the detection of protein structure using TPS nanostructures is introduced. This technique relies on mediation of the electric/magnetic coupling in the TPS by the adsorbed protein. This phenomenon is probed through both linear reflectance and nonlinear second harmonic generation (SHG) measurements. Detection of protein structure using this method does not require the presence of fields of enhanced chirality whilst it is also sensitive to a larger array of secondary structure motifs than the measurements in chapters 4 and 5. Finally, a preliminary investigation into the detection of mesoscale biological structure is presented. Sensitivity to the mesoscale helical pitch of insulin amyloid fibrils is displayed through the asymmetry in the circular dichroism (CD) of lithographic gammadions of varying thickness upon adsorption of insulin amyloid fibril spherulites and fragmented fibrils. The proposed model for this sensitivity to the helical pitch relies on the vertical height of the nanostructures relative to this structural property as well as the binding orientation of the fibrils.