Synthesis of proteophenes that can be utilized as fluorescent ligands for biological targets

Björk, Linnea

January 2019

Small fluorescent probes are important tools when studying protein aggregates involved in different neurodegenerative diseases, such as Alzheimer’s disease. Luminescent conjugated oligothiophenes have been developed and shown to be excellent ligands when studying morphology among amyloids, due to their conjugated thiophene backbone that provides them with unique photophysical properties. This kind of probes are being developed successively to enhance the specificity of their biological targets. In this project, luminescent conjugated oligothiophenes functionalized with amino acids, so called proteophenes, have been synthesized to investigate their optical properties. Since amino acids are chiral molecules, the possibility of induced chirality to the thiophene backbone was examined, as well as the proteophenes ability to work as amyloidospecific ligands for the study of protein aggregates. The synthesis of four different proteophenes are presented in this report, along with analysis results of their photophysical properties.

Fluorescent probes

Neuredegenerative diseases

Luminescent Conjugated Oligothiophenes

Protein misfolding

Aggregates

Amyloids

Alzheimer’s disease

Aβ-plaque

Organic Chemistry

Organisk kemi

Synthesis and Photoinduced Electron Transfer of Donor-Sensitizer-Acceptor Systems

Xu, Yunhua

January 2005

<p>Artificial systems involving water oxidation and solar cells are promising ways for the conversion of solar energy into fuels and electricity. These systems usually consist of a photosensitizer, an electron donor and / or an electron acceptor. This thesis deals with the synthesis and photoinduced electron transfer of several donor-sensitizer-acceptor supramolecular systems.</p><p>The first part of this thesis describes the synthesis and properties of two novel dinuclear ruthenium complexes as electron donors to mimic the donor side reaction of Photosystem II. These two Ru₂ complexes were then covalently linked to ruthenium trisbipyridine and the properties of the resulting trinuclear complexes were studied by cyclic voltammetry and transient absorption spectroscopy.</p><p>The second part presents the synthesis and photoinduced electron transfer of covalently linked donor-sensitizer supramolecular systems in the presence of TiO₂ as electron acceptors. Electron donors are tyrosine, phenol and their derivatives, and dinuclear ruthenium complexes. Intramolecular electron transfer from the donor to the oxidized sensitizer was observed by transient absorption spectroscopy after light excitation of the Ru(bpy)₃²⁺ moiety. The potential applications of Ru₂-based electron donors in artificial systems for water oxidation and solar cells are discussed.</p><p>In the final part, the photoinduced interfacial electron transfer in the systems based on carotenoids and TiO₂ is studied. Carotenoids are shown to act as both sensitizers and electron donors, which could be used in artificial systems to mimic the electron transfer chain in natural photosynthesis.</p>

Artificial photosynthesis

Dye-sensitized solar cells

Electron donors

Dinuclear ruthenium complexes

Electron transfer

Organic chemistry

Organisk kemi

Efficient and High-Yielding Routes to Diaryliodonium Salts

Bielawski, Marcin

January 2008

<p>This thesis summarizes three novel and general reaction protocols for the synthesis of diaryliodonium salts. All protocols utilize mCPBA as oxidant and the acids used are either TfOH, to obtain triflate salts, or BF3•Et2O that gives the corresponding tetrafluoroborate salts in situ.</p><p>Chapter two describes the reaction of various arenes and aryl iodides, delivering electron-rich and electron-deficient triflates in moderate to excellent yields.</p><p>In chapter three, it is shown that the need of aryl iodides can be circumvented, as molecular iodine can be used together with arenes in a direct one-pot, three-step synthesis of symmetric diaryliodonium triflates.</p><p>The final and fourth chapter describes the development of a sequential one-pot reaction from aryl iodides and boronic acids, delivering symmetric and unsymmetric, electron-rich and electron-deficient iodonium tetrafluoroborates in moderate to excellent yields. This protocol was developed to overcome mechanistic limitations existing in the protocols described in chapter two and three.</p><p>The methodology described in this thesis is the most general, efficient and high-yielding existing up to date, making diaryliodonium salts easily available for various applications in synthesis.</p>

Hypervalent Iodine Compounds

One-Pot Synthesis

Regiospecific Synthesis

Aromatic Substitution

Aryl Iodides

Arenes

Boronic Acids

Organic chemistry

Organisk kemi

Glycoconjugates : Solid-phase synthesis and biological applications

Wallner, Fredrik

January 2005

<p>Glycoconjugates are biologically important molecules with diverse functions. They consist of carbohydrates of varying size and complexity, attached to a non-sugar moiety as a lipid or a protein. Glycoconjugate structures are often very complex and their intricate biosynthetic pathways makes overexpression difficult. This renders the isolation of pure, structurally defined compounds from natural sources cumbersome. Therefore, to better address questions in glycobiology, synthetic glycoconjugates are an appealing alternative. In addition, synthetic methods allow for the preparation of non-natural glycoconjugates that can enhance the understanding of the influence of structural features on the biological responses.</p><p>In this thesis, synthetic methods for the preparation of glycoconjugates, especially glycolipid analogues, have been developed. These methods make use of solid-phase chemistry and are amenable to library synthesis of series of similar compounds. Solid-phase synthesis is a technique where the starting material of the reaction is attached to small plastic beads through a linker. This allows large excess of reagents to speed up the reactions and the sometimes difficult purifications of intermediate products are reduced to simple washings of the beads.</p><p>One problem with solid-phase synthesis is the difficulties to monitor the reactions and characterize the intermediate products. Gel-phase 19 F-NMR spectroscopy, using fluorinated linkers and protecting groups, is an excellent tool to overcome this problem and to monitor solid-phase synthesis of e.g. glycoconjugates. Two novel fluorinated linkers for the attachment of carboxylic acids have been developed and are presented in the thesis. These linkers can be cleaved with both acids of varying strengths and nucleophiles like hydroxide ions, and they are stable to glycosylation conditions. In addition, a novel filter reactor for solid-phase synthesis was designed. The reactor fits into an ordinary NMR spectrometer to facilitate the reaction monitoring with gel-phase 19 F-NMR spectroscopy.</p><p>The biological applications of the synthesized glycolipids were demonstrated in two different settings. The CD1d restricted binding of glycolipids carrying the monosaccharide α-GalNAc as carbohydrate could be detected on viable cells of mouse origin. CD1d is one of several antigen presenting molecules (the CD1 proteins) that presents lipids and glycolipids to circulating T-cells that in turn can initiate an immune response. The CD1 molecules are relatively sparsely investigated, and the method to measure glycolipid binding on viable cells, as described in the thesis, has the possibility to greatly enhance the knowledge of the structural requirements for CD1-binding.</p><p>Serine-based neoglycolipids with terminal carboxylic acids were used to prepare glycoconjugate arrays with covalent bonds to secondary amines on microtiter plates. Carbohydrate arrays have great possibilities to simplify the study of interactions between carbohydrates and e.g. proteins and microbes. The usefulness of the glycolipid arrays constructed in the thesis was illustrated with two lectins, RCA120 from Ricinus communis and BS-1 from Bandeiraea simplicifolia. Both lectins bound to the array of neoglycolipids in agreement with their respective specificity for galactosides.</p><p>Glycobiology is a large area of great interest and the methods described in this thesis can be used to answer a variety of glycoconjugaterelated biological questions.</p>

Glycoconjugate

Glycolipid

Solid-phase synthesis

Glycosylation

Gel-phase 19F-NMR spectroscopy

Fluorinated linker

Carbohydrat array

CD1

Organic chemistry

Organisk kemi

Synthesis of ¹¹C-labelled Alkyl Iodides : Using Non-thermal Plasma and Palladium-mediated Carbonylation Methods

Eriksson, Jonas

January 2006

<p>Compounds labelled with ¹¹C (<i>β</i>⁺, t_1/2 = 20.4 min) are used in positron emission tomography (PET), which is a quantitative non-invasive molecular imaging technique. It utilizes computerized reconstruction methods to produce time-resolved images of the radioactivity distribution in living subjects. </p><p>The feasibility of preparing [¹¹C]methyl iodide from [¹¹C]methane and iodine via a single pass through a non-thermal plasma reactor was explored. [¹¹C]Methyl iodide with a specific radioactivity of 412 ± 32 GBq/µmol was obtained in 13 ± 3% decay-corrected radiochemical yield within 6 min via catalytic hydrogenation of [¹¹C]carbon dioxide (24 GBq) and subsequent iodination, induced by electron impact. </p><p>Labelled ethyl-, propyl- and butyl iodide was synthesized, within 15 min, via palladium-mediated carbonylation using [¹¹C]carbon monoxide. The carbonylation products, labelled carboxylic acids, esters and aldehydes, were reduced to their corresponding alcohols and converted to alkyl iodides. [1-¹¹C]Ethyl iodide was obtained via palladium-mediated carbonylation of methyl iodide with a decay-corrected radiochemical yield of 55 ± 5%. [1-¹¹C]Propyl iodide and [1-¹¹C]butyl iodide were synthesized via the hydroformylation of ethene and propene with decay-corrected radiochemical yields of 58 ± 4% and 34 ± 2%, respectively. [1-¹¹C]Ethyl iodide was obtained with a specific radioactivity of 84 GBq/mmol from 10 GBq of [¹¹C]carbon monoxide. [1-¹¹C]Propyl iodide was synthesized with a specific radioactivity of 270 GBq/mmol from 12 GBq and [1-¹¹C]butyl iodide with 146 GBq/mmol from 8 GBq. </p><p>Palladium-mediated hydroxycarbonylation of acetylene was used in the synthesis of [1-¹¹C]acrylic acid. The labelled carboxylic acid was converted to its acid chloride and subsequently treated with amine to yield <i>N-</i>[<i>carbonyl</i>-¹¹C]benzylacrylamide. In an alternative method, [<i>carbonyl</i>-¹¹C]acrylamides were synthesized in decay-corrected radiochemical yields up to 81% via palladium-mediated carbonylative cross-coupling of vinyl halides and amines. Starting from 10 ± 0.5 GBq of [¹¹C]carbon monoxide, <i>N-</i>[<i>carbonyl</i>-¹¹C]benzylacrylamide was obtained in 4 min with a specific radioactivity of 330 ± 4 GBq/µmol. </p>

Organic chemistry

isotopic labelling

carbon-11

alkyl iodides

acrylamides

specific radioactivity

carbonylation

carbon monoxide

non-thermal plasma

PET

Organisk kemi

Heavy-Core Staffanes : A Computational Study of Their Fundamental Properties of Interest for Molecular Electronics

Sandström, Niclas

January 2007

<p>The basic building blocks in molecular electronics often correspond to conjugated molecules. A compound class consisting of rigid rod-like staffane molecules with the heavier Group 14 elements Si, Ge, Sn and Pb at their bridgehead positions has now been investigated. Herein these oligomers are called heavy-core or Si-, Ge-, Sn- or Pb-core staffanes. These compounds benefit from interaction through their bicyclo[1.1.1]pentane monomer units. Quantum chemical calculations were performed to probe their geometries, stabilities and electronic properties associated with conjugation.</p><p>The stabilities of the bicyclo[<i>n.n.n</i>]alkane and [<i>n.n.n</i>]propellanes (1 ≤ <i>n</i> ≤ 3) with C, Si, Ge and Sn at the bridgehead positions were studied by calculation of homodesmotic ring strain energies. The bicyclic compounds with <i>n</i> = 1 and Si, Ge or Sn at bridgehead positions have lower strain than the all-carbon compound.</p><p>A gradually higher polarizability exaltation is found as the bridgehead element is changed from C to Si, Ge, Sn or Pb. The ratio between longitudinal and average polarizability also increases gradually as Group 14 is descended, consistent with enhanced conjugation in the heavier oligomers.</p><p>The localization of polarons in C-, Si- and Sn-core staffane radical cations was calculated along with internal reorganization energies. The polaron is less localized in Si- and Sn-core than in C-core staffane radical cation. The reorganization energies are also lower for the heavier staffanes, facilitating hole mobility when compared to the C-core staffanes.</p><p>The effect of the bicyclic structure on the low valence excitations in the UV-spectra of compounds with two connected disilyl segments was also investigated. MS-CASPT2 calculations of 1,4-disilyl- and 1,4-bis(trimethylsilyl)-1,4-disilabicyclo[2.2.1]heptanes and 1,4-disilyl- and 1,4-bis(trimethylsilyl)-1,4-disilabicyclo[2.1.1]hexanes revealed that although the bicyclic cage separates the two disilyl chromophores, there is a strong red-shift of the lowest valence excitations when compared to an isolated disilane.</p>

Organic chemistry

conjugation

polarizability

Group 14 elements

cage compounds

electronic excitations

quantum chemistry

molecular electronics

Organisk kemi

Towards Rational Design of Asymmetric Catalyst for Organometallic and Organocatalytic Reactions

Hartikka, Antti

January 2007

<p>This thesis deals with synthetically modified chiral molecules and their application in asymmetric catalysis. The first part of the thesis describes the use of commercially available chiral diamine ligands in the iridium catalyzed transfer hydrogenation of aromatic ketones. The chiral diamine ligands were mixed with an appropriate transition-metal complex, which after addition of suitable base provided a chiral transition metal complex capable of reducing a range of different aromatic ketones in high yields and enantioselectivities. The developed methodology constitutes a cost effective and readily available procedure for transfer hydrogenation reactions. The following chapters in the thesis are completely devoted to rational design of small organic molecules acting as catalyst in various organocatalytic transformations. Organocatalytic methodology, represent a new and complementary approach to asymmetric organic synthesis, as compared to e.g. transition metal based methodology. Advantages of this methodology typically include mild and less stringent reaction conditions. This, in combination with the lack of toxic transition metal by-products, makes the process more environmentally benign; the organocatalytic methodology, therefore represent a promising approach towards implementation of green chemistry in organic synthesis. Despite this promise, typical drawbacks of the current methodology are long reaction times and the need for high catalyst loadings. Thus, a large demand exists for enhancing reactivity and increasing selectivity in organocatalytic reactions. The present thesis describes several efforts where we have tried to rationally design improved catalysts for various enantioselective organocata-lytic reactions. First, a structurally modified L-proline, incorporating a 1H-tetrazolic acid, was synthesized and evaluated in the direct asymmetric organocatalytic aldol reaction. As shown in Paper II, the catalyst displayed very high reactivity and subsequent studies were initiated in order to rationalize the reactivity enhancement (Paper III). Delightfully, the design principle of a 1H-tetrazolic acid as replacement for a carboxylic acid has since been widely used in the community, including our own efforts in organocatalytic asymmetric cyclopropanations (Paper V)and Diels-Alder reactions (Paper VII). Novel catalysts, including other functionalizations, were also designed for organocatalytic asymmetric addition of nitroalkanes to α,β-unsaturated aldehydes (Paper IV) and for cyclopropanations (Paper VI).</p>

Organocatalysis

Transition Metal Complex

Asymmetric

Aldol Reaction

Cyclopropanation

Diels-Alder

Reduction

Conjugate Addition

Organic chemistry

Organisk kemi

Exploring Molecular Interactions : Synthesis and Studies of Clip-Shaped Molecular Hosts

Polavarapu, Anjaneya Prasad

January 2007

<p>Molecular recognition via noncovalent interactions plays a key role in many biological processes such as antigen-antibody interactions, protein folding, the bonding and catalytic transformation of substrates by enzymes, etc. Amongst these noncovalent interactions, electrostatic interactions, hydrogen bonding, π-π interactions, and metal-to-ligand bonding are the most prominent. Exploring noncovalent interactions in host-guest systems that range from small hydrocarbon systems to more complex systems is the main motivation of this thesis. The present study involves the design, synthesis and characterization of clip-shaped molecules as host structures, and an examination of their binding properties with a variety of guests using NMR spectroscopy. </p><p>Several clips with a hydrocarbon or glycoluril backbone were synthesized. The binding of cations to small, hydrocarbon-based clips suggests that binding is enhanced by the rigidity and cooperativity between the two sidewalls of the clip. Binding is also very much dependant on the solvent properties. </p><p>Glycoluril-based clips built with aromatic sidewalls provide a deep cavity for binding guest molecules. The binding properties of these hosts were studied with several guests such as cations, Lewis acids and Lewis bases. Lewis basic binding sites in the acenaphthene-terminated clip were dominating in guest binding. Complexation-induced conformational changes in the wall-to-wall distance were observed for this clip.</p><p>In contrast, for a porphyrin-terminated clip with metal centers, very strong binding to a series of Lewis basic guests of various sizes into the clip cavity was observed. Conformational locking of guests with long alkyl chains was achieved, suggesting that, this clip could be useful as a potential molecular tool for the structural characterization of acyclic molecules with several stereogenic centers. This porphyrin clip was also shown to bind substituted fullerenes in the cavity.</p>

Organic chemistry

Glycoluril clips

host-guest systems

supramolecular chemistry

complexation induced shifts

conformational restriction

NMR spectroscopy

fullerene binding

Organisk kemi

Targeting Biological Systems by Organic Synthesis Methods - Cancer Cells and Proteins

Winander, Cecilia

January 2008

<p>This thesis describes the design and synthesis of molecules with potential roles in biomedicine, with an emphasis on molecular recognition in complex biological environments. The first chapter describes the synthesis and evaluation of compounds for use in nuclide therapy. Carboranes are frequently used in the development of drugs for Boron Neutron Capture Therapy. New routes for monohydroxylation at the B and C atoms of <i>p</i>-carborane have been developed. The Suzuki-Miyaura reaction has been applied to the cross-coupling of <i>bis</i>(neopentyl glycolato)diboron or <i>bis</i>(pinacolato)diboron and 2-I-<i>p</i>-carborane. The synthesized derivatives are important intermediates in the synthesis of a number of potentially biologically active carborane-containing molecules.</p><p>The DNA intercalator doxorubicin has been functionalized to enable ¹²⁵I labelling. The aim of combining the DNA intercalator with ¹²⁵I was to achieve high delivery of cytotoxic radiation to the nucleus. The DNA-binding ability and cellular uptake of the synthesized compounds have been evaluated. One of the compounds bound strongly to DNA and had similar cellular uptake as daunorubicin, which makes the compound very interesting for further biological evaluation.</p><p>The second chapter describes the use of polypeptide conjugates to broaden our knowledge of molecular recognition. The polypeptides consist of 42 amino acids each and are designed to fold into helix-loop-helix motifs that dimerize due to their amphiphilic character. The polypeptides are combined with a variety of small organic molecules. The incorporation of small aromatic molecules to influence the structure and dynamics of a polypeptide has been investigated. By attaching a dansyl group to the side chain of a lysine residue, the dynamics of the protein’s hydrophobic core where affected to such a degree that a native-like fold was formed. The polypeptide conjugates have also been used to study the binding and recognition of native proteins. High-affinity binders for chitinases and acetylcholine esterase have been developed and evaluated.</p>

Organic chemistry

carborane

doxorubicin

125I

molecular recognition

four-helix bundle

polypeptide conjugate

affinity

chitinase

acetylcholine esterase

Organisk kemi

Targeting Biological Systems by Organic Synthesis Methods - Cancer Cells and Proteins

Winander, Cecilia

January 2008

This thesis describes the design and synthesis of molecules with potential roles in biomedicine, with an emphasis on molecular recognition in complex biological environments. The first chapter describes the synthesis and evaluation of compounds for use in nuclide therapy. Carboranes are frequently used in the development of drugs for Boron Neutron Capture Therapy. New routes for monohydroxylation at the B and C atoms of p-carborane have been developed. The Suzuki-Miyaura reaction has been applied to the cross-coupling of bis(neopentyl glycolato)diboron or bis(pinacolato)diboron and 2-I-p-carborane. The synthesized derivatives are important intermediates in the synthesis of a number of potentially biologically active carborane-containing molecules. The DNA intercalator doxorubicin has been functionalized to enable 125I labelling. The aim of combining the DNA intercalator with 125I was to achieve high delivery of cytotoxic radiation to the nucleus. The DNA-binding ability and cellular uptake of the synthesized compounds have been evaluated. One of the compounds bound strongly to DNA and had similar cellular uptake as daunorubicin, which makes the compound very interesting for further biological evaluation. The second chapter describes the use of polypeptide conjugates to broaden our knowledge of molecular recognition. The polypeptides consist of 42 amino acids each and are designed to fold into helix-loop-helix motifs that dimerize due to their amphiphilic character. The polypeptides are combined with a variety of small organic molecules. The incorporation of small aromatic molecules to influence the structure and dynamics of a polypeptide has been investigated. By attaching a dansyl group to the side chain of a lysine residue, the dynamics of the protein’s hydrophobic core where affected to such a degree that a native-like fold was formed. The polypeptide conjugates have also been used to study the binding and recognition of native proteins. High-affinity binders for chitinases and acetylcholine esterase have been developed and evaluated.

Organic chemistry

carborane

doxorubicin

125I

molecular recognition

four-helix bundle

polypeptide conjugate

affinity

chitinase

acetylcholine esterase

Organisk kemi