Synthesis of bespoke matrices to investigate a novel anti-tumour molecular target using affinity chromatography : the design, synthesis and evaluation of biotinylated biarylheterocycles used as novel affinity probes in the identification of anti-tumour molecular targets

Evans, Hayley Ruth

January 2010

Three novel, synthetic biarylheterocycles bearing imidazole terminal groups had previously been discovered with high cytotoxicity (IC₅₀ 16-640 nM) against a number of human tumour cell lines. Notably, this biological activity was independent of duplex DNA binding affinity. The compounds were tested in the NCI 60-cell line panel and COMPARE analysis suggests they have a novel mechanism of action, targeting the product of a 'gene-like sequence' of unidentified function. The identity of likely protein targets was explored using a chemical proteomic strategy. Bespoke affinity matrices for chromatography were prepared in which test compounds were attached to a solid support through a biotin tag. A synthetic route to hit compounds containing a biotin moiety in place of one of the imidazole sidechains was developed. Chemosensitivity studies confirmed that the biotinylated compounds retained their activity showing IC₅₀ = 6.25 μM in a susceptible cell line, compared with > 100 μM for an insensitive cell line. The biotinylated ligands were complexed to a streptavidin-activated affinity column and exposed to cell lysates from the susceptible cell lines. Bound proteins were eluted from the column and separated using SDS-PAGE. Proteins were characterised by MALDI MS and MS/MS and identified using Mascot database searches. Heterogeneous nuclear ribonuclear protein A2/B1 was found to selectively bind to the affinity probes.

615.19

Targeting RNA by the Antisense Approach and a Close Look at RNA Cleavage Reaction

Barman, Jharna

January 2007

This thesis summarizes the results of studies on two aspects of nucleic acids. Chemically modified antisense oligonucleotides (AONs) have been evaluated with regards to their suitability for mRNA targeting in an antisense approach (Paper I – III). The chemically modified nucleotidic units 2'-O-Me-T, 2'-O-MOE-T, oxetane-T, LNA-T, azetidine-T, aza-ENA-T, carbocyclic-ENA-T and carbocyclic-LNA-T were incorporated into 15-mer AONs and targeted against a 15-mer RNA chosen from the coding region of SV-40 large T antigen. The comparative study showed that a single modified nucleotide in the AON with North-East locked sugar (oxetane-T and azetidine-T) lowered the affinity for the complementary RNA whereas North locked sugars (LNA-T, aza-ENA-T, carbocyclic-ENA-T, and carbocyclic-LNA-T) significantly improved the affinity. A comparative RNase H digestion study showed that modifications of the same type (North-East type or North type) in different sequences gave rise to similar cleavage patterns. Determination of the Michaelis-Menten parameters by kinetic experiments showed that the modified AONs recruit RNase H resulting in enhanced turnover numbers (kcat) although with weaker enzyme-substrate binding (1/Km) compared to the unmodified AON. The modified AONs were also evaluated with regards to resistance towards snake venom phosphodiesterase and human serum to estimate their stability toward exonucleases. The aza-ENA-T and carbocyclic-ENA-T modified AONs showed improved stability compared to all other modified AONs. In general, the modified AONs with North type nucleotides (except LNA-T) were found to be superior to the North-East type as they showed improved target affinity, comparable RNase H recruitment capability and improved exonuclease stability. The second aspect studied in this thesis is based on physicochemical studies of short RNA molecules utilizing NMR based pH titration and alkaline hydrolysis reactions (Paper IV – V). The NMR based (1H and 31P) pH titration studies revealed the effect of guaninyl ion formation, propagated electrostatically through a single stranded chain in a sequence dependent manner. The non-identical electronic character of the internucleotidic phosphodiesters was further verified by alkaline hydrolysis experiments. The internucleotidic phosphodiesters, which were influenced by guaninyl ion formation, were hydrolyzed at a faster rate than those sequences where such guaninyl ion formation was prevented by replacing G with N1-Me-G.

Organic chemistry

mRNA targeting

antisense oligonucleotides

target affinity

RNase H

Michaelis-Menten kinetics

exo-nuclease stability

NMR

pH titration

alkaline hydrolysis

Organisk kemi

Conformationally Constrained Nucleosides, Nucleotides and Oligonucleotides : Design, Synthesis and Properties

Honcharenko, Dmytro

January 2008

This thesis is based on six original research publications describing synthesis, structure and physicochemical and biochemical analysis of chemically modified oligonucleotides (ONs) in terms of their potential diagnostic and therapeutic applications. Synthesis of two types of bicyclic conformationally constrained nucleosides, North-East locked 1',2'-azetidine and North locked 2',4'-aza-ENA, is described. Study of the molecular structures and dynamics of bicyclic nucleosides showed that depending upon the type of fused system they fall into two distinct categories with their respective internal dynamics and type of sugar conformation. The physicochemical properties of the nucleobases in the conformationally constrained nucleosides found to be depended on the site and ring-size of the fused system. The incorporation of azetidine modified nucleotide units into 15mer ONs lowered the affinity toward the complementary RNA. However, they performed better than previously reported isosequential 1',2'-oxetane modified analogues. Whereas aza-ENA-T modification incorporated into ONs significantly enhanced affinity to the complementary RNA. To evaluate the antisense potential of azetidine-T and aza-ENA-T modified ONs, they were subjected to RNase H promoted cleavage as well as tested towards nucleolytic degradation. Kinetic experiments showed that modified ONs recruit RNase H, however with lower enzyme efficiency due to decreased enzyme-substrate binding affinity, but with enhanced turnover number. Both, azetidine-T and aza-ENA-T modified ONs demonstrated improved 3'-exonuclease stability in the presence of snake venom phosphodiesterase and human serum compared to the unmodified sequence. Oligodeoxynucleotides (ODNs) containing pyrene-functionalized azetidine-T (Aze-pyr X) and aza-ENA-T (Aza-ENA-pyr Y) modifications showed different fluorescence properties. The X modified ODNs hybridized to the complementary DNA and RNA showed variable increase in the fluorescence intensity depending upon the nearest-neighbor at the 3'-end to X modification (dA > dG > dT > dC) with high fluorescence quantum yield. However, the Y modified ODNs showed a sensible enhancement of the fluorescence intensity only with complementary DNA. Also, the X modified ODN showed decrease (~37-fold) in the fluorescence intensity upon duplex formation with RNA containing a G nucleobase mismatch opposite to the modification site, whereas a ~3-fold increase was observed for the Y modified probe.

Bioorganic chemistry

antisense oligonucleotides

conformationally constrained nucleosides

azetidine

aza-ENA

target affinity

RNase H

exonuclease stability

pyrene-functionalized nucleotides

fluorescence

mismatch discrimination

Bioorganisk kemi

Cell and molecular biology

Cell- och molekylärbiologi