Synthesis and Polymerase-Mediated Transcription of Base-Modified 2’-Fluoroarabinose Nucleic Acid in Preparation for Particle Display Selection with Modified Aptamers:

Skrodzki, Christopher J. A.

January 2019

Thesis advisor: Jia Niu / Nucleic acid aptamers are promising alternatives to antibodies for a wide array of diagnostic and therapeutic applications. However, state-of-the-art aptamers suffer from poor pharmacokinetics and diversity, limiting their affinity and specificity for many therapeutically relevant targets. The emerging field of glycoscience provides opportunities to improve the utility of aptamers over antibodies. Combining synthetic chemistry with modern molecular biology and polymer science, the synthesis of Xeno Nucleic Acid monomers and chemoenzymatic polymerization via engineered polymerase enzymes allows the production of nucleic acid drugs with superior resistance to endogenous nucleases. The modular structure of nucleic acids provides for the design of sequence defined polymers capable of post-synthetically appending complex synthetic glycans, extending the catalytic geometry of aptamers. Our SELEX inspired FACS based particle display approach allows for high-throughput screening. Additionally, we expect this method has the capability of screening aptamers in human serum. Our synthetic approach utilizes a Sonogashira cross-coupling reaction to install a flexible alkyne to the major groove of 2′-deoxy-2′-fluoro-arabinose uracil base. By incorporated recent advances in nucleic acid synthesis, one-pot nucleobase activation and sugar glycosylation is achieved and bis-oxybenzyl phosphoamidite synthesis can afford gram scale HPLC-free purification of the triphosphates. The FANA C8-alkyl-uridine triphosphate will be incorporated by an engineered Tgo DNA polymerase to allow systematic introduction of alkynyl conjugation handles into a DNA-templated FANA polymer. Subsequent conjugation with azido-modified glycans via the Huisgen coppercatalyzed alkyne-azide cycloaddition (CuAAC) click reaction will generate sequence controlled nucleic acid-carbohydrate hybrid molecules amendable for directed evolution. / Thesis (MS) — Boston College, 2019. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

aptamers

high through-put screening

modified nucleic acids

nucleic acid analogues

sugar chemistry

xeno nucleic acid

Conformational Bias in 2'-Selenium-Modified Nucleosides and the Effect on Helical Structure and Extracellular Recombinant Protein Production: Current Systems and Applications

Thompson, Richard A

27 April 2011

Part One. X-ray crystallography has benefited from the synthetic introduction of selenium to different positions within nucleic acids by easing the solving of the phase problem. Interestingly, its addition to the 2' position of the ribose ring also significantly enhances crystal formation. This phenomenon was investigated to describe the effect of selenium-based and other 2' modifications to the ribose ring of nucleosides in solution, as well as the incorporation of the selenium-modified nucleotides into a helical structure. This work correlates the difference in conformation propensity between the selenium containing nucleosides and oligomers towards a rationale behind the enhanced crystal forming behavior. Part Two. Recombinant protein production is a critical tool in laboratories and industries, and inducing extracellular transport of these products to the culture medium shows potential for improving cases where the yields are not sufficient in quality or quantity. This review incorporates current practices and systems with future perspectives.

Selenium-modified nucleic acids

NMR spectroscopy

Sugar puckering

Recombinant Protein Secretion

Synthesis and Biochemical Studies of a Novel Thiol Modified Nucleotide

Esmaeili, Razieh

17 December 2014

Nucleic acids are important bio-macromolecules in living systems. They are involved in important functions like gene expression and regulation. Nucleoside triphosphates serve as precursors for biochemical synthesis of modified nucleic acids and nucleotide coenzymes. The modification of nucleic acids, particularly at nucleobases, can expand the function and chemical properties of nucleic acid. Herein, we report the chemical synthesis of a novel thiol-modified nucleoside S-(3-(acetylthio)propyl)-5-(mercaptomethyl)-uridine and the corresponding nucleotide via a “new synthetic methodology” developed in our laboratory. The synthesized triphosphate was used for RNA transcription. The activity and nuclease resistance of the transcribed RNA is studied. The results showed that the properties of the nucleotide with thiol functionality are as good as the native. The modified RNA can be used for RNA/protein complex structure studies and gold nanoparticles stabilizer. They can also serve as a probe in DNA/RNA microchip surface functionalization for detection of various diseases and pathogens.

Modified nucleic acids

Nucleoside

Thiol-modification of nucleic acids

Transcription

Hammerhead ribozyme

Thiol-uridine

Nucleoside 5’-triphosphate

Nucleosylaminosäuren als Bausteine zur Synthese modifizierter Oligonucleotide / Nucleosyl Amino Acids as Building Blocks for the Synthesis of Modified Oligonucleotides

Schmidtgall, Boris

09 May 2014

No description available.

571.4

Modifizierte Nucleinsäuren

Nucleoside

Nucleosylaminosäuren

modified nucleic acids

nucleosides

nucleosyl amino acids

Biologie (PPN619462639)

Characterization of two unique pathways for wyosine biosynthesis in Kinetoplastids

Sample, Paul J.

09 September 2014

No description available.

Microbiology

Molecular Biology

Bioinformatics

trypanosomes

wyosine

wybutosine

hydroxywybutosine

mitochondria

organelle

tRNA

transfer RNA

tRNA modification

modified nucleic acids

modified nucleotides

rna mass spec de novo sequencing

mass spectrometry

robooligo