Synthetic Nucleic Acid Capable of Post-Polymerization Functionalization and Evolution:

Wu, Kevin B.

January 2023

Thesis advisor: Jia Niu / Thesis advisor: Abhishek Chatterjee / The functions of natural nucleic acids such as DNA and RNA have transcended from serving as the primary information carrier in cells and have emerged as a new class of functional material with applications encompassing medicine, diagnosis, and research tools. While the vulnerability of natural nucleic acids to nuclease degradation as well as the lack of chemical functionality have imposed a significant constraint on their ever-expanding applications, scientists have put in the effort to develop new classes of synthetic nucleic acids (XNAs) to overcome current limitations. In this dissertation, we will describe the development of a novel XNA oligonucleotide structure, the “click handle-modified FANA” (cmFANA), as the next-generation nucleic acid-based biopolymer that is capable of post-polymerization functionalization and evolution. In this dissertation, we divide our graduate research into three chapters: the development of the essential building block for cmFANA and the synthesis of cmFANA oligonucleotide as Chapter 1; the evolution and application of cmFANA as a sugar-presenting affinity reagent that targets disease-related Carbohydrate-Binding Proteins (CBPs) as Chapter 2; and other collaboration projects as Chapter 3. Together, we described a highly potential XNA structure that goes beyond established impressions of nucleic acids and carries the ability to be a versatile platform technology. / Thesis (PhD) — Boston College, 2023. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

aptamer

bioorthogonal conjugation

Carbohydrate-Binding Protein

nucleic acid

oligonucleotide

XNA

Développement de nouvelles réactions de click in situ appliquées à la synthése d'inhibiteurs de la β-sécrétase. / Synthesis of bio-organic tools for the development of new in situ click reaction applied to the synthesis of β-secretase inhibitors

Lizzul-Jurse, Antoine

13 January 2017

La synthèse contrôlée par la cible sous contrôle cinétique (Kinetic Target-Guided Synthesis, KTGS) est une approche relativement peu explorée, alternative à la chimie combinatoire traditionnelle,dans laquelle la protéine cible participe à la synthèse du ou de ses propres ligands. Ainsi, les travaux présentés dans la première partie de cette thèse ont pour principal objectif d'élargir l'éventail des réactions actuellement disponibles en KTGS grâce à la réaction d'aldolisation voire d'amidation, et ce en utilisant la β-sécrétase (BACE-1) comme cible biologique, qui est une enzyme étroitement impliquée dans la maladie d'Alzheimer. La seconde partie de cette thèse a été consacrée à la synthèse de marqueurs de masse fluorescents bioconjugables basés sur l'association d'un noyau coumarinique et d'une fonction phosphonium. Les deux générations présentées dans ce manuscrit ont entre autre permis de synthétiser une sonde FRET permettant de détecter l'activité enzymatique de la BACE-1, qui pourrait par ailleurs être un outil intéressant pour l'analyse des bruts réactionnels des réactions de click in situ,et diminuer les quantités d'enzyme engagées dans ces expériences. Enfin dans la dernière partie de cette thèse nous décrivons la mise au point de nouvelles réactions de conjugaison bio-orthogonale pour le marquage de molécules comportant une fonction aldéhyde. Nous avons ainsi développé d'une part une réaction trois composants via une séquence de condensation/Mannich/lactamisation et d'autre part une réaction d'oléfination de Wittig. / The kinetic target-guided synthesis (KTGS), is an underexplored alternative approach to combinatorial chemistry, in which the biological target is able to assemble its own inhibitors from a pool of fragments. Thus, the first part of this thesis aimed at extending the scope of the reactions available for the KTGS, by investigating the aldolisation and amidation reaction, using the β-secretase (BACE-1) as biological target, which is an enzyme narrowly involved in the Alzheimer's disease. The second part of this thesis was dedicated to the synthesis of bioconjagatable fluorophores containing a phosphonium group as mass tag associated to a coumarin core. Both generations presented in this manuscript allowed us, among other things, to synthesize a FRET probe that proved suitable for the determination of BACE-1 enzymatic activity. The utility of such a fluorogenic tool could be leveraged to facilitate the analysis of crude mixtures obtained during KTGS experiments, and lessen the amount of enzyme required in these experiments. Finally, in the last part of this thesis, we describe the development of two new bioorthogonal reactions allowing the selective labeling of molecules containing an aldehyde moiety : 1) a three component reaction involving a condensation/Mannich/lactamisation procedure, between an amine, an aldehyde and an enol partner; 2) a Wittig ligation between an aldehyde and a phosphonium bearing an active methylene.

Dir. chimie

BACE-1

Marqueur de masse

Coumarine

Phosphonium

Conjugaison bio-orthogonale

Kinetic target-guided synthesis

BACE-1

Mass tag

Coumarin

Phosphonium

Bioorthogonal conjugation

541.39

Site-specific functionalization of antigen binding proteins for cellular delivery, imaging and target modulation

Schumacher, Dominik

09 November 2017

Antikörper und Antigen-bindende Proteine, die an Fluorophore, Tracer und Wirkstoffe konjugiert sind, sind einzigartige Moleküle, welche die Entwicklung wertvoller diagnostischer und therapeutischer Werkzeuge ermöglichen. Allerdings ist der Konjugationsschritt sehr anspruchsvoll und trotz intensiver Forschung noch immer ein bedeutender Engpass. Zusätzlich sind Antigen-bindende Proteine oftmals nicht dazu in der Lage, die Zellmembran zu durchdringen und im Zellinneren nicht funktionsfähig. Daher ist ihre Verwendung auf extrazelluläre Targets beschränkt, was eine bedeutende Anzahl wichtiger Antigene vernachlässigt. Beide Limitierungen bilden Kernaspekte dieser Arbeit. Mit Tub-tag labeling wurde ein neuartiges und vielseitiges Verfahren für die ortsspezifische Funktionalisierung von Biomolekülen und Antigen-bindenden Proteinen entwickelt, und so die Palette der Proteinfunktionalisierungen bedeutend erweitert. Tub-tag wurde erfolgreich für die ortsspezifische Funktionalisierung verschiedener Proteine und Antigen-bindender Nanobodies angewendet, die für konfokale Mikroskopie, Proteinanreicherung und hochauflösende Mikroskopie eingesetzt wurden. In einem weiteren Projekt wurden zellpermeable Antigen-bindende Nanobodies hergestellt und somit das schon lange Zeit bestehende Ziel, intrazelluläre Targets durch in vitro funktionalisierte Antigen-bindende Proteine zu visualisieren und manipulieren, erreicht. Hierzu wurden zwei verschiedene Nanobodies an ihrem C-Terminus cyclischen zellpenetrierenden Peptiden unter Verwendung von Expressed Protein Ligation funktionalisiert. Diese Peptide ermöglichten die Endozytose-unabhängige Aufnahme der Nanobodies mit sofortiger Bioverfügbarkeit. Mit Tub-tag labeling und der Synthese von zellpermeablen Nanobodies konnten wichtige Bottlenecks im Bereich der Proteinfunktionalisierung und Antikörperforschung adressiert werden und neue Tools für die biochemische und zellbiologische Forschung entwickelt werden. / Antibodies and antigen binding proteins conjugated to fluorophores, tracers and drugs are powerful molecules that enabled the development of valuable diagnostic and therapeutic tools. However, the conjugation itself is highly challenging and despite intense research efforts remains a severe bottleneck. In addition to that, antibodies and antigen binding proteins are often not functional within cellular environments and unable to penetrate the cellular membrane. Therefore, their use is limited to extracellular targets leaving out a vast number of important antigens. Both limitations are core aspects of the presented thesis. With Tub-tag labeling, a novel and versatile method for the site-specific functionalization of biomolecules and antigen binding proteins was developed expanding the toolbox of protein functionalization. The method is based on the microtubule enzyme tubulin tyrosine ligase. Tub-tag labeling was successfully applied for the site-specific functionalization of different proteins including antigen binding nanobodies which enabled confocal microscopy, protein enrichment and super-resolution microscopy. In addition to that, cell permeable antigen binding nanobodies have been generated constituting a long thought goal of tracking and manipulating intracellular targets by in vitro functionalized antigen binding proteins. To achieve this goal, two different nanobodies were functionalized at their C-terminus with linear and cyclic cell-penetrating peptides using expressed protein ligation. These peptides triggered the endocytosis independent uptake of the nanobodies with immediate bioavailability. Taken together, Tub-tag labeling and the generation of cell-permeable antigen binding nanobodies strongly add to the functionalization of antibodies and their use in biochemistry, cell biology and beyond.

Nanobodies

Antigen-bindende Proteine

Endozytose-unabhängige Zellaufnahme

Ortsspezifische Funktionalisierung

Tubulin Tyrosin Ligase

Bioorthogonale Konjugation

Manipulation intrazellulärer Antigene

Protein-Protein-Interaktionen

Antigen transport

Nanobodies

antigen binding proteins

site-specific functionalization

Tubulin Tyrosine Ligase

bioorthogonal conjugation

co-transport of antigens

manipulation of intracellular antigens

protein-protein interactions

572 Biochemie

547 Organische Chemie

570 Biowissenschaften; Biologie

WD 5085

WF 9900

VK 8567

ddc:572

ddc:547

ddc:540

ddc:570