In vitro genetic code expansion and selected applications

Iqbal, Emil S

01 January 2018

The ability of incorporation non-canonical amino acids (ncAAs) using translation offers researchers the ability of extend the functionality of proteins and peptides for many applications including synthetic biology, biophysical and structural studies, and discovery of novel ligands. Here we describe the three projects where the addition of ncAAs to in vitro translation systems creates useful chemical biology techniques. In the first, a fluorinated histidine derivative is used to create a novel affinity tag that allows for the selective purification of peptides from a complex mixture of proteins. In the second, the high promiscuity of an editing-deficient valine-tRNA synthetase (ValRS T222P) is used to demonstrate ribosomal translation of 13 ncAAs including those with novel side chains, α,α disubstitutions, and cyclic β amino acids. Lastly, a couple of these amino acids are integrated into the powerful ligand discovery tool of mRNA display for the discovery of helical peptide ligands.

genetic code expansion

unnatural amino acids

mRNA display

in vitro peptide synthesis

Amino Acids, Peptides, and Proteins

Molecular Biology

Structure-Function Relationships of Pi Class Glutathione Transferase Studied by Protein Engineering

Hegazy, Usama M.

January 2006

<p>The glutathione transferases (GSTs) represent a superfamily of dimeric proteins involved in cellular detoxication by catalyzing the nucleophilic addition of the reduced glutathione (GSH) to the hydrophobic electrophiles. The present work focuses on the functional role of the conserved structures of GSTP1-1. The lock-and-key motif is a highly conserved hydrophobic interaction in the subunit interface of Pi, Mu, and Alpha class GSTs. The key residue (Tyr⁵⁰ in hGSTP1-1) of one subunit is wedged into a hydrophobic pocket of the neighboring subunit. The heterodimer GSTP1/Y50A was constructed from the fully active wild-type GSTP1-1 and the nearly inactive Y50A in order to study how an essentially inactive subunit influences the activity of the neighboring subunit. The results illuminate the vital role of the lock-and-key motif in modulating the GSH binding and the rate of catalysis. Additionally, the two active sites of the dimeric enzyme work synergistically. An observed water network, in hGSTP1-1 structures, connects the two active sites, thereby offering a mechanism for communication between the two active sites.</p><p>Cys⁴⁸ and Tyr⁵⁰ were targeted by mutations and chemical modifications for understanding how the α2 loop residues modulate GSH binding and catalysis. The replacement of Tyr⁵⁰ with different unnatural amino acids showed that the nature of the key residue side-chain influences the interaction with the lock structure and, consequently, the catalytic activity. The K_M^GSH, GSH affinity and protein stability can be modulated by fitting key residue into the lock cavity of the neighbor subunit and, consequently, restriction of the flexibility of the α2 loop. Optimization of the interaction between the key residue and the lock-cavity increases k_cat. Also, the crystal structure of the Cys-free variant was determined. The result indicated that Cys⁴⁸ restricts the flexibility of the α2 loop by interacting with surrounding residues and, consequently, contributes to GSH binding and protein stability.</p>

Biochemistry

Glutathione transferase

targeted chemical modification

lock-and-key motif

cooperativity

stucture-function relationship

protein engineering

unnatural amino acid

site-specific mutation

Biokemi

Structure-Function Relationships of Pi Class Glutathione Transferase Studied by Protein Engineering

Hegazy, Usama M.

January 2006

The glutathione transferases (GSTs) represent a superfamily of dimeric proteins involved in cellular detoxication by catalyzing the nucleophilic addition of the reduced glutathione (GSH) to the hydrophobic electrophiles. The present work focuses on the functional role of the conserved structures of GSTP1-1. The lock-and-key motif is a highly conserved hydrophobic interaction in the subunit interface of Pi, Mu, and Alpha class GSTs. The key residue (Tyr50 in hGSTP1-1) of one subunit is wedged into a hydrophobic pocket of the neighboring subunit. The heterodimer GSTP1/Y50A was constructed from the fully active wild-type GSTP1-1 and the nearly inactive Y50A in order to study how an essentially inactive subunit influences the activity of the neighboring subunit. The results illuminate the vital role of the lock-and-key motif in modulating the GSH binding and the rate of catalysis. Additionally, the two active sites of the dimeric enzyme work synergistically. An observed water network, in hGSTP1-1 structures, connects the two active sites, thereby offering a mechanism for communication between the two active sites. Cys48 and Tyr50 were targeted by mutations and chemical modifications for understanding how the α2 loop residues modulate GSH binding and catalysis. The replacement of Tyr50 with different unnatural amino acids showed that the nature of the key residue side-chain influences the interaction with the lock structure and, consequently, the catalytic activity. The KMGSH, GSH affinity and protein stability can be modulated by fitting key residue into the lock cavity of the neighbor subunit and, consequently, restriction of the flexibility of the α2 loop. Optimization of the interaction between the key residue and the lock-cavity increases kcat. Also, the crystal structure of the Cys-free variant was determined. The result indicated that Cys48 restricts the flexibility of the α2 loop by interacting with surrounding residues and, consequently, contributes to GSH binding and protein stability.

Biochemistry

Glutathione transferase

targeted chemical modification

lock-and-key motif

cooperativity

stucture-function relationship

protein engineering

unnatural amino acid

site-specific mutation

Biokemi

From Probes to Cell Surface Labelling: Towards the Development of New Chemical Biology Compounds and Methods

Legault, Marc

29 June 2011

Chemical biology encompasses the study and manipulation of biological system using chemistry, often by virtue of small molecules or unnatural amino acids. Much insight has been gained into the mechanisms of biological processes with regards to protein structure and function, metabolic processes and changes between healthy and diseased states. As an ever expanding field, developing new tools to interact with and impact biological systems is an extremely valuable goal. Herein, work is described towards the synthesis of a small library of heterocyclic-containing small molecules and the mechanistic details regarding the interesting and unexpected chemical compounds that arose; an alternative set of non-toxic copper catalyzed azide-alkyne click conditions for in vivo metabolic labelling; and the synthesis of an unnatural amino acid for further chemical modification via [3+2] cycloadditions with nitrones upon incorporation into a peptide of interest. Altogether, these projects strive to supplement pre-existing methodology for the synthesis of small molecule libraries and tools for metabolic labelling, and thus provide further small molecules for understanding biological systems.

CuAAC

click chemistry

N-heterocyclic carbene

intramolecular cyclization

diversity oriented synthesis

unnatural amino acid

metabolic labelling

rearrangement

small molecule library

chemical biology

bioorthogonal

From Probes to Cell Surface Labelling: Towards the Development of New Chemical Biology Compounds and Methods

Legault, Marc

29 June 2011

Chemical biology encompasses the study and manipulation of biological system using chemistry, often by virtue of small molecules or unnatural amino acids. Much insight has been gained into the mechanisms of biological processes with regards to protein structure and function, metabolic processes and changes between healthy and diseased states. As an ever expanding field, developing new tools to interact with and impact biological systems is an extremely valuable goal. Herein, work is described towards the synthesis of a small library of heterocyclic-containing small molecules and the mechanistic details regarding the interesting and unexpected chemical compounds that arose; an alternative set of non-toxic copper catalyzed azide-alkyne click conditions for in vivo metabolic labelling; and the synthesis of an unnatural amino acid for further chemical modification via [3+2] cycloadditions with nitrones upon incorporation into a peptide of interest. Altogether, these projects strive to supplement pre-existing methodology for the synthesis of small molecule libraries and tools for metabolic labelling, and thus provide further small molecules for understanding biological systems.

CuAAC

click chemistry

N-heterocyclic carbene

intramolecular cyclization

diversity oriented synthesis

unnatural amino acid

metabolic labelling

rearrangement

small molecule library

chemical biology

bioorthogonal

Investigation of Nucleosome Dynamics by Genetic Code Expansion

Hahn, Liljan

10 March 2015

No description available.

572

Genetic code expansion

Unnatural amino acids

PTM (posttranslational modifications)

Lysine acylations

Propionylation

Crotonylation

Butyrylation

Acetylation

Click chemistry

Protein labeling

FRET

Biologie (PPN619462639)

ENGINEERING PROTEINS WITH UNIQUE CHARACTERISTICS FOR DIAGNOSTICS AND BIOSENSORS

Joel, Smita

01 January 2011

Proteins possess a broad range of structural and functional properties and, therefore, can be employed in a variety of biomedical applications. While a good number of protein-based biosensing systems and biosensors for target analytes have been developed, the search for versatile, highly sensitive and selective sensors with long term stability able to provide fast detection of target analytes continues to be a challenge. To that end, we now report the design and development of modified proteins with tailored characteristics and their further utilization in the development of biosensing systems. We take advantage of binding proteins that undergo a change in conformation upon binding to their respective target ligand analytes for the development of highly selective biosensing systems. The first class of binding proteins that was explored for this purpose was antibodies. A non-canonical site in the variable region of a monoclonal antibody was tagged with a fluorescent probe to sense the binding of analyte to its corresponding antigen-binding site. The strategy employed for designing antibodysensing molecules is universal as it can be employed for sensing any biomolecule of interest provided that there is an available antibody against the target ligand analyte. In a second strategy, we utilized designer glucose recognition proteins (GRPs) that were prepared by incorporation of unnatural amino acids in the glucose/galactose binding protein (GBP) of Escherichia coli and its truncated fragments. By taking advantage of the global incorporation method, we were able to fine-tune the binding affinity and thermal stability of the proteins, thus, allowing for the development of a reagentless fluorescence based fiber optic glucose biosensor capable of monitoring glucose in the hypoglycemic, normal, and hyperglycemic range, as well as in the hypothermic and hyperthermic temperature range.

protein-based biosensing systems

antibody

glucose recognition proteins

fiber optic glucose biosensor

Biology

Physical Sciences and Mathematics

From Probes to Cell Surface Labelling: Towards the Development of New Chemical Biology Compounds and Methods

Legault, Marc

29 June 2011

Chemical biology encompasses the study and manipulation of biological system using chemistry, often by virtue of small molecules or unnatural amino acids. Much insight has been gained into the mechanisms of biological processes with regards to protein structure and function, metabolic processes and changes between healthy and diseased states. As an ever expanding field, developing new tools to interact with and impact biological systems is an extremely valuable goal. Herein, work is described towards the synthesis of a small library of heterocyclic-containing small molecules and the mechanistic details regarding the interesting and unexpected chemical compounds that arose; an alternative set of non-toxic copper catalyzed azide-alkyne click conditions for in vivo metabolic labelling; and the synthesis of an unnatural amino acid for further chemical modification via [3+2] cycloadditions with nitrones upon incorporation into a peptide of interest. Altogether, these projects strive to supplement pre-existing methodology for the synthesis of small molecule libraries and tools for metabolic labelling, and thus provide further small molecules for understanding biological systems.

CuAAC

click chemistry

N-heterocyclic carbene

intramolecular cyclization

diversity oriented synthesis

unnatural amino acid

metabolic labelling

rearrangement

small molecule library

chemical biology

bioorthogonal

From Probes to Cell Surface Labelling: Towards the Development of New Chemical Biology Compounds and Methods

Legault, Marc

January 2011

Chemical biology encompasses the study and manipulation of biological system using chemistry, often by virtue of small molecules or unnatural amino acids. Much insight has been gained into the mechanisms of biological processes with regards to protein structure and function, metabolic processes and changes between healthy and diseased states. As an ever expanding field, developing new tools to interact with and impact biological systems is an extremely valuable goal. Herein, work is described towards the synthesis of a small library of heterocyclic-containing small molecules and the mechanistic details regarding the interesting and unexpected chemical compounds that arose; an alternative set of non-toxic copper catalyzed azide-alkyne click conditions for in vivo metabolic labelling; and the synthesis of an unnatural amino acid for further chemical modification via [3+2] cycloadditions with nitrones upon incorporation into a peptide of interest. Altogether, these projects strive to supplement pre-existing methodology for the synthesis of small molecule libraries and tools for metabolic labelling, and thus provide further small molecules for understanding biological systems.

CuAAC

click chemistry

N-heterocyclic carbene

intramolecular cyclization

diversity oriented synthesis

unnatural amino acid

metabolic labelling

rearrangement

small molecule library

chemical biology

bioorthogonal

Photoredox catalysis enabled C–O bond activation: Access to unnatural amino acids / Fotoredoxkatalyserad aktivering av C–O bindningar: Syntes av icke-naturliga aminosyror

Lantz, Josefin

January 2021

Fotoredoxkatalys tillhandahåller möjligheter att utveckla nya hållbara kemiska reaktionsvägar. När fotokatalysatorn bestrålas med synligt ljus möjliggörs elektronöverföring till eller från substratet som i sin tur medför alstring av reaktiva fria radikaler. Kolradikaler, genererade med fotoredox-katalys från alkyloxalataktiverade alkoholer, har framgångsrikt kopplats till sulfinyliminer och möjliggör därigenom syntes av onaturliga α-aminosyror. Reaktionen utförs vid rumstemperatur och kräver endast extern energi i form av synligt ljus för att aktivera den iridium-baserade fotokatalysatorn. Den höga tillgängligheten av alkoholer utgör ett rimligt skäl för att använda dem som startmaterial. I detta projekt har tertiära alkoholer resulterat i framgångsrika reaktioner. / Photoredox catalysis provides opportunities to develop new sustainable chemical reaction pathways through single-electron transfer events and generation of reactive free-radical species. In this thesis carbon radicals, generated with photoredox catalysis from alkyl oxalate-activated alcohols, have successfully been coupled to sulfinyl imines and thereby enabling synthesis of unnatural α-amino acids. The reaction is performed at room temperature and only requires external energy in the form of visible light to activate the iridium-based photocatalyst. The abundance and availability of alcohols presents good reasons to use them as radical precursors. Under the developed reaction conditions, tertiary alcohols proved to be successful radical precursors, giving the desired product in good yield.

photoredox catalysis

unnatural amino acids

alkyl oxalate

visible light

radicals

fotoredoxkatalys

icke-naturliga aminosyror

alkyloxalat

synligt ljus

radikaler

Organic Chemistry

Organisk kemi