Cellular and Computational Evaluation of the Structural Pharmacology of Delta Opioid Receptors

Yazan J Meqbil (14210360)

05 December 2022

<p>G-protein coupled receptors (GPCRs) are membrane proteins that constitute ~30% of the FDA-approved drug targets. Opioid receptors are a subtype of GPCRs with four different receptor types: delta, kappa, mu, and nociception opioid receptors. Opioids such as morphine have been used for thousands of years and are deemed the most effective method for treating pain. However, opioids can have detrimental effects if used illicitly or over an extended period of time. Intriguingly, most of the clinically used opioids act on the mu opioid receptor (µOR). Hence, efforts in recent decades have focused on other opioid receptors to treat pain and other disorders. The delta opioid receptor (δOR) is one of four opioid receptors expressed in the central and peripheral nervous system. The δOR has attracted much attention as a potential target for a multitude of diseases and disorders including substance and alcohol use disorders, ischemia, migraine, and neurodegenerative diseases. However, to date, no δOR agonists, or drugs that act directly at the δOR, have been successful as clinical candidates. Nonetheless, the therapeutic potential of the δOR necessitates the targeting its pharmacologically. In this dissertation, I highlight peptide-based modulation as well as the identification of novel agonists at the δOR. I report research findings in the context of biased agonism at δOR, which is a hypothesized cellular signaling mechanism with potential therapeutic benefits. The focus on this work is the molecular determinants of biased agonism, which were investigated using a combination of cellular and computational approaches.  </p>

Basic pharmacology

Biomolecular modelling and design

Proteins and peptides

Computational chemistry

structure-based drug design (SBDD)

Opioid Receptors Signaling

Hit identification

Molecular modeling

Drug Design of β-Lactamase Inhibitors of the DBO-scaffold against OXA-48 : A Molecular Dynamics Study of Ligand Stability in the Michaelis Complex

Liljeholm, Linda

January 2022

The emergence of β-lactamase-mediated antibiotic resistance is one of the biggest threats in modern times. Combined with the discovery void of new forms of antibiotics, this sets the course toward a future where the efficacy of present-day health care will be jeopardized. To hinder the spread of β-lactamase-mediated antibiotic resistance, the development of the drug class β-lactamase inhibitors has been prioritized. The foremost candidate for development of this drug class, that has wide-spectrum inhibition of β-lactamases, is the clinically available avibactam of the diazabicyclooctane-scaffold (i.e., DBO-scaffold). However, the clinical applications of this inhibitor have been limited against one of the more rapidly spreading β-lactamases; OXA-48. In order to bolster the drug development of β-lactamase inhibitors of the DBO-scaffold, with good inhibitory activity toward OXA-48, DBO-ligands with different structure elements were analyzed for stability of the Michaelis Complex in the OXA-48 binding site using molecular dynamic simulations. The results indicate that elongation of the chain to the anionic group of the ligand combined with the addition of a methyl group to the DBO-ring was stabilizing for the productive position between the backbone hydrogens of Y211 and S70. The binding affinity was also estimated using the Linear Interaction Energy method, and an offset parameter of γ ≈ -19 kcal/mol was found and could represent the entropic differences of a flexible ligand-protein system. The results of this study may also indicate that the ligand stability of the Michaelis Complex is of minor consequence to the inhibition mechanism as a whole compared to the reaction rate.

OXA-48

β-lactamase

DBO inhibitors

diazabicyclooctane

avibactam

relebactam

β-lactamase inhibitor

BLI

molecular dynamics

LIE

Linear Interaction Energy

antibiotic resistance

drug design

Analytical Chemistry

Analytisk kemi

Physical Chemistry

Fysikalisk kemi

Design, Synthesis, and Process Chemistry Studies of Agents Having Anti-Cancer Properties

Luniwal, Amarjit

26 May 2011

No description available.

Chemistry

Design

Pharmaceuticals

Pharmacy Sciences

Drug Design

Scale-up Synthesis

Molecular docking studies

Estrogen receptors

Selective estrogen receptor modulators

Breast Cancer

Prostate Cancer

Process Chemistry

Glyceollins

Pterocarpans

Glycinol

Benzofuran

Dihydroxylation

Isoprenylation

Structure-Based Computer Aided Drug Design and Analysis for Different Disease Targets

Kumari, Vandana

13 September 2011

No description available.

Bioinformatics

Biophysics

Pharmacy Sciences

structure-based drug design

Molecular modeling

protein structure prediction

virtual screening

Free energy calculation

molecular dynamic simulation

Molecular docking

Surface plasmon resonance

Synthesis of Carbohydrate-based Inhibitors of Antigen 85

Umesiri, Francis E.

January 2010

No description available.

Pharmaceuticals

Biochemistry

Biomedical Research

Chemistry

Organic Chemistry

tuberculosis

TB

mycobacterium tuberculosis

antigen 85' mycobacterial cell wall

inhibitors of mycobacterial synthesis

bacterial cell wall synthesis

mycolyltransferase assay

enzyme

tuberculosis drugs

new TB drugs

drug design for TB

Theoretical Studies of Molecular Recognition in Protein-Ligand and Protein-Protein Complexes

Yang, Hui

January 2010

No description available.

Chemistry

quantum chemical

molecular recognition

supermolecular approach

solvation correction

nonbonded interactions

HIV-1

Reverse Transcriptase

non-nucleoside inhibitor

trp 229

Botulinum neurotoxin B

synaptotagmin II

ASADH

structure-based drug design

Biophysical characterization of and screening for binders and potentiator compounds that modulate the binding of PDZ domains to the C-terminal peptide motifs of target proteins

Olsson, Carl

January 2021

The N-methyl-D-aspartate receptor (NMDAR) hypofunctional hypothesis is believed to explain one of the contributing factors to schizophrenia. This hypothesis suggests the dysregulation of NMDAR, a protein responsible for receiving signals from the synapses between neurons, is the cause of some of the symptoms seen in schizophrenia. The post synaptic density protein 95 (PSD95) uses its PDZ-domains to help facilitate the received signal from NMDAR to α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (AMPAR) which in turn transmits the signal through the neuron. One way to increase the function of NMDAR could be to increase its affinity towards PDZ-domains of PSD95 using a small molecule. Fragment based drug design (FBDD) is one way to screen for molecules that modulates the NMDAR-PDZ interaction. This work describes the development of differential scanning fluorimetry (DSF) and surface plasmon resonance (SPR) assays using a fusion protein to screen for molecules that potentiate the interaction between NMDAR and AMPAR as well as methods assisting in the prioritization of hits based on both affinity, selectivity, and mechanism. The developed assays were used to screen a library containing 768 compounds. Screen positives and other compounds of interest were triaged and evaluated based on affinity, selectivity, and ability to modulated peptide binding resulting in eight confirmed hits that interacts with the two PDZ-domains of PSD95 investigated. As part of this work, the dissociation constant (KD) was determined for a panel of peptides representing versions of the truncated NMDAR GluN2b-subunit C-terminal towards PDZ1 and 2 of PSD95.

Post synaptic density protein 95

PDZ-domains

N-methyl-D-aspartate receptor

NMDAR hypofunctional hypothesis

GluN2b

Differential scanning fluorimetry

Surface plasmon resonance

Fragment based drug design

Assay development

Medical Biotechnology

Medicinsk bioteknik

Novel Antipsychotic Drug Carriers: The Development of Nanoparticle and Microgel Drug Carriers for Antipsychotic Delivery in the Treatment of Schizophrenia

Piazza, Justin E.

10 1900

<p>Lectin-functionalized, Poly [oligo(ethylene glycol) methyl ether methacrylate] (<em>POEGMA</em>) loaded with 3(R)-[(2(S)-pyrrolidinylcarbonyl)amino]-2-oxo-1-pyrrolidineacetamide (PAOPA) and poly(ethylene glycol)–block-poly(D,L-lactic-co-glycolic acid) (PEG-PLGA) nanoparticles loaded with haloperidol were prepared with narrow size distributions and sizes < 135 nm. The microgels and nanoparticles exhibited high <em>Solanum tuberosum </em>lectin (STL) conjugation efficiencies, encapsulation efficiencies, and drug loading capacities. The <em>in vitro</em> release of PAOPA and haloperidol was slow in physiological conditions over 96 hours, demonstrating minimal drug leakage and the potential for efficient drug transport to the targeted brain tissue. POAPA, POEGMA and the STL-functionalized POEGMA microgels were found to be non-toxic in both cell lines, indicating that they would not be toxic when administered intranasally or when they reach the brain. The nasal epithelial cell uptake of rhodamine-labelled microgels was higher in cells when the STL-functionalization was present. All haloperidol-loaded nanoparticle formulations were found to be highly effective at inducing catalepsy, while intranasal administration of STL-functionalized nanoparticles using the intranasal spray device increased the brain tissue haloperidol concentrations by 2-3.5 fold compared to STL-functionalized particles administered intranasally with a pipette. For the first time, brain tissue concentrations of rhodamine-labelled microgels confirmed that microgels are capable of passing the blood-brain barrier and that this uptake is size dependent. These formulations demonstrate promise in the reduction of the drug dose necessary to produce a therapeutic effect with antipsychotic drugs for the treatment of schizophrenia using a non-invasive route of administration.</p> / Master of Science (MSc)

nanoparticle

microgel

antipsychotic

allosteric modulator

PAOPA

Amino Acids, Peptides, and Proteins

Biochemistry

Biomaterials

Cell Biology

Medicinal Chemistry and Pharmaceutics

Molecular and Cellular Neuroscience

Molecular Biology

Nanomedicine

Nervous System Diseases

Pharmaceutics and Drug Design

Polymer Science

Psychiatric and Mental Health

Toxicology

Amino Acids, Peptides, and Proteins

Synthesis and mechanism-of-action of a novel synthetic antibiotic based on a dendritic system with bow-tie topology

Revilla-Guarinos, Ainhoa, Popp, Philipp F., Dürr, Franziska, Lozano-Cruz, Tania, Hartig, Johanna, de la Mata, Francisco Javier, Gómez, Rafael, Mascher, Thorsten

21 May 2024

Over the course of the last decades, the continuous exposure of bacteria to antibiotics—at least in parts due to misprescription, misuse, and misdosing—has led to the widespread development of antimicrobial resistances. This development poses a threat to the available medication in losing their effectiveness in treating bacterial infections. On the drug development side, only minor advances have been made to bring forward novel therapeutics. In addition to increasing the efforts and approaches of tapping the natural sources of new antibiotics, synthetic approaches to developing novel antimicrobials are being pursued. In this study, BDTL049 was rationally designed using knowledge based on the properties of natural antibiotics. BDTL049 is a carbosilane dendritic system with bow-tie type topology, which has antimicrobial activity at concentrations comparable to clinically established natural antibiotics. In this report, we describe its mechanism of action on the Gram-positive model organism Bacillus subtilis. Exposure to BDTL049 resulted in a complex transcriptional response, which pointed toward disturbance of the cell envelope homeostasis accompanied by disruption of other central cellular processes of bacterial metabolism as the primary targets of BDTL049 treatment. By applying a combination of whole-cell biosensors, molecular staining, and voltage sensitive dyes, we demonstrate that the mode of action of BDTL049 comprises membrane depolarization concomitant with pore formation. As a result, this new molecule kills Gram-positive bacteria within minutes. Since BDTL049 attacks bacterial cells at different targets simultaneously, this might decrease the chances for the development of bacterial resistances, thereby making it a promising candidate for a future antimicrobial agent.

info:eu-repo/classification/ddc/570

ddc:570

Étude structure-fonction des fructose-1,6-bisphosphate aldolases métallo-dépendantes : mécanisme catalytique et développement d’antimicrobiens

Coinçon, Mathieu

09 1900

Les fructose-1,6-bisphosphate aldolases (FBPA) sont des enzymes glycolytiques (EC 4.1.2.13) qui catalysent la transformation réversible du fructose-1,6-bisphosphate (FBP) en deux trioses-phosphates, le glycéraldéhyde-3-phosphate (G3P) et le dihydroxyacétone phosphate (DHAP). Il existe deux classes de FBPA qui diffèrent au niveau de leur mécanisme catalytique. Les classes I passent par la formation d’un intermédiaire covalent de type iminium alors que les classes II, métallodépendantes, utilisent généralement un zinc catalytique. Contrairement au mécanisme des classes I qui a été très étudié, de nombreuses interrogations subsistent au sujet de celui des classes II. Nous avons donc entrepris une analyse détaillée de leur mécanisme réactionnel en nous basant principalement sur la résolution de structures cristallographiques. De nombreux complexes à haute résolution furent obtenus et ont permis de détailler le rôle de plusieurs résidus du site actif de l’enzyme. Nous avons ainsi corrigé l’identification du résidu responsable de l’abstraction du proton de l’O4 du FBP, une étape cruciale du mécanisme. Ce rôle, faussement attribué à l’Asp82 (chez Helicobacter pylori), est en fait rempli par l’His180, un des résidus coordonant le zinc. L’Asp82 n’en demeure pas moins essentiel car il oriente, active et stabilise les substrats. Enfin, notre étude met en évidence le caractère dynamique de notre enzyme dont la catalyse nécessite la relocalisation du zinc et de nombreux résidus. La dynamique de la protéine ne permet pas d’étudier tous les aspects du mécanisme uniquement par l’approche cristallographique. En particulier, le résidu effectuant le transfert stéréospécifique du proton pro(S) sur le carbone 3 (C3) du DHAP est situé sur une boucle qui n’est visible dans aucune de nos structures. Nous avons donc développé un protocole de dynamique moléculaire afin d’étudier sa dynamique. Validé par l’étude d’inhibiteurs de la classe I, l’application de notre protocole aux FBPA de classe II a confirmé l’identification du résidu responsable de cette abstraction chez Escherichia coli (Glu182) mais pointe vers un résidu diffèrent chez H. pylori (Glu149 au lieu de Glu142). Nos validations expérimentales confirment ces observations et seront consolidées dans le futur. Les FBPA de classe II sont absentes du protéome humain mais sont retrouvées chez de nombreux pathogènes, pouvant même s'y révéler essentielles. Elles apparaissent donc comme étant une cible idéale pour le développement de nouveaux agents anti-microbiens. L’obtention de nouveaux analogues des substrats pour ces enzymes a donc un double intérêt, obtenir de nouveaux outils d’étude du mécanisme mais aussi développer des molécules à visée pharmacologique. En collaboration avec un groupe de chimistes, nous avons optimisé le seul inhibiteur connu des FBPA de classe II. Les composés obtenus, à la fois plus spécifiques et plus puissants, permettent d’envisager une utilisation pharmacologique. En somme, c’est par l’utilisation de techniques complémentaires que de nouveaux détails moléculaires de la catalyse des FBPA de classe II ont pu être étudiés. Ces techniques permettront d’approfondir la compréhension fine du mécanisme catalytique de l’enzyme et offrent aussi de nouvelles perspectives thérapeutiques. / Fructose-1,6-bisphosphate aldolases (FBPA) are glycolytic enzymes (EC 4.1.2.13) that catalyze the reversible cleavage of fructose-1,6-bisphosphate (FBP) into the triose phosphates, glyceraldehyde-3-phosphate (G3P) and dihydroxyacetone phosphate (DHAP). There are two classes of FBPAs that differ at the level of their mechanism. Class I FBPAs form a covalent iminium intermediate whereas class II FBPAs, being metalloenzymes, generally use a catalytic zinc in their reaction mechanism. In contrast to the mechanism of the class I FBPAs, which has been thoroughly studied, there are several unresolved inquiries as to the mechanism of class II FBPAs. We have therefore pursued a detailed analysis of the reaction mechanism using as a primary tool the elucidation of crystallographic structures. Several high resolution complexes have been resolved and have provided critical evidence to help us suggest the implication and role of several key residues in the active site. Consequently, we have correctly identified the residue which is responsible for the abstraction of the O4 proton from FBP, a vital step in the reaction mechanism. The residue responsible for this abstraction, which had incorrectly been assigned to Asp82 (in Helicobacter pylori), has been appropriately consigned to His180, a residue which is involved in coordinating the zinc molecule. Nevertheless, Asp82 remains an important residue as it orients, activates and stabilizes substrates. Finally, our study brings to evidence the dynamic character of our enzyme in which catalysis entails the relocalization of the catalytic zinc and several residues. The complexity of this reaction, notably one of the proton exchanges in the mechanism, could not be resolved solely by crystallographic means. In fact, the residue responsible for the stereospecific transfer of the pro(S) proton on carbon 3 (C3) of DHAP is situated on a loop that was not resolved in any of our structures. We therefore developed a molecular dynamics approach to study this intricate movement. After preliminary validation by inhibitor studies with class I FBPAs, the protocol was applied to class II FBPAs and several remarkable observations emerged: the residue responsible for this abstraction in Escherichia coli is Glu182 whereas a different residue, Glu149 (instead of Glu142) appears to assume this role in H. pylori. Our preliminary validations have confirmed this observation and shall be further consolidated in the future. Class II FBP aldolases, although absent from the human proteome, are prevalently found in several pathogens, and have further been found to be essential to a number of these organisms. As such, they are ideal targets for the development of novel anti-microbial agents. Developing new analogues of the cognate substrates of these enzymes is therefore not only advantageous for mechanistic studies, but has endless pharmacological potential. In the context of a collaborative effort involving a group of chemists, a compound that initially had an inhibition constant in the millimolar range was optimized and produced a series of compounds that inhibit in the nanomolar range.

aldolase glycolitique

glycolitic aldolase

mécanisme catalytique

catalytic mechanism

clivage du substrat

substrate cleavage

condensation aldolique

aldol condensation

transfert de proton stéréospécifique

stereospecific proton transfer

drug-design

radiocristallographie

crystallography

macromolecular X-ray diffraction

Dynamique moléculaire

molecular dynamic