Targeting HIV-1 RNAs with Medium Sized Branched Peptides Featuring Boron and Acridine-Branched Peptide Library Design, Synthesis, High-Throughput Screening and Validation

Zhang, Wenyu

14 April 2014

RNAs have gained significant attention in recent years because they can fold into well-defined secondary or tertiary structures. These three dimensional architectures provide interfaces for specific RNA-RNA or RNA-protein interactions that are essential for biological processes in a living system. These discoveries greatly increased interest in RNA as a potential drug target for the treatment of diseases. Two of the most studied RNA based regulatory systems are HIV-1 trans-activating response element (TAR)/Tat replication pathway and Rev response element (RRE)/Rev export pathway. To efficiently target TAR and RRE RNA, we designed and synthesized three generations of branched peptide libraries that resulted in medium sized molecules. The first generation of BPs were discovered from screening a one-bead one-compound library (4,096 compounds) against HIV-1 TAR RNA. One peptide FL4 displayed a binding affinity of 600 nM to TAR RNA, which is tighter than its native protein counterpart, Tat. Biophysical characterization of these BP demonstrated that "branches" in BPs impart multivalency, and they are cell permeable and non-toxic. The second generation peptides were discovered from an on-bead high-throughput screening of a 3.3.4 branched peptide boronic acids (BPBAs) library that bind selectively to the tertiary structure of RRE IIB. The library comprised of 46,656 unique sequences. We demonstrate that our highest affinity BPBA (BPBA1) selectively binds RRE IIB in the presence of competitor tRNAs as well as against six RRE IIB structural variants. Further, we show that the boronic acid moieties afford a novel binding mode towards RNA that is tunable; their Lewis acidity has critical effects on binding affinity. In addition, biophysical characterizations provide evidence that "branching" in these peptides is a key structural motif for multivalent interactions with the target RNA. Finally, RNA footprinting studies revealed that the BPBA1 binding site encompasses a large surface area that spans both the upper stem as well as the internal loop regions of RRE IIB. BPBA1 is cell permeable and non-toxic. In the next generation of branched peptides, a 3.3.4 branched peptide library composed of 4,096 unique sequences that featured boronic acid and acridine moieties was designed. We chose acridine as the amino acid side chain due to its potential for π-stacking interaction that provides high binding affinity to RNA target. The library was screened against HIV-1 RRE IIB RNA. Fifteen peptides were sequenced and four contained acridine alone and/or in conjunction with boronic acid moieties displayed dissociation constants lower than 100 nM. The ribonuclease protection assays of A7, a sequence that contains both boronic acid and acridine residues, showed a similar protection pattern compared to previous peptide BPBA1, suggesting that the 3.3.4 branched peptides shared similar structural elements and contacted comparable regions of the RRE IIB RNA. The results from this research indicated that "branching" in peptides imparts multivalent interactions to the RNA, and that functional groups such as boronic acid and acridine are key structural features for efficient binding and selectivity for the folded RNA target. We demonstrated that the branched peptides are cell permeable and non-toxic. / Ph. D.

HIV-1

TAR RNA

RRE RNA

Branched Peptide Library

High-throughput Screening

Branched Peptide Boronic Acids

Acridine Branched Peptides

Unnatural Amino Acids

Spektroskopische Charakterisierung der grün-absorbierenden Kanalrhodopsin-Chimäre ReaChR

Krause, Benjamin Sören

06 September 2018

Kanalrhodopsine (ChRs) sind lichtgesteuerte Ionenkanäle, welche nach Absorption eines Photons durch den Retinal-Cofaktor einen passiven Ionentransport über die Zellmembran katalysieren. Im Zuge von optogenetischen Anwendungen wird diese Reaktion für die Beeinflussung der Ionenhomöostase von verschiedenen Zelltypen und Geweben ausgenutzt. Zu Beginn dieser Arbeit wurden lichtinduzierte Strukturänderungen und Protontransferschritte in einem breiten Zeitbereich (Nanosekunden bis Minuten) in dem grün-absorbierenden ChR ReaChR mithilfe von stationärer und transienter UV-vis- und Fourier-Transform-Infrarot-Spektroskopie (FTIR) untersucht. Auf Basis der experimentellen Daten wurde ein komplexes Photozyklus-Modell konzipiert. Anschließend wurde die IR-aktive, nichtkanonische Aminosäure p-Azido-L-phenylalanin (azF) mittels Stopp-Codon-Suppression ortsspezifisch an mehreren Positionen innerhalb der vermuteten ionenleitenden Kanalpore in ReaChR inkorporiert und mit FTIR untersucht. azF ist sensitiv gegenüber Polaritätsänderungen und absorbiert in einem hochfrequenten Bereich (~2100 cm-1). Aufgrund der großen spektralen Separation zu endogenen Proteinschwingungen (< 1800 cm-1) können globale Konformations- und lokale Hydratisierungsänderungen simultan detektiert werden. Die erhobenen Daten leisten einen wichtigen Beitrag zum Verständnis der Bildung einer temporären Wasserpore in ChRs und demonstrieren zum ersten Mal den erfolgreichen in-vivo-Einbau einer artifiziellen Aminosäure in mikrobielle Rhodopsine und dessen schwingungsspektroskopische Analyse. Die Methode bietet aufgrund ihrer hohen Ortsauflösung ein großes Potential für die Studie von Mikroumgebungen innerhalb komplexer Proteinensemble. / Channelrhodopsins (ChRs) are light-gated ion channels. Upon absorption of a photon, the retinal chromophore isomerizes and drives conformational changes within the protein, which lead to a passive ion transport across the cell membrane. This capability is used for optogenetic applications to manipulate ionic homeostasis of different cell types and entire organisms. Within the work, light-induced structural changes and proton transfer steps were studied in the green-absorbing ChR ReaChR in great detail by steady-state and transient UV-vis and Fourier transform infrared spectroscopy (FTIR). The data were merged into a complex photocycle model. Next, the IR-active, unnatural amino acid p-azido-L-phenylalanine (azF) was site-specifically introduced at several sites of the putative ion pore of ReaChR by stop codon suppression. azF is sensitive to polarity changes and absorbs in a clear spectral window lacking endogenous protein vibrations. Thus, FTIR measurements of labeled mutants report for global conformational changes (< 1800 cm-1) and local hydration changes (~2100 cm-1) simultaneously. The presented findings reveal crucial insights regarding formation of a transient water pore in ChRs and demonstrate the first report of the successful in-vivo incorporation of an artificial amino acid into a microbial rhodopsin and its subsequent spectroscopic investigation. Additionally, the so far unprecedented spatial resolution renders this methodology superior over conventional FTIR methods to study microenvironments within complex protein ensembles.

Kanalrhodopsin

Photozyklus

Protontransferreaktionen

UV-vis-Spektroskopie

FTIR

Unnatürliche Aminosäuren

Stopp-Codon-Suppression

channelrhodopsin

photocycle

proton transfer reactions

UV-vis spectroscopy

FTIR

unnatural amino acids

stop codon suppression

570 Biowissenschaften; Biologie

WD 2800

WD 2200

WE 5460

WF 9746

ddc:570

Streamlined Extract Preparation for E. coli-Based Cell-Free Protein Synthesis and Rapid Site-Specific Incorporation of Unnatural Amino Acids in Proteins

Shrestha, Prashanta

07 December 2012

This thesis reports the viability of E. coli cell extracts prepared using equipment that is both common to biotechnology laboratories and able to process small volume samples and expression of proteins containing unnatural amino acids (UAAs) at higher level using PCR amplified linear DNA templates (LETs) in cell-free protein synthesis (CFPS) system. E. coli-based cell extracts are a vital component of inexpensive and high-yielding CFPS reactions. However, effective preparation of E. coli cell extract is limited to high-pressure homogenizers (French press style or impinge-style) or bead mill homogenizers, which all require a significant capital investment. This work specifically assessed the following capital cost lysis techniques: (1) sonication, (2) bead vortex mixing, (3) freeze-thaw cycling, and (4) lysozyme incubation to prepare E. coli cell extract for CFPS. In this work, simple shake flask fermentation with a commercially available E. coli strain was used. Additionally, the RNA polymerase was over expressed in the E. coli cells prior to lysis which eliminated the need to add independently purified RNA polymerase to the CFPS reaction. As a result, high yielding E. coli-based cell extract was prepared using equipment requiring reduced capital investment and common to biotechnology laboratories. To our knowledge, this is the first successful prokaryote-based CFPS reaction to be carried out with extract prepared by sonication or bead vortex mixing. LETs are an attractive alternative to plasmids for site-specific incorporation of unnatural amino acids in proteins in the CFPS system because of their short preparation time and ease of production. However, major limitations associated with LETs are: (1) their degradation by RecBCD enzyme present in the cell-extract used for CFPS and (2) high CFPS energy costs. In this work, we report the optimization of LET-based CFPS for improved protein yield by inhibiting the RecBCD enzyme with small inhibitor molecules resulting in three fold increment in yield of protein containing UAA. We also assessed alternative energy sources such as glucose, fructose-1,6-bisphospate, creatine phosphate/creatine kinase, and high glutamate salt for cost reduction. This work could be important for high-throughput applications based on linear expression templates. This work demonstrates simple E. coli extract preparation and improved yield with linear expression templates for further advancements of cell-free protein synthesis system.

Prashanta Shrestha

cell-free protein synthesis

in vitro protein synthesis

unnatural amino acids

para-proparglyoxyphenylalanine (pPa)

cell lysis

cell extract

bead milling

sonication

RecBCD

exonucleases

small molecules

linear expression templates

linear DNA

PCR

transcription

translation

Chemical Engineering

Synthesis of unusual alpha-amino acids and study of the effect of their incorporation into antimicrobial peptides. Total synthesis of biactive marine natural products and analogues thereof

El Marrouni El Ghazaoui, Abdellatif

13 April 2012

The principle theme of this thesis was the synthesis of bioactive compounds. To this end, this work was focus on two main projects. The first one, which was carried out in the Department of Chemistry of the University of Girona under the supervision of Dr Montserrat Heras, concerned the synthesis of new unnatural amino acids bearing a pyrimidine ring within their side chain for incorporation into the antimicrobial peptide BP100 following a rational design in order to improve its biological profile. On the other hand, the second chapter of this thesis was developed in collaboration with the Laboratoire de Chimie Organique (ESPCI-ParisTech, Paris, France) under the guidance of Pr Janine Cossy and Dr Arseniyadis. This chapter was centered on the total synthesis of three marine natural products with complex structures and interesting biological activities: acremolide B, (–) bitungolide F and lyngbouilloside. / Aquesta tesi s'ha centrat en la preparació de nous compostos bioactius seguint dues estratègies diferents. El primer projecte es va portar a terme sota la supervisió de la Dra. Montserrat Heras del grup LIPPSO del Departament de Química i ha permés el desenvolupament de noves metodologies per la síntesi de nous aminoàcids no naturals. i el seu ús en la preparació d'anàlegs del pèptid antimicrobià BP100 amb l'objectiu de millorar-ne les propietats biològiques. El segon projecte és fruit de la col•laboració amb la Prof. Janine Cossy i el Dr. Stellios Arseniyadis del "Laboratoire de Chimie Organique" de l'Ecole Superieur de Physique et Chimie Industrielles (ESPCI-ParisTech, Paris, França). I ha permés posar a punt tres estratègies sintètiques convergents i versàtils per l’obtenció de tres productes naturals de gran complexitat estructural i interessants activitats biològiques – l'acremolide B, la bitungolide F i la lyngbouilloside – aïllats recentment del fons marí de diferents punts del món.

Pèptids antimicrobials

Péptidos antimicrobianos

Antimicrobial peptides

Compostos bioactius

Compuestos bioactivos

Bioactive compounds

Marine natural products

Unnatural amino acids

Aminoàcids no naturals

Aminoácidos no naturales

Productes naturals marins

Productos naturales marinos

547

STRATEGIC MODIFICATIONS TO OPTIMIZE A CELL PENETRATING ANTIMICROBIAL PEPTIDE

Reena Blade (7289858)

31 January 2022

<p>Pathogenic bacteria are evolving to drug resistant strains at alarming rates. The threat posed by drug resistant bacterial infections emphasize the need to establish new antimicrobial agents. Of immediate concern regarding the dangers of antibiotic resistance is the existence of intracellular bacteria, which find refuge from bactericidal devices by hiding within mammalian cells. Unfortunately, many therapeutics, such as vancomycin, do not possess membrane penetrating abilities to achieve efficacious eradication of bacteria at the subcellular level, allowing infections to persist. In an effort to target pathogens that thrive within mammalian cells, features of cell penetrating peptides (CPPs) and antimicrobial peptides (AMPs) were combined to develop a dual action antimicrobial CPP, cationic amphiphilic polyproline helices (CAPHs). CAPHs have proven to be an effective antimicrobial agent to combat an array of both Gram negative and Gram positive bacteria. </p> <p> </p> <p>Herein, to improve CAPHs activity, we have demonstrated how the incorporation of strategic modifications has resulted in increased cell uptake, alternative subcellular locations for CAPHs, and advanced antimicrobial potency. By simultaneously extending the helical length of CAPHs while incorporating different hydrophobic groups in place of the original isobutyl moiety that compose CAPHs we have created a <b>FL-P17-5R </b>series of peptides with five carbon aliphatic motifs: <b>Fl-P17-5B</b>, <b>Fl-P17-5C</b> and <b>Fl-P17-5L. </b>Through these modifications the peptides proved to be 2 to 5-fold more efficient in accumulating in macrophage cells than parent peptide Fl-P14LRR and where able to clear intracellular pathogenic bacteria, such as <i>Listeria</i>, from infected macrophages by 26 to 54%. </p> <p> </p> <p>In addition to making the <b>Fl-P17-5R</b> series of CAPHs to potentiate CAPHs activity, modifications to the cationic moiety of CAPHs were explored. By incorporating a new cationic monomer into the CAPHs sequence, a guanylated amino proline (GAP) residue, we produced <b>Fl-P14GAP</b>, a CAPHs peptide with an organized cationic charge display. This modification resulted in a 5-fold increase in cell uptake and a 2 to 16-fold decrease in minimum inhibitory concentration (MIC) values against strains of enteric and ESKAPE pathogens in comparison to Fl-P14LRR. <b>Fl-P14GAP</b> also executed superior clearance of intracellular pathogenic bacteria that resulted in the complete eradication of a drug resistant strain of <i>A. baumannii</i> from infected macrophage cells. Overall, our efforts with the <b>Fl-P17-5R</b> series of CAPHs and <b>Fl-P14GAP</b> have strengthened the therapeutic potential of CAPHs in the hopes of addressing the need for novel antibiotics with the propensity to eradicate intracellular pathogens.</p>

Organic Chemistry

Proteins and Peptides

Peptides

Cell penetrating peptides

antimicrobial peptides

AMPs

CPPs

antibacterial

antimicrobial

unnatural amino acids

peptide synthesis

solid phase peptide synthesis

biofilm

antibiofilm

rigid cationic motif

amphiphilic peptide

amphiphatic peptide

Arginine rich peptide

Mechanism of N-Type Inactivation in Shaker Potassium Channels

Pandey, Roshan

08 1900

Hyperexcitabilité est l'un des changements les plus importants observés dans de nombreuses maladies neuro-dégénératives telles que la sclérose latérale amyotrophique (SLA) et la maladie d'Alzheimer. De nombreuses recherches études se sont concentrées sur la réduction de l'hyperexcitabilité, soit en inactivant les canaux sodiques ce qui va réduire la génération de potentiels d'action, soit en prolongeant l'ouverture des canaux potassiques ce qui va qui ramener la membrane à son état de repos et réduire l’activité des neurones. Ainsi, pour cibler l'hyperexcitabilité, il faut tout d’abord comprendre les différents aspects de la fonction des canaux ioniques au niveau. Les objectifs des travaux présentés dans cette thèse consistent à déterminer le mécanisme d'inactivation dans les canaux potassiques Shaker. Les canaux Shaker Kv s'inactivent rapidement pour culminer le potentiel d'action et maintenir l'homéostasie des cellules excitables. L'inactivation de type N est causée par les 46 premiers acides aminés situés de l'extrémité N-terminale du canal, encore appelé, peptide d'inactivation (IP). De nombreuses études mutationnelles ont caractérisé l'inactivation de type N au niveau fonctionnel, cependant, la position de l'IP à l'état de repos et leur transition lors de l'inactivation est encore débattue. L'objectif de la première étude consiste à évaluer le mouvement des IP pendant leur inactivation à l'aide de la fluorométrie en voltage imposé. En insérant un acide aminé non naturel, la 3-[(6-acétyl-2-naphtalényl) amino]-L-alanine (Anap), qui est sensible aux changements d'environnement, nous avons identifié séparément les mouvements de la boule et de la chaîne. Nos données suggèrent que l'inactivation de type N se produit dans un mouvement biphasique en libérant d'abord le IP, ce qui va bloquer le pore du côté cytoplasmique. Pour affiner davantage la position de repos des IP, nous avons utilisé le transfert d'énergie de résonance à base de lanthanide et le métal de transition FRET. Nous proposons que le IP se situe dans la fenêtre formée par le canal et le domaine T1, interagissant avec les résidus acides-aminés du domaine T1. Dans notre deuxième étude, nous avons montré que le ralentissement de l'inactivation de type N observé dans la première étude est causée par une expression élevée des canaux Shaker. En effet, l'extrémité C-terminale du canal interagit avec les protéines d'échafaudage associées à la membrane pour la formation d'amas. Nous avons aussi montré qu'en tronquant les quatre derniers résidus C-terminaux impliqués dans la formation des amas, nous empêchons également le ralentissement de la cinétique d'inactivation dans les canaux Shaker. Nous avons également démontré que l'inactivation lente de type N n'est pas affectée par l'accumulation des cations potassiques [K+] externe ou toute diaphonie entre les sous-unités voisines. Cette étude élucide non seulement la cause du ralentissement de l'inactivation, mais montre également que les canaux modifient leur comportement en fonction des conditions d'expression. Les résultats trouvés au niveau moléculaire ne peuvent donc pas toujours être extrapolés au niveau cellulaire. / Hyperexcitability of neurons is a major symptom observed in many degenerative diseases such as ALS and Alzheimer’s disease. A lot of research is focused on reducing hyperexcitability, either by inactivating sodium channels that will reduce the generation of action potentials, or by prolonging the opening of potassium channels which will help to bring the membrane back to resting state and thus, reduce firing frequency of neurons. At the molecular level, it is important to understand different aspects of ion channel function to target hyperexcitability. The aim of this thesis was to investigate in two projects the inactivation mechanism in Shaker potassium channels. Shaker Kv channels inactivate rapidly to culminate the action potential and maintain the homeostasis of excitable cells. The so-called N-type inactivation is caused by the first 46 amino acids of the N-terminus of the channel, known as the inactivation peptide (IP). Numerous mutational studies have characterized N-type inactivation functionally, however, the position of the IP in the resting state and its transition during inactivation is still debated. The aim of the first project was to track the movement of IP during inactivation using voltage clamp fluorometry. By inserting an unnatural amino acid, 3-[(6-acetyl-2-naphthalenyl) amino]-L-alanine (Anap), which is sensitive to changes in environment, we identified the movements of ball and chain separately. Our data suggests that N-type inactivation occurs in a biphasic movement by first releasing the IP, which then blocks the pore from the cytoplasmic side. To further narrow down the resting position of the inactivation peptide, we used Lanthanide-based Resonance Energy transfer and transition metal FRET. We propose that the inactivation peptide is located in the window formed by the channel and the T1 domain, interacting with the acidic residues of the T1 domain. In a follow-up study, we explored the reason underlying slow inactivation kinetics observed during the study of N-type inactivation in the first project. High expression of Shaker channels results in slowing of the N-type inactivation. The C-terminus of the channel interacts with membrane associated scaffold proteins for cluster formation. In this study, we have shown that by truncating the last four C-terminal residues involved in cluster formation, and hence preventing channel clustering, we also prevent slowing of the inactivation kinetics in Shaker channels. We also showed that slow N-type inactivation is not affected by accumulation of external [K+] or any crosstalk between the neighboring subunits. The second project not only elucidates the cause of the inactivation slow-down but illustrates that the channels alter their behavior dependent on the expression conditions. Results found on the molecular level can thus not always be extrapolated to the cellular level.

Canaux Kv

acides aminés non-naturels

Anap

fluorimétrie en voltage impose

tmFRET

LRET

Kv channels

Unnatural amino acids

Voltage clamp fluorometry

Lanthanide resonance energy transfer