Designed β-Hairpin, β-Sheet And Mixed α-β Structures In Synthetic Peptides

Das, Chittaranjan

10 1900

Synthetic construction of protein molecules has been widely pursued over the last two decades. A primary goal behind de novo protein design has been to build minimal systems by capturing the essential features of protein structures. Such minimal models can be used to understand underlying principles governing folding, structure, and function of proteins molecules. Several approaches envisioning successful construction of synthetic proteins have been described over the years, some of them being admirably successful (DeGrado et al, 1999; Richardson et al> 1992; Baltzer, 1998). Specific patterning of polar and apolar residues in synthetic sequences has been widely used to achieve designed polypeptide structures like helix bundles (DeGrado et ah, 1999) and (3-sheets (Smith and Regan, 1997; Lacroix et a/., 1998), with reliance on hydrophobic driving forces for folding. Our laboratory has been pursuing a distinctly alternative approach, that employs stereochemically constrained amino acids to generate specific secondary structures which can then be assembled into composite structures by appropriately chosen linking segments. This approach, which involves linking prefabricated modules of secondary structures can be termed as a "Meccano set" approach to protein design (Balaram, 1992). The studies embodied in the present thesis describe attempts at construction of synthetic polypeptide motifs using the stereochemically directing influence of conformationally constrained amino acid residues, such as DPro or Aib (α-aminoisobutyric acid). This thesis is subdivided into 8 chapters, with Chapter 1 providing a perspective of the field of protein design. Subsequent chapters (2-8) describe studies directed towards the specific goal of construction of polypeptide motifs. Chapter 2 describes synthesis and conformational characterization of two octapeptides Boc-Leu-Val-Val-DPro-LAla-Leu-Val-Val-OMe (1) and Boc-Leu-Val-Val-DPro-DAla-Leu-Val-Val-OMe (2), designed to investigate the effect of specific β-turn stereochemistry on β-hairpin structures. 500 MHz NMR studies establish that both peptides 1 and 2 adopt predominantly β-hairpin conformations in chloroform and methanol solutions, with interstrand registry established by observation of long-range nuclear Overhauser effects (NOEs). Specific NOEs provide evidence for a type II' β-turn conformation for the DPro-LAla segment in 1, while the NMR data suggest that a type I' DPro-DAla β-turn conformation predominates in the peptide 2. The crystal structure of 1 reveals two independent molecules in the crystallographic asymmetric unit, both of which adopt β-hairpin conformations nucleated by a type II’ β-turn across DPro-LAla and stabilized by 3 cross strand hydrogen bonds. These designed β-hairpins with defined tight turns produce characteristic vibrational circular dichroism (VCD) patterns, demonstrating the utility of VCD as a probe for conformational analysis of β-hairpins. In Chapter 3, we present conformational analysis on designed β-hairpin sequences incorporating a 'Phe-Phe' residue pair at a non-hydrogen bonding position. Two octapeptides Boc-Leu-Phe-Val-DPro-Gly-Leu-Phe-Val-OMe and Boc-Leu-Phe-Val-DPro-Ala-Leu-Phe-Val-OMe were synthesized and conformationally characterized by 500 MHz NMR spectroscopy. Specific NOEs observed in solution provide conclusive evidence favoring specific orientation effects pertaining to the 'Phe-Phe' pair. The peptides exhibited anomalous electronic CD, which has been explained in terms of aromatic contributions by the side chain chromophores. Interestingly, the VCD patterns obtained for these peptides were almost identical to those obtained for other β-hairpins, described in Chapter 2. Chapter 4 describes the synthesis and conformational analysis of designed decapeptide sequences with centrally located DPro-Xxx β-trun segments. Two sequences Boc-Met-Leu»Phe-Val'DPro-Ala-Leu-Val-Val-Phe-OMe (1) and Boc-Met-Leu-Val-Val-^ro-Gly-Leu-Val-Val-Phe-OMe (2) were designed to study the effect of chain length elongation, of β-strands, on designed β-hairpin structures. 500 MHz NMR studies establish β-hairpin folds in both these sequences, with strand segments aligned even at the termini of the structures. Multi-stranded, antiparallel β-sheet structures can be generated by successive placement of β-hairpin sequences in a single polypeptide chain. The successful construction of three stranded β-sheet structures is described in Chapter 5 of this dissertation. A 14-residue peptide Boc-Leu-Phe-Val-DPro-Gly-Leu-Val-Leu-Ala-DPro-Gly-Phe-Val-Leu-OMe (LFV14) was designed such that it is composed of three strand segments linked by two DPro-Gly turn segments. The peptide showed excellent solubility in apolar media, permitting detailed conformational analysis by 500 MHz NMR spectroscopy in organic solvents. Observation of long-range, interstrand NOEs, diagnostic of multiple hairpin structures, provides conclusive evidence for a predominantly populated three stranded β-sheet structure in solution. Extension of this strategy has been described in which an 18-residue peptide, Arg-Gly-Thr-Ile-Lys-DPro-Gly-Val-Thr-Phe-Ala-DPro-Ala-Thr-Lys-Tyr-Gly-Arg, was designed with enhanced solutility in water to probe (β-sheet structure formation in aqueous and mixed aqueous-methanol systems. NMR data provided conclusive evidence in favor of the desired structure being significantly populated in methanol and methanol-water mixtures (50 %, v/v). In water, spectroscopic evidence suggests that the long-range order expected of a three-stranded structure is lost, possibly due to water invading the interstrand hydrogen bonds. Successful construction of a four-stranded antiparallel β-sheet structure has been demonstrated in Chapter 6. A 26-residue peptide Arg-Gly-Thr-Ile-Lys»DPro-Gly-Ile-Thr- Phe-Ala-DPro-Ala-Thr-Val-Leu-Phe-Ala-Val-DPro-Gly-Lys-Thr-Leu-Tyr-Arg was designed to have four strand segments linked by three DPro-Xxx turn segments. The peptide exhibited excellent NMR properties permitting structure determination by analysis of NOE data, which revealed that a four stranded β-sheet structure is indeed populated in methanol. Structural studies on this peptide in mixed methanol-water established that the four stranded β-sheet is appreciably populated at a composition of 50 % (v/v) methanol-water mixture, with the β-sheet structure still detectable even at a composition of 70 % water-30 % methanol. In a completely aqueous environment, the β-sheet structures is significantly disrupted, presumably due to solvent invasion. The nucleating β-turns, however, appear to have retained their structural integrity even in this competitive environment. Chapter 7 describes the insertion of L-Lactic acid (Lac), a hydroxy acid, into polypeptide helices stabilized by a-aminoisobutyricacid (Aib). This study was undertaken to investigate the effect of hydrogen bond deletion on peptide helices. Crystal structure determination of three oligopeptides containing Lac residues has been performed. Peptide 1, Boc-Val-Ala-Leu-Aib-Val-Lac-Leu-Aib-Val-Ala-Leu-OMe, and peptide 2, Boc-Val-Ala-Leu-Aib-Val-Lac-Leu-Aib-Val-Leu-OMe adopt completely helical conformations in the crystalline state, with the Lac(6) residue comfortably accommodated in the center of a helix. NMR studies of peptide 1 and its all amide analog 4, Boc-Val-Ala-Leu-Aib-Val-Ala-Leu-Aib-Val-Ala-Leu-OMe, provide firm evidence for a continuous helical segment in both the cases. In a 14-residue peptide 3, Boc-Val-Ala-Leu-Aib- Val- Ala-Leu- Val- Ala-Leu- Aib-Val-Lac-Leu-OMe, residues Val( 1 )-Leu( 10) adopt a helical conformation, which is terminated by formation of a Schellman motif, with Aib(ll) as the site of chiral reversal. The loss of the hydrogen bond at the C-terminus appears to facilitate the chiral reversal at Aib(l 1). In the final section of this thesis, Chapter 8, successful construction of a synthetic motif containing two distinct elements of secondary structure, a (β-hairpin and a helix, has been described. The design of a 17-residue peptide Boc-Val-Ala-Leu-Aib-Val-Ala-Leu-Gly-Gly-Leu-Phe-Val-DPro-Gly-Leu-Phe-Val-OMe, BH17, is based on a modular approach, in which previously characterized β-hairpin (Leu-Phe-Val-DPro-Gly-Leu-Phe-Val) and helix (Val-Ala-Leu-Aib-Val-Ala-Leu) modules are linked by a Gly-Gly linker. The positioning of the achiral Gly residue at position 8 facilitates termination of the potential helical segment (residues 1-7) by formation of a Schellman motif. Gly(9) is anticipated to be the sole conformationally flexible residue. NMR studies on BH17 indicated the presence of both the helix (residues 1-7) and the β-hairpin (residues 10-17) structures in the sequence, with four major conformational possibilities at the linking segment. Crystal structure determination of BH17 revealed that the two elements of structure are approximately arranged in an orthogonal fashion. The crystal structure validates the original premise that a modular assembly strategy may be viable for the construction of larger synthetic structures. Chapter 9 summarises the major results of this thesis. (For formulae, please refer "pdf" format)

Biochemistry

β-Sheet

β-Hairpins

Synthetic Polypeptide

Synthetic Peptide

Protein Design

Beta Hairpins

Beta Sheet

Designed Peptides

Ramachandran Map

Peptide Helices

de novo Protein Design

Polypeptide Motifs

NMR Spectroscopy

Circular Dichroism

Electrostaticanalisys the Ras active site

Khan, Abdul Kareem

05 March 2009

La preorganització electrostàtica del centre actiu s'ha postulat com el mecanisme genèric de l'acció dels enzims. Així, alguns residus "estratègics" es disposarien per catalitzar reaccions interaccionant en una forma més forta amb l'estat de transició, baixant d'aquesta manera el valor de l'energia dactivació g cat. S'ha proposat que aquesta preorientació electrostática s'hauria de poder mostrar analitzant l'estabilitat electrostàtica de residus individuals en el centre actiu.Ras es una proteïna essencial de senyalització i actúa com un interruptor cel.lular. Les característiques estructurals de Ras en el seu estat actiu (ON) són diferents de les que té a l'estat inactiu (OFF). En aquesta tesi es duu a terme una anàlisi exhaustiva de l'estabilitat dels residus del centre actiu deRas en l'estat actiu i inactiu. / The electrostatic preorganization of the active site has been put forward as the general framework of action of enzymes. Thus, enzymes would position "strategic" residues in such a way to be prepared to catalyze reactions byinteracting in a stronger way with the transition state, in this way decreasing the activation energy g cat for the catalytic process. It has been proposed thatsuch electrostatic preorientation should be shown by analyzing the electrostatic stability of individual residues in the active site.Ras protein is an essential signaling molecule and functions as a switch in thecell. The structural features of the Ras protein in its active state (ON state) are different than those in its inactive state (OFF state). In this thesis, an exhaustive analysis of the stability of residues in the active and inactive Ras active site is performed.

dinàmica

centre actiu

relacions d'estructura activitat

preorganització

reorganització

estat de transició

estat actiu

estabilitat electrostàtica

interacción proteïna-proteïna

test de ranks de Wilcoxon

P-loop

G1 motif

HVR

metastability

RMSD

substrate assisted catalysis

sequence alignment

beta sheet

helix

Z-test

wilcoxon rank test

protein-protein interactions

electrostatic stability

active state

dynamics

signal transduction

electrostatic stabilization

ras effectors

guanine exchange factor

GTPase-activating proteins

quantum mechanics/molecular

PDLD/S-LRA

X-ray crystallography

solvation energy

free energy perturbation

statistical analysis

GTP hydrolysis

guanosine diphosphate

guanosine triphosphate

computer simulation

thermodynamics

protein conformation

electrostatics

interruptor II

interruptor I

llaç P

motiu G1

HVR (regions altament variables)

metaestabilita

RMSD

catàlisi assistida pel substrat

aliniament de seqüència

fulla beta

hèlix

test Z

transducció del senyal

estabilització electrostàtica

efectors de ras

factor de bescamvi de guanina

proteïnes activadores de l'activitat

mecànica quàntica/mecànica

PDLD/S-LRA

cristalografia de raigs X

energia de solvatació

perturbació de l'energia lliure

anàlisi estadística

hidròlisi de GTP

difosfat de guanosina

trifosfat de guanosina

simulació computacional

termodinàmica

conformació proteïca

electrostàtica

switch-I

switch-II

537

576

Modellierung und Visualisierung von Systemen zur Beschreibung der intra- und intermolekularen Wechselwirkungen in hydrophoben Peptiden

Schneider, Alexander

11 November 2014

Die vorliegende Arbeit beschäftigt sich mit der Untersuchung und Beschreibung der Eigenschaften der synthetischen Dekapeptide Cetrorelix und Ozarelix durch analytische Methoden und computergestützte Modellierung. Diese Moleküle sind hydrophobe, aggregierende Antagonisten des Gonadotropin-Releasing-Hormons (GnRH). Zusätzlich wurden amyloidbildende Peptidstrukturen als Modelle für die Assoziationsprozesse in hydrophoben Peptiden untersucht und visualisiert. Die intrinsische Fluoreszenz der GnRH-Antagonisten und zusätzlich der Peptide Teverelix und D-Phe6-GnRH sowie von verkürzten Fragmenten des Cetrorelix wurde untersucht. Ein Strukturmodell für die Beschreibung der Aggregation der Dekapeptide wurde erarbeitet. Der Aufbau eines Rechenclusters durch das Einbinden der Computer am Lehrstuhl in ein Linux-System zur Verteilung von Rechenprozessen über das Netzwerk ermöglichte die Bereitstellung der notwendigen Leistung zur Realisierung der Berechnungen. Es wurden Werkzeuge zur Modellierung der solvatisierten Aggregate von Peptiden ohne eindeutige Vorzugsstruktur programmiert und in ein Docking-System für beliebige Moleküle eingebunden. Verwendet wurde das Kraftfeld MMFF94 mit einer Erweiterung durch ein Verfahren zur dynamischen Berechnung von Partialladungen in Molekülstrukturen. Solvatisierte Aggregate der Dekapeptide und von bekannten amyloidbildenden Strukturen wurden modelliert (Docking). Berechnet wurden als aggregierend beschriebene Sequenzen und entsprechende Vergleichsstrukturen des Calcitonins, des Insel-Amyloid-Polypeptides, des beta2-Mikroglobulins, des Amyloid-beta-Proteins, des Lactoferrins und weitere Modellpeptide. Die wesentlichen Wechselwirkungen während der Aggregation konnten schließlich anhand von Dynamik-Simulationen der faltblattartigen Dimere des Cetrorelix und Ozarelix beschrieben werden. So wurden die Prozesse der hydrophoben Assoziation und Stabilisierung durch Wasserstoffbrücken von Peptiden veranschaulicht und auf molekularer Ebene erfolgreich analysiert. Die Visualisierung der erhaltenen Modellierungsergebnisse erfolgt durch die Darstellung der Strukturen und Dynamik-Simulationen als interaktive 3D-Modelle in einem für diese Arbeit aufgebauten Internetauftritt. / This work discusses the analysis of the aggregation properties of the gonadotropin releasing hormone antagonists Cetrorelix, Teverelix, Ozarelix and of small amyloid forming model peptides by analytical fluorescence spectroscopy and molecular modelling. A high performance linux compute cluster was developed for calculation of molecular structures. Solvated aggregate clusters of peptides without defined secondary structure were modelled by molecular mechanics methods (forcefield mmff94) in combination with an advanced charge equilibration and docking technique. Molecular dynamics of solvated peptide dimers were implemented and the role of hydrophic association and hydrogen bond formation in hydrophobic peptide aggregates was explained. Finally, an aggregation model for the directed association of hydrophobic peptides is presented. The modelling results, 3d structures and dynamic simulations are visualized in an interactive web material.

Aggregation

GnRH-Antagonist

Peptidaggregation

Gonadotropin-Releasinghormon-Analoga

Cetrorelix

Ozarelix

Teverelix

Fluoreszenzspektroskopie

LINUX-Rechencluster

Molekulardynamik

Molekülmechanik

Docking

Solvatation

Kraftfeldberechnung

MMFF94

Naphthylalanin

Tyrosin

Tyrosinat

Hydropathie

Wasserstoffbrücken

aggregation

peptide aggregation

peptide docking

fluorescence spectroscopy

amyloid

molecular modelling

molecular dynamics

force field

hydrogen bonds

hydropathy

hydrophobicity

hydrophobic effect

secondary structure

beta sheet

compute cluster

ddc:540

rvk:WD 5250

Aggregation

Aggregat <Chemie>

Assoziation <Chemie>

Gonadotropin-Releasinghormon-Analoga

Cetrorelix

Fluoreszenzspektroskopie

Amyloid

Gel

Aminosäuren

Nichtproteinogene Aminosäuren

Peptide

Strukturanalyse

Faltblatt

Sekundärstruktur

Wasserstoffbrückenbindung

Hydrophobe Wechselwirkung

Hydrophobie

Van-der-Waals-Kraft

Aromaten

LINUX

Cluster <Rechnernetz>

Hochleistungsrechnen

Kraftfeld

Kraftfeld-Rechnung

Modellierung

Molekulardesign

Molekulardynamik

Docking <Chemie>

Solvatation

Tyrosin

Calcitonin

Amylin

Mikroglobulin <beta-2->

Amyloid <beta->

Amyloid-Peptid <beta->

Lactoferrin

Visualisierung

VRML

Virtualisierung

Visuelle Wahrnehmung

Modellierung und Visualisierung von Systemen zur Beschreibung der intra- und intermolekularen Wechselwirkungen in hydrophoben Peptiden

Schneider, Alexander

08 October 2014

Die vorliegende Arbeit beschäftigt sich mit der Untersuchung und Beschreibung der Eigenschaften der synthetischen Dekapeptide Cetrorelix und Ozarelix durch analytische Methoden und computergestützte Modellierung. Diese Moleküle sind hydrophobe, aggregierende Antagonisten des Gonadotropin-Releasing-Hormons (GnRH). Zusätzlich wurden amyloidbildende Peptidstrukturen als Modelle für die Assoziationsprozesse in hydrophoben Peptiden untersucht und visualisiert. Die intrinsische Fluoreszenz der GnRH-Antagonisten und zusätzlich der Peptide Teverelix und D-Phe6-GnRH sowie von verkürzten Fragmenten des Cetrorelix wurde untersucht. Ein Strukturmodell für die Beschreibung der Aggregation der Dekapeptide wurde erarbeitet. Der Aufbau eines Rechenclusters durch das Einbinden der Computer am Lehrstuhl in ein Linux-System zur Verteilung von Rechenprozessen über das Netzwerk ermöglichte die Bereitstellung der notwendigen Leistung zur Realisierung der Berechnungen. Es wurden Werkzeuge zur Modellierung der solvatisierten Aggregate von Peptiden ohne eindeutige Vorzugsstruktur programmiert und in ein Docking-System für beliebige Moleküle eingebunden. Verwendet wurde das Kraftfeld MMFF94 mit einer Erweiterung durch ein Verfahren zur dynamischen Berechnung von Partialladungen in Molekülstrukturen. Solvatisierte Aggregate der Dekapeptide und von bekannten amyloidbildenden Strukturen wurden modelliert (Docking). Berechnet wurden als aggregierend beschriebene Sequenzen und entsprechende Vergleichsstrukturen des Calcitonins, des Insel-Amyloid-Polypeptides, des beta2-Mikroglobulins, des Amyloid-beta-Proteins, des Lactoferrins und weitere Modellpeptide. Die wesentlichen Wechselwirkungen während der Aggregation konnten schließlich anhand von Dynamik-Simulationen der faltblattartigen Dimere des Cetrorelix und Ozarelix beschrieben werden. So wurden die Prozesse der hydrophoben Assoziation und Stabilisierung durch Wasserstoffbrücken von Peptiden veranschaulicht und auf molekularer Ebene erfolgreich analysiert. Die Visualisierung der erhaltenen Modellierungsergebnisse erfolgt durch die Darstellung der Strukturen und Dynamik-Simulationen als interaktive 3D-Modelle in einem für diese Arbeit aufgebauten Internetauftritt. / This work discusses the analysis of the aggregation properties of the gonadotropin releasing hormone antagonists Cetrorelix, Teverelix, Ozarelix and of small amyloid forming model peptides by analytical fluorescence spectroscopy and molecular modelling. A high performance linux compute cluster was developed for calculation of molecular structures. Solvated aggregate clusters of peptides without defined secondary structure were modelled by molecular mechanics methods (forcefield mmff94) in combination with an advanced charge equilibration and docking technique. Molecular dynamics of solvated peptide dimers were implemented and the role of hydrophic association and hydrogen bond formation in hydrophobic peptide aggregates was explained. Finally, an aggregation model for the directed association of hydrophobic peptides is presented. The modelling results, 3d structures and dynamic simulations are visualized in an interactive web material.

info:eu-repo/classification/ddc/540

ddc:540