Exploring amino-acid radicals and quinone redox chemistry in model proteins

Westerlund, Kristina

January 2008

<p>Amino-acid radical enzymes have been studied extensively for 30 years but the experimental barriers to determine the thermodynamic properties of their key radical cofactors are so challenging that only a handful of reports exist in the literature. This is a major drawback when trying to understand the long-range radical transfer and/or catalytic mechanisms of this important family of enzymes. Here this issue is addressed by developing a library of well-structured model proteins specifically designed to study tyrosine and tryptophan radicals. The library is based on a 67-residue three-helix bundle (α₃W) and a 117-residue four-helix bundle (α₄W). α₃W and α₄W are single-chain and uniquely structured proteins. They are redox inert except for a single radical site (position 32 in α₃W and 106 in α₄W). Papers I and II describe the design process and the protein characteristics of α₄W as well as a voltammetry study of its unique tryptophan. Paper III and V describe two projects based on α₃C, which is a Trp-32 to Cys-32 variant of α₃W. In Paper III we use α₃C to investigate what effect the degree of solvent exposure of the phenolic OH group has on the redox characteristics of tyrosine analogs. We show that the potential of the PhO•/PhOH redox pair is dominated by interactions with the OH group and that the environment around the hydrophobic part of the phenol has no significant impact. In addition, we observe that interactions between the phenolic OH group and the protein matrix can raise the phenol potential by 0.11-0.12 V relative to solution values. The α₃C system is extended in Paper V to study quinone redox chemistry. Papers III and V contain protocols to generate the cofactor-containing α₃C systems and descriptions of their protein properties. Paper IV describes efforts to redesign α₃Y (a Trp-32 to Tyr-32 variant of α₃W) to contain an interacting Tyr-32/histidine pair. The aim is to engineer and study the effects of a redox-induced proton acceptor in the Tyr-32 site.</p>

amino-acid radicals

quinone redox chemistry

model proteins

protein redesign

electrochemistry

Biochemistry

Biokemi

Exploring amino-acid radicals and quinone redox chemistry in model proteins

Westerlund, Kristina

January 2008

Amino-acid radical enzymes have been studied extensively for 30 years but the experimental barriers to determine the thermodynamic properties of their key radical cofactors are so challenging that only a handful of reports exist in the literature. This is a major drawback when trying to understand the long-range radical transfer and/or catalytic mechanisms of this important family of enzymes. Here this issue is addressed by developing a library of well-structured model proteins specifically designed to study tyrosine and tryptophan radicals. The library is based on a 67-residue three-helix bundle (α3W) and a 117-residue four-helix bundle (α4W). α3W and α4W are single-chain and uniquely structured proteins. They are redox inert except for a single radical site (position 32 in α3W and 106 in α4W). Papers I and II describe the design process and the protein characteristics of α4W as well as a voltammetry study of its unique tryptophan. Paper III and V describe two projects based on α3C, which is a Trp-32 to Cys-32 variant of α3W. In Paper III we use α3C to investigate what effect the degree of solvent exposure of the phenolic OH group has on the redox characteristics of tyrosine analogs. We show that the potential of the PhO•/PhOH redox pair is dominated by interactions with the OH group and that the environment around the hydrophobic part of the phenol has no significant impact. In addition, we observe that interactions between the phenolic OH group and the protein matrix can raise the phenol potential by 0.11-0.12 V relative to solution values. The α3C system is extended in Paper V to study quinone redox chemistry. Papers III and V contain protocols to generate the cofactor-containing α3C systems and descriptions of their protein properties. Paper IV describes efforts to redesign α3Y (a Trp-32 to Tyr-32 variant of α3W) to contain an interacting Tyr-32/histidine pair. The aim is to engineer and study the effects of a redox-induced proton acceptor in the Tyr-32 site.

amino-acid radicals

quinone redox chemistry

model proteins

protein redesign

electrochemistry

Biochemistry

Biokemi

Estudo da interação de líquidos iônicos com proteínas modelo / Study on the interaction of ionic liquids with model proteins.

Raw, Juliana

25 October 2016

Líquidos iônicos (LIs) são sais que se encontram no estado líquido em temperaturas menores que 100ºC e que vêm ganhando protagonismo na área chamada química verde, prometendo: substituir solventes nocivos ao meio ambiente, aprimorar componentes eletrônicos, favorecer biocatálises dentre outros. Sua alta estabilidade e baixa toxicidade são frequentemente afirmadas, porém, devem ainda ser melhor investigadas. Com o objetivo de implementar o entendimento da interação dos líquidos iônicos com sistemas de relevância biológica, realizamos um estudo sistemático acerca da interação de 3 diferentes líquidos iônicos anfifílicos de mesma cabeça polar e diferentes caudas carbônicas ([C10mim][Cl], [C12mim][Cl] e [C14mim][Cl]) com 3 diferentes proteínas modelo, através das técnicas de absorção óptica, fluorescência, dicroísmo circular (CD) e espalhamento de raios-X a baixos ângulos (SAXS). Para Tanto, utilizamos as proteínas BSA e HSA (Albuminas de Soro Bovino e Humano, respectivamente) além da lisozima. Observamos a supressão da fluorescência das proteínas em todos os casos analisados, onde a diminuição da intensidade correspondeu a, para as proteínas BSA, HSA e lisozima, respectivamente, (55±3)%, (16.1±0.8)% e (4.1±0.2)%, em presença de 0.6mM de [C14mim][Cl], (38±2)%, (13.2±0.7)% e (0.6±0.1)% em presença de 0.6mM de [C12mim][Cl] e (11.0±0.5)%, (9.2±0.5)% e (0.0±0.1)% em presença de 0.6mM de [C10mim][Cl]. Os espectros de absorbância e fluorescência de todos os sistemas nos indicam uma interação de contato entre as proteínas e os líquidos iônicos. Constatamos também o deslocamento do pico de fluorescência, das proteínas BSA e HSA, para menores comprimentos de onda (blue-shift), na medida em que a concentração de LI era aumentada. O máximo deslocamento () alcançado correspondeu a (21±1)nm para ambas albuminas, enquanto que a lisozima não apresentou deslocamento significativo. O blue-shift pode ser explicado pela aproximação das cadeias carbônicas e formações de pontes de hidrogênio nas proximidades dos triptofanos. De acordo com a técnica de SAXS, evidenciamos o aumento do raio de giro das proteínas, na medida em que adicionamos LIs. O raio de giro da BSA, da HSA e lisozima em ausência de LI são (29±1)Å, (30±1)Å e (15±1)Å, respectivamente, e passam para (46±1)Å, (44±1)Å e (20±1)Å respectivamente, em presença de 0.6mM de [C14mim][Cl]. As curvas de SAXS também apresentaram o indício da formação de estruturas micelares a partir de uma dada concentração. Além da alteração em sua estrutura terciária, os dados de CD indicam uma leve perda de estrutura secundária de ambas as albuminas (BSA e HSA), passando de 80 para 65% de -hélice em ausência e presença de 0.6mM de [C14mim][Cl], respectivamente. Sugerimos que as interações das proteínas com os líquidos iônicos, embora inicialmente movidas por forças eletroestática, possuem como principal fator o efeito hidrofóbico, portanto quanto maior a cadeia carbônica do LI maior é sua interação com a proteína. Tal interação causa o desenovelamento das proteínas e formação de um complexo e estruturas micelares a altas concentrações de LI. Acreditamos que este trabalho traz novas informações acerca da interação dos LIs com proteínas modelo, indicando sua capacidade de alterar a conformação das mesmas. / Ionic liquids (ILs) are salts that are liquid at temperatures smaller than 100 ° C and are gaining prominence in the so-called green chemistry, promising: replace harmful solvents to the environment, improve electronic components, and favor biocatalysis, among others. Its high stability and low toxicity are often asserted; nevertheless, they are ascribed to ILs due to its small volatility. With the aim of improving the understanding of the interaction of ILs with biological relevant systems, we conducted a systematic study of the interaction of three different ionic liquids of the same polar head and different paraffinic tails ([C10mim][Cl], [C12mim][Cl] and [C14mim][Cl]) with three different model proteins, through the techniques of optical absorption, fluorescence, circular dicrhoism (CD) and small angle X-ray scattering (SAXS). To do so, we use BSA and HSA proteins (Bovine Serum Albumin and the Human Serum Albumin, respectively) and lysozyme. We observed fluorescence quenching, of all studied proteins, where the decrease in the fluorescence was (for BSA, HAS and lysozyme, respectively): (55 ± 3)%, (16.1 ± 0.8)% to (4.1 ± 0.2 )% in the presence of 0.6mm [C14mim][Cl], (38 ± 2)%, (13.2 ± 0.7)% to (0.6 ± 0.1)% in the presence of 0.6mm [C12mim][Cl] and ( 11.0 ± 0.5)% (9.2 ± 0.5)% and (0.0 ± 0.1)% in the presence of 0.6mm [C10mim][Cl]. UV-vis absorbance spectra and fluorescence indicate all systems in a contact interaction between proteins and ionic liquids. We also note the shift of the fluorescent peak of BSA and HSA proteins for shorter wavelengths (blue-shift), as the IL content was increased. The maximum shift () achieved corresponded to (21 ± 1) nm for both albumins, whereas no significant displacement was observed for lysozyme. The blue-shift can be explained by the approach of carbon chains and formation of hydrogen bonds in the vicinity of tryptophan. SAXS data indicate an increasing in the proteins radius of gyration value as ILs was added in the solution. The turning radius of BSA, HSA and lysozyme in the absence of IL are (29 ± 1) Å, (30 ± 1) Å and (15 ± 1) Å, respectively, and go to (46 ± 1) Å, ( 44 ± 1) Å and (20 ± 1) Å, respectively, in the presence of 0.6mm [C14mim][Cl]. The SAXS curves also show evidence of the formation of micellar structures from a given concentration. Besides the change in its tertiary structure, the CD data indicates a slight loss of secondary structure of both albumins (BSA and HSA), from 80 to 65% of -helix in the absence and presence of 0.6mm [C14mim][Cl], respectively. We suggest that the interactions of the protein with the ionic liquid, although initially driven by electrostatic forces, have a major factor hydrophobic effect and thus the higher the carbon chain of greater IL is its interaction with the protein. This interaction causes unfolding of the protein and formation of a micellar structures at high concentrations of IL. We believe this work provides new information about the interaction of ILs with model proteins, indicating its ability to alter the conformation of the same.

Absorção ótica

CD

CD

Espectroscopias

Fluorescence

Fluorescência

interação proteína surfactante.

Ionic liquids

Líquidos iônicos

Model Proteins

optical absorption

Proteínas Modelo

SAXS

SAXS

Spectroscopy

surfactant-protein interaction

Estudo da interação de líquidos iônicos com proteínas modelo / Study on the interaction of ionic liquids with model proteins.

Juliana Raw

25 October 2016

Líquidos iônicos (LIs) são sais que se encontram no estado líquido em temperaturas menores que 100ºC e que vêm ganhando protagonismo na área chamada química verde, prometendo: substituir solventes nocivos ao meio ambiente, aprimorar componentes eletrônicos, favorecer biocatálises dentre outros. Sua alta estabilidade e baixa toxicidade são frequentemente afirmadas, porém, devem ainda ser melhor investigadas. Com o objetivo de implementar o entendimento da interação dos líquidos iônicos com sistemas de relevância biológica, realizamos um estudo sistemático acerca da interação de 3 diferentes líquidos iônicos anfifílicos de mesma cabeça polar e diferentes caudas carbônicas ([C10mim][Cl], [C12mim][Cl] e [C14mim][Cl]) com 3 diferentes proteínas modelo, através das técnicas de absorção óptica, fluorescência, dicroísmo circular (CD) e espalhamento de raios-X a baixos ângulos (SAXS). Para Tanto, utilizamos as proteínas BSA e HSA (Albuminas de Soro Bovino e Humano, respectivamente) além da lisozima. Observamos a supressão da fluorescência das proteínas em todos os casos analisados, onde a diminuição da intensidade correspondeu a, para as proteínas BSA, HSA e lisozima, respectivamente, (55±3)%, (16.1±0.8)% e (4.1±0.2)%, em presença de 0.6mM de [C14mim][Cl], (38±2)%, (13.2±0.7)% e (0.6±0.1)% em presença de 0.6mM de [C12mim][Cl] e (11.0±0.5)%, (9.2±0.5)% e (0.0±0.1)% em presença de 0.6mM de [C10mim][Cl]. Os espectros de absorbância e fluorescência de todos os sistemas nos indicam uma interação de contato entre as proteínas e os líquidos iônicos. Constatamos também o deslocamento do pico de fluorescência, das proteínas BSA e HSA, para menores comprimentos de onda (blue-shift), na medida em que a concentração de LI era aumentada. O máximo deslocamento () alcançado correspondeu a (21±1)nm para ambas albuminas, enquanto que a lisozima não apresentou deslocamento significativo. O blue-shift pode ser explicado pela aproximação das cadeias carbônicas e formações de pontes de hidrogênio nas proximidades dos triptofanos. De acordo com a técnica de SAXS, evidenciamos o aumento do raio de giro das proteínas, na medida em que adicionamos LIs. O raio de giro da BSA, da HSA e lisozima em ausência de LI são (29±1)Å, (30±1)Å e (15±1)Å, respectivamente, e passam para (46±1)Å, (44±1)Å e (20±1)Å respectivamente, em presença de 0.6mM de [C14mim][Cl]. As curvas de SAXS também apresentaram o indício da formação de estruturas micelares a partir de uma dada concentração. Além da alteração em sua estrutura terciária, os dados de CD indicam uma leve perda de estrutura secundária de ambas as albuminas (BSA e HSA), passando de 80 para 65% de -hélice em ausência e presença de 0.6mM de [C14mim][Cl], respectivamente. Sugerimos que as interações das proteínas com os líquidos iônicos, embora inicialmente movidas por forças eletroestática, possuem como principal fator o efeito hidrofóbico, portanto quanto maior a cadeia carbônica do LI maior é sua interação com a proteína. Tal interação causa o desenovelamento das proteínas e formação de um complexo e estruturas micelares a altas concentrações de LI. Acreditamos que este trabalho traz novas informações acerca da interação dos LIs com proteínas modelo, indicando sua capacidade de alterar a conformação das mesmas. / Ionic liquids (ILs) are salts that are liquid at temperatures smaller than 100 ° C and are gaining prominence in the so-called green chemistry, promising: replace harmful solvents to the environment, improve electronic components, and favor biocatalysis, among others. Its high stability and low toxicity are often asserted; nevertheless, they are ascribed to ILs due to its small volatility. With the aim of improving the understanding of the interaction of ILs with biological relevant systems, we conducted a systematic study of the interaction of three different ionic liquids of the same polar head and different paraffinic tails ([C10mim][Cl], [C12mim][Cl] and [C14mim][Cl]) with three different model proteins, through the techniques of optical absorption, fluorescence, circular dicrhoism (CD) and small angle X-ray scattering (SAXS). To do so, we use BSA and HSA proteins (Bovine Serum Albumin and the Human Serum Albumin, respectively) and lysozyme. We observed fluorescence quenching, of all studied proteins, where the decrease in the fluorescence was (for BSA, HAS and lysozyme, respectively): (55 ± 3)%, (16.1 ± 0.8)% to (4.1 ± 0.2 )% in the presence of 0.6mm [C14mim][Cl], (38 ± 2)%, (13.2 ± 0.7)% to (0.6 ± 0.1)% in the presence of 0.6mm [C12mim][Cl] and ( 11.0 ± 0.5)% (9.2 ± 0.5)% and (0.0 ± 0.1)% in the presence of 0.6mm [C10mim][Cl]. UV-vis absorbance spectra and fluorescence indicate all systems in a contact interaction between proteins and ionic liquids. We also note the shift of the fluorescent peak of BSA and HSA proteins for shorter wavelengths (blue-shift), as the IL content was increased. The maximum shift () achieved corresponded to (21 ± 1) nm for both albumins, whereas no significant displacement was observed for lysozyme. The blue-shift can be explained by the approach of carbon chains and formation of hydrogen bonds in the vicinity of tryptophan. SAXS data indicate an increasing in the proteins radius of gyration value as ILs was added in the solution. The turning radius of BSA, HSA and lysozyme in the absence of IL are (29 ± 1) Å, (30 ± 1) Å and (15 ± 1) Å, respectively, and go to (46 ± 1) Å, ( 44 ± 1) Å and (20 ± 1) Å, respectively, in the presence of 0.6mm [C14mim][Cl]. The SAXS curves also show evidence of the formation of micellar structures from a given concentration. Besides the change in its tertiary structure, the CD data indicates a slight loss of secondary structure of both albumins (BSA and HSA), from 80 to 65% of -helix in the absence and presence of 0.6mm [C14mim][Cl], respectively. We suggest that the interactions of the protein with the ionic liquid, although initially driven by electrostatic forces, have a major factor hydrophobic effect and thus the higher the carbon chain of greater IL is its interaction with the protein. This interaction causes unfolding of the protein and formation of a micellar structures at high concentrations of IL. We believe this work provides new information about the interaction of ILs with model proteins, indicating its ability to alter the conformation of the same.

Absorção ótica

CD

Espectroscopias

Fluorescência

interação proteína surfactante.

Líquidos iônicos

Proteínas Modelo

SAXS

CD

Fluorescence

Ionic liquids

Model Proteins

optical absorption

SAXS

Spectroscopy

surfactant-protein interaction

Sequenz, Energie, Struktur - Untersuchungen zur Beziehung zwischen Primär- und Tertiärstruktur in globulären und Membran-Proteinen

Dressel, Frank

08 September 2008

Proteine spielen auf der zellulären Ebene eines Organismus eine fundamentale Rolle. Sie sind quasi die „Maschinen“ der Zelle. Ihre Bedeutung wird nicht zuletzt in ihrem Namen deutlich, welcher 1838 erstmals von J. Berzelius verwendet wurde und „das Erste“, „das Wichtigste“ bedeutet. Proteine sind aus Aminosäuren aufgebaute Moleküle. Unter physiologischen Bedingungen besitzen sie eine definierte dreidimensionale Gestalt, welche für ihre biologische Funktion bestimmend ist. Es wird heutzutage davon ausgegangen, dass diese dreidimensionale, stabile Struktur von Proteinen eindeutig durch die Abfolge der einzelnen Aminosäuren, der Sequenz, bestimmt ist. Diese Abfolge ist für jedes Protein in der Desoxyribonukleinsäure (DNS) gespeichert. Es ist allerdings eines der größten ungelösten Probleme der letzten Jahrzehnte, wie die Beziehung zwischen Sequenz und 3D-Struktur tatsächlich aussieht. Die Beantwortung dieser Fragestellung erfordert interdisziplinäre Ansätze aus Biologie, Informatik und Physik. In dieser Arbeit werden mit Hilfe von Methoden der theoretischen (Bio-) Physik einige der damit verbundenen Aspekte untersucht. Das Hauptaugenmerk liegt dabei auf Wechselwirkungen der einzelnen Aminosäuren eines Proteins untereinander, wofür in dieser Arbeit ein entsprechendes Energiemodell entwickelt wurde. Es werden Grundzustände sowie Energielandschaften untersucht und mit experimentellen Daten verglichen. Die Stärke der Wechselwirkung einzelner Aminosäuren erlaubt zusätzlich Aussagen über die Stabilität von Proteinen bezüglich mechanischer Kräfte. Die vorliegende Arbeit unterteilt sich wie folgt: Kapitel 2 dient der Einleitung und stellt Proteine und ihre Funktionen dar. Kapitel 3 stellt die Modellierung der Proteinstrukturen in zwei verschiedenen Modellen vor, welche in dieser Arbeit entwickelt wurden, um 3D-Strukturen von Proteinen zu beschreiben. Anschließend wird in Kapitel 4 ein Algorithmus zum Auffinden des exakten Energieminimums dargestellt. Kapitel 5 beschäftigt sich mit der Frage, wie eine geeignete diskrete Energiefunktion aus experimentellen Daten gewonnen werden kann. In Kapitel 6 werden erste Ergebnisse dieses Modells dargestellt. Der Frage, ob der experimentell bestimmte Zustand dem energetischen Grundzustand eines Proteins entspricht, wird in Kapitel 7 nachgegangen. Die beiden Kapitel 8 und 9 zeigen die Anwendung des Modells an zwei Proteinen, dem Tryptophan cage protein als dem kleinsten, stabilen Protein und Kinesin, einem Motorprotein, für welches 2007 aufschlussreiche Experimente zur mechanischen Stabilität durchgeführt wurden. Kapitel 10 bis 12 widmen sich Membranproteinen. Dabei beschäftigt sich Kapitel 10 mit der Vorhersage von stabilen Bereichen (sog. Entfaltungsbarrieren) unter externer Krafteinwirkung. Zu Beginn wird eine kurze Einleitung zu Membranproteinen gegeben. Im folgenden Kapitel 11 wird die Entfaltung mit Hilfe des Modells und Monte-Carlo-Techniken simuliert. Mit dem an Membranproteine angepassten Wechselwirkungsmodell ist es möglich, den Einfluss von Mutationen auch ohne explizite strukturelle Informationen vorherzusagen. Dieses Thema wird in Kapitel 12 diskutiert. Die Beziehung zwischen Primär- und Tertiärstruktur eines Proteins wird in Kapitel 13 behandelt. Es wird ein Ansatz skizziert, welcher in der Lage ist, Strukturbeziehungen zwischen Proteinen zu detektieren, die mit herkömmlichen Methoden der Bioinformatik nicht gefunden werden können. Die letzten beiden Kapitel schließlich geben eine Zusammenfassung bzw. einen Ausblick auf künftige Entwicklungen und Anwendungen des Modells.

info:eu-repo/classification/ddc/530

ddc:530

Study of Hsp70/CHIP mediated Protein Quality Control by Folding Sensors

Karunanayake, Chamithi Samadharshi

21 June 2023

No description available.

Biochemistry

Chemistry

Biophysics

Biology