Templating and self-assembly of biomimetic materials

Mille, Christian

January 2012

This thesis focuses on the use of biomolecular assemblies for creating materials with novel properties. Several aspects of biomimetic materials have been investigated, from fundamental studies on membrane shaping molecules to the integration of biomolecules with inorganic materials. Triply periodic minimal surfaces (TPMS) are mathematically defined surfaces that partition space and present a large surface area in a confined space. These surfaces have analogues in many physical systems. The endoplasmic reticulum (ER) can form intricate structures and it acts as a replica for the wing scales of the butterfly C. rubi, which is characterized by electron microscopy and reflectometry. It was shown to contain a photonic crystal and an analogue to a TPMS. These photonic crystals have been replicated in silica and titania, leading to blue scales with replication on the nanometer scale. Replicas analyzed with left and right handed polarized light are shown be optically active. A macroporous hollow core particle was synthesized using a double templating method where a swollen block copolymer was utilized to create polyhedral nanofoam. Emulsified oil was used as a secondary template which gave hollow spheres with thin porous walls. The resulting material had a high porosity and low thermal conductivity. The areas of inorganic materials and functional biomolecules were combined to create a functional nanoporous endoskeleton. The membrane protein ATP synthase were incorporated in liposomes which were deposited on nanoporous silica spheres creating a tight and functional membrane. Using confocal microscopy, it was possible to follow the transport of Na+ through the membrane. Yop1p is a membrane protein responsible for shaping the ER. The protein was purified and reconstituted into liposomes of three different sizes. The vesicles in the 10-20 nm size range resulted in tubular structures. Thus, it was shown that Yop1p acts as a stabilizer of high curvature structures. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 3: Submitted. Paper 4: Submitted. Paper 5: Submitted.</p>

biomimetic

biotemplating

self-assembly

triply periodic minimal surfaces

the gyroid

photonic crystals

band gap

structural color

chirality

butterflies

membrane proteins

lipid bilayers

sol-gel

mesostructured

polyhedral nanofoams

Phospholipid membranes in biosensor applications : Stability, activity and kinetics of reconstituted proteins and glycolipids in supported membranes

Gustafson, Inga

January 2004

In this study the formation of supported membranes onto planar solid supports has been investigated. The stability and activity of reconstituted membrane receptors has been studied. The potential use of such preparations in biosensor applications is discussed. The lipid films were made by the Langmuir Blodgett and by the liposome fusion techniques. These supported films were characterised by ellipsometry, atomic force microscopy, surface plasmon resonance (SPR) and resonant mirror techniques. The thickness of the films was in agreement with that of a cell membrane. The kinetics of formation of the lipid films was studied and discussed. The proteins, bacteriorhodopsin, cytochrome oxidase, acetylcholinesterase and the nicotinic acetylcholine receptor were reconstituted into the supported membrane. The subsequent analysis showed that the proteins were individually distributed and that the activity was retained, in some cases for several weeks after immobilisation. The glycolipids, GM1, GM2, GD1b, asialo-GM1, globotriaosylceramide, lactosylceramide and galactosylceramide, were also reconstituted into the supported membranes. Their specific interaction with the toxin ricin or with its B-chain was examined using SPR. The affinity of intact toxin and of its B-chain differed markedly and was pH dependent. The carbohydrate chain length and charge density of the glycolipids also influenced the affinity.

Biochemistry

Phospholipid films

Liposomes

Membrane proteins

Glycolipids

Ellipsometry

Langmuir Blodgett (LB)

Surface plasmon resonance (SPR)

Resonant mirror (RM)

Atomic force microscopy (AFM)

Biosensors

Biokemi

Biochemistry

Biokemi

Improved Techniques for Protein Analysis Focusing on Membrane Proteins and Hydrophobic Peptides

Redeby, Theres

January 2006

In this thesis, the vital cell functions performed by integral membrane proteins (IMPs) are briefly discussed. Such proteins are under-represented in most protein studies due to the hydrophobic nature of IMPs, which seriously complicate their solubilization, sample handling, preparation, separation and analysis. Conventional analytical techniques include for example matrix-assisted laser desorption/ionization mass spectrometry (MALDIMS), capillary electrophoresis (CE) and reversed phase high-performance liquid chromatography (RP-HPLC). Presented here are methods and protocols, which have been developed especially for IMP and hydrophobic peptide analysis, using the abovementioned techniques. The fluorinated organic solvent hexafluoroisopropanol (HFIP) has previously been shown beneficial as an additive for solubilization of hydrophobic analytes, which are poorly soluble in commonly used organic solvents or water. In Papers I-IV, HFIP is successfully exploited as solvent for the investigated IMPs and peptides. The simple fabrication and the focusing effect of a new structured MALDI target plate are presented in Paper I. This target plate contains concentrating sample spots, specifically designed to provide increased sensitivity for hydrophobic protein and peptide MALDI-MS analysis. When replacing a regular steel target with this new structured MALDI plate, more than a five-fold increase in average sensitivity is achieved for HFIP solubilized hydrophobic peptides. The full-length IMP bacteriorhodopsin (BR) and a cyanogen bromide digest thereof are used as model samples for the development of sample handling procedures in Paper II, and the peptides were used for evaluation of the MALDI-target plate in Paper I. Furthermore, the CE separation of the peptides, fractionation onto the structured MALDI plate and following MS analysis is presented in Paper III. Nine of the ten theoretical BR peptides were detected using this method. A protocol for the purification and analysis of chloroplast membrane proteins from the green macroalga Ulva lactuca has been described in Paper IV. The highest protein yield was achieved when proteins were extracted in HFIP, directly from the chloroplasts. The MALDI-MS analysis of samples with and without previous RP-HPLC fractionation revealed proteins with molecular weights ranging between 1 and 376 kDa. In Paper V, a closed-open-closed CE system is presented, containing an open microchannel for off-line MALDI detection. The electroosmotic flow and band broadening of this system has been evaluated. / QC 20100916

Integral membrane proteins

Hydrophobic peptides

Sample handling

MALDI-TOF-MS

Structured sample support

CE

fraction collection

microchannel

Analytical chemistry

Analytisk kemi

Stress driven changes in the kinetics of bilayer embedded proteins: a membrane spandex and a voltage-gated sodium channel

Boucher, Pierre-Alexandre

27 May 2011

Bilayer embedded proteins are affected by stress. This general affirmation is, in this thesis, embodied by two types of proteins: membrane spandex and voltage-gated sodium channels. In this work, we essentially explore, using methods from physics, the theoretical consequences of ideas drawn from experimental biology. Membrane spandex was postulated to exist and we study the theoretical implications and possible benefits for a cell to have such proteins embedded in its bilayer. There are no specific membrane spandex proteins, rather any protein with a transition involving a large enough area change between two non-conducting states could act as spandex. Bacterial cells have osmovalve channels which open at near-lytic tensions to protect themselves against rupture. Spandex expanding at tensions just below the osmovalves’ opening tension could relieve tension enough as to avoid costly accidental osmovalve opening due to transient bilayer tension excursions. Another possible role for spandex is a tension-damper: spandex could be used to maintain bilayer tension at a fixed level. This would be useful as many bilayer embedded channels are known to be modulated by tension. The Stress/shear experienced in traumatic brain injury cause an immediate (< 2 min) and irreversible TTX-sensitive rise in axonal calcium. In situ, this underlies an untreatable condition, diffuse axonal injury. TTX sensitivity indicates that leaky voltage-gated sodium (Nav) channels mediate the calcium increase. Wang et al. showed that the mammalian adult CNS Nav isoform, Nav1.6, expressed in Xenopus oocytes becomes “leaky” when subjected to bleb-inducing pipette aspiration. This “leaky” condition is caused by a hyperpolarized-shift (left-shift or towards lower potentials, typically 20 mV) of the kinetically coupled processes of activation and inactivation thus effectively degrading a well-confined window conductance into a TTX-sensitive Na leak. We propose experimental protocols to determine whether this left-shift is the result of an all-or-none or graded process and whether persistent Na currents are also left-shifted by trauma. We also use modeling to assess whether left-shifted Nav channel kinetics could lead to Na+ (and hence Ca2+ ) loading of axons and to study saltatory propagation after traumatizing a single node of Ranvier.

membrane

spandex

tension

membrane proteins

tension relief

voltage-gated sodium channel

trauma

Nav1.6

subthreshold oscillations

activation

inactivation

Nav channel

osmovalve

membrane trauma

nodes of Ranvier

left-shift

Stress driven changes in the kinetics of bilayer embedded proteins: a membrane spandex and a voltage-gated sodium channel

Boucher, Pierre-Alexandre

27 May 2011

Bilayer embedded proteins are affected by stress. This general affirmation is, in this thesis, embodied by two types of proteins: membrane spandex and voltage-gated sodium channels. In this work, we essentially explore, using methods from physics, the theoretical consequences of ideas drawn from experimental biology. Membrane spandex was postulated to exist and we study the theoretical implications and possible benefits for a cell to have such proteins embedded in its bilayer. There are no specific membrane spandex proteins, rather any protein with a transition involving a large enough area change between two non-conducting states could act as spandex. Bacterial cells have osmovalve channels which open at near-lytic tensions to protect themselves against rupture. Spandex expanding at tensions just below the osmovalves’ opening tension could relieve tension enough as to avoid costly accidental osmovalve opening due to transient bilayer tension excursions. Another possible role for spandex is a tension-damper: spandex could be used to maintain bilayer tension at a fixed level. This would be useful as many bilayer embedded channels are known to be modulated by tension. The Stress/shear experienced in traumatic brain injury cause an immediate (< 2 min) and irreversible TTX-sensitive rise in axonal calcium. In situ, this underlies an untreatable condition, diffuse axonal injury. TTX sensitivity indicates that leaky voltage-gated sodium (Nav) channels mediate the calcium increase. Wang et al. showed that the mammalian adult CNS Nav isoform, Nav1.6, expressed in Xenopus oocytes becomes “leaky” when subjected to bleb-inducing pipette aspiration. This “leaky” condition is caused by a hyperpolarized-shift (left-shift or towards lower potentials, typically 20 mV) of the kinetically coupled processes of activation and inactivation thus effectively degrading a well-confined window conductance into a TTX-sensitive Na leak. We propose experimental protocols to determine whether this left-shift is the result of an all-or-none or graded process and whether persistent Na currents are also left-shifted by trauma. We also use modeling to assess whether left-shifted Nav channel kinetics could lead to Na+ (and hence Ca2+ ) loading of axons and to study saltatory propagation after traumatizing a single node of Ranvier.

membrane

spandex

tension

membrane proteins

tension relief

voltage-gated sodium channel

trauma

Nav1.6

subthreshold oscillations

activation

inactivation

Nav channel

osmovalve

membrane trauma

nodes of Ranvier

left-shift

Molecular characterization of the fepA-fes bidirectional promoter in escherichia coli

Morris, Terry Lynn,

January 2001

Thesis (Ph. D.)--University of Missouri--Columbia, 2001. / Typescript. Vita. Includes bibliographical references (leaves 135-149). Also available on the Internet.

Understanding the molecular machinery of aquaporins through molecular dynamics simulations / Verständnis der molekularen Maschinerie von Aquaporinen durch Molekulardynamiksimulationen

Aponte-Santamaria, Camilo Andres

28 February 2011

No description available.

530 Physik

Physics

Aquaporine

Molekulardynamiksimulationen

Wasserpermeation

Wasserkanäle

Membranproteine

Kanalsteuerung

aquaporins

molecular dynamics simulations

water permeation

water channels

membrane proteins

channel gating

33.00

42.12

WC000

RD000

RDH100

Phosphorylcholine based amphiphilic polymers for the solubilization of integral membrane proteins

Diab, Charbel

January 2008

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal

Solubilization

Amphipols

Integral membrane proteins

Phosphorylcholine

Amphiphilic macromolecules

Detergent

Mixed micelles

ITC

Solubilisation

Amphipols

Protéines

Transmembranaires

Phosphorylcholine

Macromolécules amphiphiles

Détergent

Micelles mélangées

ITC

Proteomic Analysis Reveals a Novel Function of the Kinase Sat4p in Saccharomyces cerevisiae Mitochondria

Gey, Uta, Czupalla, Cornelia, Hoflack, Bernard, Krause, Udo, Rödel, Gerhard

07 May 2015

The Saccharomyces cerevisiae kinase Sat4p has been originally identified as a protein involved in salt tolerance and stabilization of plasma membrane transporters, implicating a cytoplasmic localization. Our study revealed an additional mitochondrial (mt) localization, suggesting a dual function for Sat4p. While no mt related phenotype was observed in the absence of Sat4p, its overexpression resulted in significant changes of a specific mitochondrial subproteome. As shown by a comparative two dimensional difference gel electrophoresis (2D-DIGE) approach combined with mass spectrometry, particularly two groups of proteins were affected: the iron-sulfur containing aconitase-type proteins (Aco1p, Lys4p) and the lipoamide-containing subproteome (Lat1p, Kgd2p and Gcv3p). The lipoylation sites of all three proteins could be assigned by nanoLC-MS/MS to Lys75 (Lat1p), Lys114 (Kgd2p) and Lys102 (Gcv3p), respectively. Sat4p overexpression resulted in accumulation of the delipoylated protein variants and in reduced levels of aconitase-type proteins, accompanied by a decrease in the activities of the respective enzyme complexes. We propose a regulatory role of Sat4p in the late steps of the maturation of a specific subset of mitochondrial iron-sulfur cluster proteins, including Aco1p and lipoate synthase Lip5p. Impairment of the latter enzyme may account for the observed lipoylation defects.

Mitochondrien

Proteine

Membrane

TU Dresden

Publikationsfonds

Mitochondria

Hyperexpression techniques

Lipoylation

Membrane proteins

Technical University Dresden

Publication funds

ddc:570

rvk:WE 3100

Exploring the Interplay of Lipids and Membrane Proteins

Ariöz, Candan

January 2014

The interplay between lipids and membrane proteins is known to affect membrane protein topology and thus have significant effect (control) on their functions. In this PhD thesis, the influence of lipids on the membrane protein function was studied using three different membrane protein models. A monotopic membrane protein, monoglucosyldiacylglyecerol synthase (MGS) from Acholeplasma laidlawii is known to induce intracellular vesicles when expressed in Escherichia coli. The mechanism leading to this unusual phenomenon was investigated by various biochemical and biophysical techniques. The results indicated a doubling of lipid synthesis in the cell, which was triggered by the selective binding of MGS to anionic lipids. Multivariate data analysis revealed a good correlation with MGS production. Furthermore, preferential anionic lipid sequestering by MGS was shown to induce a different fatty acid modeling of E. coli membranes. The roles of specific lipid binding and the probable mechanism leading to intracellular vesicle formation were also investigated. As a second model, a MGS homolog from Synechocystis sp. PCC6803 was selected. MgdA is an integral membrane protein with multiple transmembrane helices and a unique membrane topology. The influence of different type of lipids on MgdA activity was tested with different membrane fractions of Synechocystis. Results indicated a very distinct profile compared to Acholeplasma laidlawii MGS. SQDG, an anionic lipid was found to be the species of the membrane that increased the MgdA activity 7-fold whereas two other lipids (PG and PE) had only minor effects on MgdA. Additionally, a working model of MgdA for the biosynthesis and flow of sugar lipids between Synechocystis membranes was proposed. The last model system was another integral membrane protein with a distinct structure but also a different function. The envelope stress sensor, CpxA and its interaction with E. coli membranes were studied. CpxA autophosphorylation activity was found to be positively regulated by phosphatidylethanolamine and negatively by anionic lipids. In contrast, phosphorylation of CpxR by CpxA revealed to be increased with PG but inhibited by CL. Non-bilayer lipids had a negative impact on CpxA phosphotransfer activity. Taken together, these studies provide a better understanding of the significance of the interplay of lipids and model membrane proteins discussed here.

Membrane lipids

membrane proteins

anionic lipids

membrane remodeling

intracellular vesicles

model membrane systems

glycosyltransferase

Escherichia coli

lipid composition

fatty acid modification

membrane curvature

bacterial homeoviscous adaptation