D. C. Florian Wieland

Intercalation in Layered Metal–Organic Frameworks: Reversible Inclusion of an Extended π-System

We report the synthesis of layered [Zn(2)(bdc)(2)(H(2)O)(2)] and [Cu(2)(bdc)(2)(H(2)O)(2)] (bdc = benzdicarboxylate) metal-organic frameworks (MOF) carried out using the liquid-phase epitaxy approach employing self-assembled monolayer (SAM) modified Au-substrates. We obtain Cu and Zn MOF-2 structures, which have not yet been obtained using conventional, solvothermal synthesis methods. The 2D Cu(2+) dimer paddle wheel planes characteristic for the MOF are found to be strictly planar, with the planes oriented perpendicular to the substrate. Intercalation of an organic dye, DXP, leads to a reversible tilting of the planes, demonstrating the huge potential of these surface-anchored MOFs for the intercalation of large, planar molecules.

Exploring the Piezophilic Behavior of Natural Cosolvent Mixtures

Proteins are only marginally stable and are hence very sensitive to environmental conditions, such as high and low temperatures or high hydrostatic pressures. In nature, living organisms are able to compensate for extreme environmental conditions and hence rescue proteins from denaturation by using osmolytes. Organic osmolytes are accumulated under anhydrobiotic, thermal, and pressure stresses. Among those osmolytes are amino acids, polyols and sugars (e.g., glycerol and trehalose), methylamines such as trimethylamine-Noxide (TMAO), and urea. TMAO has been found to enhance protein folding and ligand binding most efficiently. On the other hand, urea, a highly concentrated waste product in mammalian kidneys, is a perturbant. It is also a major organic osmolyte in marine elasmobranch fishes. Interestingly, TMAO has been found to counteract perturbations imposed by urea and hydrostatic pressure in deep-sea animals, most effectively at a 2:1 urea:TMAO ratio. In the deep sea, hydrostatic pressures up to the 1 kbar (100 MPa) range prevail, and living organisms have to cope with such extreme environmental conditions. High hydrostatic pressure generally destabilizes the protein structure, inhibits polymerization of proteins and ligand binding. Interestingly, TMAO has been shown to largely offset these pressure effects. In fact, it was found that the amount of TMAO in the cells of a series of marine organisms increases linearly with the depth of the ocean. For that reason, TMAO is thought to serve as pressure counteractant. The term “piezolyte” has been coined for such kind of cosolute. About the underlying mechanism of stabilization by TMAO at ambient pressure conditions several experimental and theoretical (molecular dynamics simulations) articles have been published in recent years. TMAO is largely excluded from the protein surface and enhances the water structure causing greater organization through more and stronger hydrogen bonding among water molecules. However, the mechanism of this “chemical chaperon” at high hydrostatic pressure (HHP) conditions is still unclear. To yield a deeper understanding of this phenomenon, we determined the intermolecular interaction of dense protein solutions in the absence and presence of cosolvent mixtures of TMAO and urea also under HHP conditions. Small-angle Xray scattering (SAXS) experiments on dense lysozyme solutions have been carried out in the pressure range from 1 bar up to 4 kbar. The SAXS technique accurately monitors structural alterations of the protein solution and yields quantitative information on the state-dependent protein– protein interaction potential. As lysozyme is a highly stable protein, pressure-induced effects will only be attributed to changes in the protein–protein interaction of the native protein and how this is influenced by osmolytes. No pressureinduced unfolding of the protein occurs in the pressure range covered. Complementary thermodynamic data, that is, the temperature of unfolding and the volume change upon unfolding of the protein, were obtained by differential scanning (DSC) and pressure perturbation calorimetry (PPC), respectively. To verify that the protein is folded at all solution conditions studied, SAXS measurements on diluted lysozyme solutions (cP= 10 mgmL ) were carried out in the whole pressure range covered. For diluted protein solutions, the scattering intensity I(q) is proportional to the form factor P(q) (q= (4p/l)sin(V/2) is the wave vector transfer, l the wavelength of the X-rays, and V the scattering angle), which depends on the structure and size of the protein. For dilute lysozyme solutions, the radius of gyration of the particle, Rg, could be determined. We found a constant Rg value of (15.1 0.4) up to 4 kbar, indicating the absence of unfolding even at the highest pressure applied. In the case of concentrated protein solutions, the interaction between the particles gives rise to an additional scattering contribution. This SAXS signal can be described as the product of the form factor and an effective structure factor, which is related to the intermolecular structure factor S(q). To relate the structure factor to the protein–protein interaction potential, statistical mechanical model approaches have to be employed. Here, the mean-spherical approximation (MSA) in combination with the DLVO (Derjaguin– Landau–Verwey–Overbeek) potential V(r) has been used. The pair potential V(r) is given as the sum of a hard sphere potential VHS(r), a repulsive screened Coulomb-like potential VSC(r) and an attractive Yukawian potential VY(r), which is frequently used to describe protein–protein interactions (for details, see the Supporting Information). [*] Y. Zhai, Prof. Dr. R. Winter Fakult t Chemie, TU Dortmund Physikalische Chemie—Biophysikalische Chemie Otto-Hahn Str. 6, 44227 Dortmund (Germany) E-mail: roland.winter@tu-dortmund.de

Multiple phase-transitions upon selective CO2 adsorption in an alkyl ether functionalized metal–organic framework—an in situ X-ray diffraction study

The flexible alkyl ether functionalized metal–organic framework [Zn2(BME-bdc)2(dabco)]n (BME-bdc = 2,5-bis(2-methoxyethoxy)-1,4-benzenedicarboxylate, dabco = 1,4-diazabicyclo[2.2.2]octane) shows remarkable structural changes upon selective adsorption of CO2 as determined by in situ X-ray diffraction at 195 K. Upon accommodation of carbon dioxide [Zn2(BME-bdc)2(dabco)]n transfers from a narrow pore form to an open pore form, which exhibits a much higher unit cell volume. Due to the slow adsorption kinetics an unexpected metastable intermediate form could be identified.

High-Pressure SAXS Study of Folded and Unfolded Ensembles of Proteins

A structural interpretation of the thermodynamic stability of proteins requires an understanding of the structural properties of the unfolded state. High-pressure small-angle x-ray scattering was used to measure the effects of temperature, pressure, denaturants, and stabilizing osmolytes on the radii of gyration of folded and unfolded state ensembles of staphylococcal nuclease. A set of variants with the internal Val-66 replaced with Ala, Tyr, or Arg was used to examine how changes in the volume and polarity of an internal microcavity affect the dimensions of the native state and the pressure sensitivity of the ensemble. The unfolded state ensembles achieved for these proteins with high pressure were more compact than those achieved at high temperature, and were all very sensitive to the presence of urea and glycerol. Substitutions at the hydrophobic core detectably altered the conformation of the protein, even in the folded state. The introduction of a charged residue, such as Arg, inside the hydrophobic interior of a protein could dramatically alter the structural properties, even those of the unfolded state. The data suggest that a charge at an internal position can interfere with the formation of transient hydrophobic clusters in the unfolded state, and ensure that the pressure-unfolded form of a protein occupies the maximum volume possible. Only at high temperatures does the radius of gyration of the unfolded state ensemble approach the value for a statistical random coil.

Effect of magnetic nanoparticles on the surface rheology of surfactant films at the water surface

The stability of fluid interfaces is important in many technical fields, e.g. suspensions, emulsions and foams. In this publication we investigated the influence of maghemite nanoparticles (γ-Fe2O3) on the surface stability of different surfactant films (SDS, CTAB, Brij 35). We investigated the interactions between nanoparticles and surfactant films by means of surface dilatation and surface shear rheological experiments. For further characterizations we used X-ray reflectivity (XRR) measurements, dynamic light scattering (DLS) and zeta (ζ)-potential measurements. For CTAB and more obvious for SDS it was found that at low to moderate surfactant concentrations, the viscoelasticity of the interface was increased drastically in the presence of the iron oxide nanoparticles. For films of Brij 35, however, the nanoparticles did not have any influence on the surface rheology.

Structure of DPPC–hyaluronan interfacial layers – effects of molecular weight and ion composition

Hyaluronan and phospholipids play an important role in lubrication in articular joints and provide in combination with glycoproteins exceptionally low friction coefficients. We have investigated the structural organization of 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) Langmuir layers at the solution-air interface at different length scales with respect to the adsorption of hyaluronan (HA). This allows us to assemble a comprehensive picture of the adsorption and the resulting structures, and how they are affected by the molecular weight of HA and the presence of calcium ions. Brewster angle microscopy and grazing incident diffraction were used to determine the lateral structure at the micro- and macro scale. The data reveals an influence of HA on both the macro and micro structure of the DPPC Langmuir layer, and that the strength of this effect increases with decreasing molecular weight of HA and in presence of calcium ions. Furthermore, from X-ray reflectivity measurements we conclude that HA adsorbs to the hydrophilic part of DPPC, but data also suggest that two types of interfacial structures are formed at the interface. We argue that hydrophobic forces and electrostatic interactions play important rules for the association between DPPC and HA. Surface pressure area isotherms were used to determine the influence of HA on the phase behavior of DPPC while electrophoretic mobility measurements were used to gain insight into the binding of calcium ions to DPPC vesicles and hyaluronan.

The influence of hyaluronan on the structure of a DPPC—bilayer under high pressures

The superior lubrication properties of synovial joints have inspired many studies aiming at uncovering the molecular mechanisms which give rise to low friction and wear. However, the mechanisms are not fully understood yet, and, in particular, it has not been elucidated how the biolubricants present at the interface of cartilage respond to high pressures, which arise during high loads of joints. In this study we utilize a simple model system composed of two biomolecules that have been implied as being important for joint lubrication. It consists of a solid supported dipalmitoylphosphatidylcholin (DPPC) bilayer, which was formed via vesicles fusion on a flat Si wafer, and the anionic polysaccharide hyaluronan (HA). We first characterized the structure of the HA layer that adsorbed to the DPPC bilayers at ambient pressure and different temperatures using X-ray reflectivity (XRR) measurements. Next, XRR was utilized to evaluate the response of the system to high hydrostatic pressures, up to 2kbar (200MPa), at three different temperatures. By means of fluorescence microscopy images the distribution of DPPC and HA on the surface was visualized. Our data suggest that HA adsorbs to the headgroup region that is oriented towards the water side of the supported bilayer. Phase transitions of the bilayer in response to temperature and pressure changes were also observed in presence and absence of HA. Our results reveal a higher stability against high hydrostatic pressures for DPPC/HA composite layers compared to that of the DPPC bilayer in absence of HA.

Manipulating thin polymer films by changing the pH value

The structural change of Langmuir layers composed of alkyltrichlorosilanes under the influence of ammonia (NH3) was investigated. X-ray reflectivity and grazing incidence diffraction measurements along with surface pressure and surface potential measurements were performed in order to characterize the network structure. The data show an increase of the scattered intensity after addition of ammonia while the domain and unit cell size of the film did not change. These results show a higher surface coverage, which is not caused by a simple compression of the lipid tails. The effect can be attributed to a closing of voids in the polymer film caused by temporary breaking and annealing of the chemical bonds in the network by an increase of pH.

Bulk sensitive determination of the Fe3+/FeTot-ratio in minerals by Fe L2/3-edge X-ray Raman scattering

We present the first measurements of the iron L2/3-edge of the compounds FeO, Fe2O3, and Fe3O4 at ambient pressure and of FeCO3 at high pressures of 2.4 and 40 GPa using a diamond anvil cell by X-ray Raman scattering spectroscopy, a bulk sensitive probe of soft X-ray absorption edges making use of hard X-rays. We show that the spectral shape of the Fe L2/3-edge can be analyzed quantitatively to reveal the oxidation state of iron in matter. Consequently, in situ X-ray Raman scattering spectroscopy at the iron L-edge at high pressure and temperature opens exciting perspectives to characterize the local coordination, oxidation, and spin state of iron at high pressure and temperature, conditions that are of relevance for e.g. geological sciences or chemical processing.

Mixed Layers of Nonionic Dendritic Amphiphiles and DPPC at the Water Surface

Nonionic dendritic amphiphiles that self-assemble into defined supramolecular aggregates are useful for the efficient solubilization of active agents, for example, in drug delivery. We investigated a new class of dendritic amphiphiles based on a hydrophilic polyol dendron head connected to a two-chain hydrophobic block. In analogy to phospholipids, these molecules form well-organized layers in bulk (vesicles) or at the water surface (Langmuir monolayer). The actual study focuses on the phase behavior and microscopic structure of mixed Langmuir layers of theses dendritic amphiphiles with the well-known phospholipid DPPC. The combination of surface pressure area isotherms with X-ray grazing incident diffraction and Brewster angle microscopy gives us information on the phase behavior of the mixed monolayers and the orientation of the amphiphiles inside the condensed domains with molecular resolution. We could prove that the dendritic generation and, by this, the headgroup size of the amphiphilic molecules have a significant influence on their interaction with DPPC at the air-water interface. Thus, our findings are important for the understanding of mixed lipid membranes in general as well as for the preparation of artificial membranes and vesicles with adjustable properties, e.g., their drug delivery potential.