53 research outputs found
Zona Pellucida like Domain Protein 1 (ZPLD1) Polymerization Is Regulated by Two Distinguished Hydrophobic Motifs
Zona Pellucida Like Domain 1 Protein (ZPLD1) is a main component of the cupula, a gelatinous structure located in the labyrinth organ of the inner ear and involved in vestibular function. The N-glycosylated protein is likely able to organize high-molecular-weight polymers via its zona pellucida (ZP) module, which is common for many extracellular proteins that self-assemble into matrices. In this work, we confirmed that ZPLD1 can form multimers while setting up a cellular model leveraging Madin–Darby canine kidney (MDCK) cells to study protein polymerization. We identified two motifs within ZPLD1 which regulate its polymerization and follow previously published conserved regions, identified across ZP proteins. Mutational depletion of either one of these modules led to diminished or abnormal polymer formation outside of the cells, likely due to altered processing at the plasma membrane. Further, intracellular polymer formation was observed. Proteolytic cleavage during secretion, separating the regulatory motif located distinct of the ZP module from the mature monomer, seems to be necessary to enable polymerization. While the molecular interactions of the identified motifs remain to be proven, our findings suggest that ZPLD1 is a polymer forming ZP protein following an orchestrated mechanism of protein polymerization to finally build up a gelatinous hydrogel
Single-Step Purification of Monomeric l-Selectin via Aptamer Affinity Chromatography
l-selectin is a transmembrane receptor expressed on the surface of white blood
cells and responsible for the tethering of leukocytes to vascular endothelial
cells. This initial intercellular contact is the first step of the complex
leukocyte adhesion cascade that ultimately permits extravasation of leukocytes
into the surrounding tissue in case of inflammation. Here we show the binding
of a soluble histidine tagged l-selectin to a recently described shortened
variant of an l-selectin specific DNA aptamer with surface plasmon resonance.
The high specificity of this aptamer in combination with its high binding
affinity of ~12 nM, allows for a single-step protein purification from cell
culture supernatants. In comparison to the well-established Ni-NTA based
technology, aptamer affinity chromatography (AAC) was easier to establish,
resulted in a 3.6-fold higher protein yield, and increased protein purity.
Moreover, due to target specificity, the DNA aptamer facilitated binding
studies directly from cell culture supernatant, a helpful characteristic to
quickly monitor successful expression of biological active l-selectin. View
Full-Tex
Multivalent interaction and selectivities in selectin binding of functionalized gold colloids decorated with carbohydrate mimetics
Colloidal gold particles with functionalized organic shells were applied as novel selectin binders. The ligand shell was terminated with different monocyclic carbohydrate mimetics as simplified analogs of the sLe(x) unit found in biological selectin ligands. The multivalent presentation of the sulfated selectin binding epitopes on the gold particles led to extremely high binding affinities towards L- and P-selectin and IC(50) values in the subnanomolar range. Depending on the ring size of the sulfated carbohydrate mimetic, its substitution pattern and its configuration, different selectivities for either L-selectin or P-selectin were obtained. These selectivities were not found for gold particles with simple acyclic sulfated alcohols, diols and triols in the ligand shell. In addition, the influence of the particle size and the thickness of the hydrophobic organic shell were systematically investigated
Significantly enhanced proteolytic activity of cyclen complexes by monoalkylation
A simple approach towards efficient artificial proteases based on the cyclen
ligand is presented. We thus achieved an increase of the proteolytic activity
of two orders of magnitude when compared to the unsubstituted cyclen complex.
Amphiphilic Cu(II) and Co(III) complexes cut BSA and myoglobin as model
substrates at μM concentrations. MALDI-ToF MS is used to identify the cleavage
fragments
dPGS Regulates the Phenotype of Macrophages via Metabolic Switching
The synthetic compound dendritic polyglycerol sulfate (dPGS) is a pleiotropic acting molecule but shows a high binding affinity to immunological active molecules as L-/P-selectin or complement proteins leading to well described anti-inflammatory properties in various mouse models. In order to make a comprehensive evaluation of the direct effect on the innate immune system, macrophage polarization is analyzed in the presence of dPGS on a phenotypic but also metabolic level. dPGS administered macrophages show a significant increase of MCP1 production paralleled by a reduction of IL-10 secretion. Metabolic analysis reveals that dPGS could potently enhance the glycolysis and mitochondrial respiration in M0 macrophages as well as decrease the mitochondrial respiration of M2 macrophages. In summary the data indicate that dPGS polarizes macrophages into a pro-inflammatory phenotype in a metabolic pathway-dependent manner
Understanding the interaction of polyelectrolyte architectures with proteins and biosystems
Polyelectrolytes such as e.g. DNA or heparin are long linear or branched macromolecules onto which charges are appended. The counterions neutralizing these charges may dissociate in water and will largely determine the interaction of such polyelectrolytes with biomolecules and in particular with proteins. Here we review studies on the interaction of proteins with polyelectrolytes and how this knowledge can be used for medical applications. Counterion release was identified as the main driving force for the binding of proteins to polyelectrolytes: Patches of positive charge become multivalent counterions of the polyelectrolyte which leads to the release of counterions of the polyelectrolyte and a concomitant increase of entropy. We show this by surveying investigations done on the interaction of proteins with natural and synthetic polyelectrolytes. Special emphasis is laid on sulfated dendritic polyglycerols (dPGS). The entire overview demonstrates that we are moving on to a better understanding of charge‐charge interaction in system of biological relevance. Hence, research along these lines will aid and promote the design of synthetic polyelectrolytes for medical applications
Size Dependence of Steric Shielding and Multivalency Effects for Globular Binding Inhibitors
Competitive binding inhibitors based on multivalent nanoparticles have shown
great potential for preventing virus infections. However, general design
principles of highly efficient inhibitors are lacking as the quantitative
impact of factors such as virus concentration, inhibitor size, steric
shielding, or multivalency effects in the inhibition process is not known.
Based on two complementary experimental inhibition assays we determined size-
dependent steric shielding and multivalency effects. This allowed us to adapt
the Cheng–Prusoff equation for its application to multivalent systems. Our
results show that the particle and volume normalized IC50 value of an
inhibitor at very low virus concentration predominantly depends on its
multivalent association constant, which itself exponentially increases with
the inhibitor/virus contact area and ligand density. Compared to multivalency
effects, the contribution of steric shielding to the IC50 values is only
minor, and its impact is only noticeable if the multivalent dissociation
constant is far below the virus concentration, which means if all inhibitors
are bound to the virus. The dependence of the predominant effect, either
steric shielding or multivalency, on the virus concentration has significant
implications on the in vitro testing of competitive binding inhibitors and
determines optimal inhibitor diameters for the efficient inhibition of
viruses
A Simple and Robust Method to Prepare Polyelectrolyte Brushes on Polymer Surfaces
A simple and robust method is presented to immobilize a heparin-analog polyelectrolyte on inert hydrophobic surfaces. It is demonstrated that an amphiphilic block copolymer consisting of linear polyglycerol sulfate (lPGS) and a benzophenone modified anchor block can be bound to polystyrene surfaces in a facile dip-coating procedure. The chaotropic salt guanidinium chloride is used to overcome the aggregation of the polymer as well as the repulsion between highly hydrated sulfate groups and the polystyrene surface. Irradiation with UV light tethers the polymer chains covalently to the surface. The resulting coating exhibits an aggregate morphology that resembles the aggregation behavior in solution, with a coating thickness of 8 nm. The behavior of the surfaces is dominated by the polyelectrolyte brush coating. They swell and collapse in response to different ionic strengths of the surrounding medium, and bind proteins via electrostatic interactions. The coating is stable toward physiological conditions over the course of several weeks. Coated surfaces bind to proteins of the complement cascade when in contact with dilute blood serum, which results in a decrease of complement activity to 78 ± 4%. The coating procedure can also be applied to other nonactivated polymer surfaces, as demonstrated on a polypropylene fleece
Cupulin Is a Zona Pellucida-Like Domain Protein and Major Component of the Cupula from the Inner Ear
The extracellular membranes of the inner ear are essential constituents to
maintain sensory functions, the cupula for sensing torsional movements of the
head, the otoconial membrane for sensing linear movements and accelerations
like gravity, and the tectorial membrane in the cochlea for hearing. So far a
number of structural proteins have been described, but for the gelatinous
cupula precise data are missing. Here, we describe for the first time a major
proteinogenic component of the cupula structure with an apparent molecular
mass of 45 kDa from salmon. Analyses of respective peptides revealed highly
conserved amino-acid sequences with identity to zona pellucida-like domain
proteins. Immunohistochemistry studies localized the protein in the ampulla of
the inner ear from salmon and according to its anatomical appearance we
identified this glycoprotein as Cupulin. Future research on structure and
function of zona pellucida-like domain proteins will enhance our knowledge of
inner ear diseases, like sudden loss of vestibular function and other
disturbances
Site-selective modification of proteins for the synthesis of structurally defined multivalent scaffolds
Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG geförderten) Allianz- bzw. Nationallizenz frei zugänglich.This publication is with permission of the rights owner freely accessible due to an Alliance licence and a national licence (funded by the DFG, German Research Foundation) respectively.A combination of classical site-directed mutagenesis, genetic code engineering and bioorthogonal reactions delivered a chemically modified barstar protein with one or four carbohydrates installed at specific residues. These protein conjugates were employed in multivalent binding studies, which support the use of proteins as structurally defined scaffolds for the presentation of multivalent ligands.DFG, SFB 765, Multivalenz als chemisches Organisations- und Wirkprinzip: Neue Architekturen, Funktionen und Anwendunge
- …