Lipoprotein particles associate with lipid-linked proteins and are required for long-range Wingless and Hedgehog signaling / Lipoprotein-Partikel assoziieren mit lipid-modifizierten proteinen und sind notwendig zur Wingless-und Hedgehog Signaltransduktion über grosse Distanzen.

Panakova, Daniela

21 June 2005

Morphogens of the Wnt and Hedgehog families are secreted signaling molecules that coordinate growth and patterning of many different tissues. Both, Wingless and Hedgehog spread across long distances in developing wing of Drosophila melanogaster. However, both proteins are covalently modified with lipid moieties. The mechanisms that allow long-range movement of such hydrophobic molecules are unclear. Like Wingles and Hedgehog, glycosylphosphatidylinositol (gpi)-linked proteins also transfer between cells with their lipid anchor intact. It has been speculated that gpi-linked proteins and lipid-linked morphogens travel together on a membranous particle, which was termed an argosome. As yet however, no functional link between argosome production and dispersal of lipid-linked proteins has been established. The topic of this thesis is to understand the cell biological nature of the argosome and thus contribute to understanding of morphogen gradient formation. To address the question of argosome biosynthesis, at least two models have been proposed. One possibility is that argosomes are membranous exovesicles with a complete membrane bilayer. Alternatively, argosomes might resemble lipoprotein particles that comprise on of a family of apolipoproteins scaffolded around a phospholipid monolayer that surrounds a core of esterified cholesterol and triglyceride. Lipid-modified proteins of the exoplasmic face of the membrane (like GFPgpi, Wingless or Hedgehog) might fit well into the outer phospholipid monolayer of such a particle. Here, I utilize biochemical fractionation to determine the sort of particle that lipid-linked proteins associate with. I show that Wingless, Hedgehog and gpi-linked proteins bind Drosophila lipoprotein particles in vitro, and colocalize with them in wing imaginal discs. Next, I use genetic means to address the functional importance of this association. I demonstrate that reducing Lipophorin levels in Drosophila larvae perturbs long-range but not shor-range Wingless and Hedgehog signaling, and increases the sequestration of Hedgehog by Patched. I propose that Lipophorin particles are vehicles for the long-range movement of lipid-linked morphogens and gpi-linked proteins.

Lipoprotein-Partikel

Lipophorin

Signaltransduktion

Wingless

Hedgehog

lipid-modifizierten Proteinen

gpi-modifizierten Proteinen

lipid-linked proteins

gpi-linked proteins

lipoprotein particles

Lipophorin

signal transduction

Wingless

Hedgehog

ddc:570

rvk:WE 5320

Lipoproteide

Morphogen

Signaltransduktion

Lipoprotein particles associate with lipid-linked proteins and are required for long-range Wingless and Hedgehog signaling

Panakova, Daniela

01 July 2005

Morphogens of the Wnt and Hedgehog families are secreted signaling molecules that coordinate growth and patterning of many different tissues. Both, Wingless and Hedgehog spread across long distances in developing wing of Drosophila melanogaster. However, both proteins are covalently modified with lipid moieties. The mechanisms that allow long-range movement of such hydrophobic molecules are unclear. Like Wingles and Hedgehog, glycosylphosphatidylinositol (gpi)-linked proteins also transfer between cells with their lipid anchor intact. It has been speculated that gpi-linked proteins and lipid-linked morphogens travel together on a membranous particle, which was termed an argosome. As yet however, no functional link between argosome production and dispersal of lipid-linked proteins has been established. The topic of this thesis is to understand the cell biological nature of the argosome and thus contribute to understanding of morphogen gradient formation. To address the question of argosome biosynthesis, at least two models have been proposed. One possibility is that argosomes are membranous exovesicles with a complete membrane bilayer. Alternatively, argosomes might resemble lipoprotein particles that comprise on of a family of apolipoproteins scaffolded around a phospholipid monolayer that surrounds a core of esterified cholesterol and triglyceride. Lipid-modified proteins of the exoplasmic face of the membrane (like GFPgpi, Wingless or Hedgehog) might fit well into the outer phospholipid monolayer of such a particle. Here, I utilize biochemical fractionation to determine the sort of particle that lipid-linked proteins associate with. I show that Wingless, Hedgehog and gpi-linked proteins bind Drosophila lipoprotein particles in vitro, and colocalize with them in wing imaginal discs. Next, I use genetic means to address the functional importance of this association. I demonstrate that reducing Lipophorin levels in Drosophila larvae perturbs long-range but not shor-range Wingless and Hedgehog signaling, and increases the sequestration of Hedgehog by Patched. I propose that Lipophorin particles are vehicles for the long-range movement of lipid-linked morphogens and gpi-linked proteins.

info:eu-repo/classification/ddc/570

ddc:570

Glycopolymer Polyelectrolyte Multilayers Based on Maltose-Modified Hyperbranched Poly(ethyleneimine) For Future Drug Delivery Coatings and Biomedical Applications

Salem, Samaa

08 July 2015

Establishing highly sophisticated polymer films for delivery systems in a biological environment and bioanalytical tasks, the formation, thickness, swelling behavior, and (physiological) stability of highly biocompatible polyelectrolyte multilayers (PEMs) are described. These PEMs are composed of the very weak polycation maltose-modified hyperbranched poly(ethyleneimine) (PEI-Mal), strongly polyanion heparin sodium salt (HE − Na +) or weakly charged polyanion hyaluronic acid sodium salt (HA-Na+) deposited on Si wafer substrates. Two different glyco architectures for PEI-Mal are used, characterized by two different degrees of maltose decoration on a PEI scaffold. Using three pH-dependent deposition approaches for optimizing the (physiological) PEM stability and swelling, PEMs are characterized by (in situ) ellipsometry, atomic force microscopy (AFM), and (in situ) attenuated total reflection-Fouriertransform infrared (ATR-FTIR). Thus, PEMs reveal significantly different thicknesses, growth mechanisms (linear versus exponential), and swelling behavior in dependence of both the polycation architectures and the deposition protocol. These PEMs will allow the study of their complexation and release properties as preswollen PEMs against anionic drug molecules, adenosine triphosphate sodium salt (ATP), especially under physiological conditions for future drug delivery coatings.

Polyelektrolytmultischicht

Schicht-für-Schicht-Abscheidungs

Maltose-modifizierten Poly (ethylenimin)

Heparin-Natriumsalz

Hyaluronsäure

Adenosintriphosphat Natriumsalz

elektrostatische Wechselwirkung

polyelectrolyte multilayer

layer-by-layer deposition

maltose-modified poly(ethyleneimine)

heparin sodium salt

hyaluronic acid

adenosine triphosphate sodium salt

electrostatic interaction

ddc:540

rvk:VK 8007

Glycopolymer Polyelectrolyte Multilayers Based on Maltose-Modified Hyperbranched Poly(ethyleneimine) For Future Drug Delivery Coatings and Biomedical Applications

Salem, Samaa

01 July 2015

Establishing highly sophisticated polymer films for delivery systems in a biological environment and bioanalytical tasks, the formation, thickness, swelling behavior, and (physiological) stability of highly biocompatible polyelectrolyte multilayers (PEMs) are described. These PEMs are composed of the very weak polycation maltose-modified hyperbranched poly(ethyleneimine) (PEI-Mal), strongly polyanion heparin sodium salt (HE − Na +) or weakly charged polyanion hyaluronic acid sodium salt (HA-Na+) deposited on Si wafer substrates. Two different glyco architectures for PEI-Mal are used, characterized by two different degrees of maltose decoration on a PEI scaffold. Using three pH-dependent deposition approaches for optimizing the (physiological) PEM stability and swelling, PEMs are characterized by (in situ) ellipsometry, atomic force microscopy (AFM), and (in situ) attenuated total reflection-Fouriertransform infrared (ATR-FTIR). Thus, PEMs reveal significantly different thicknesses, growth mechanisms (linear versus exponential), and swelling behavior in dependence of both the polycation architectures and the deposition protocol. These PEMs will allow the study of their complexation and release properties as preswollen PEMs against anionic drug molecules, adenosine triphosphate sodium salt (ATP), especially under physiological conditions for future drug delivery coatings.

info:eu-repo/classification/ddc/540

ddc:540