STRUCTURAL AND BIOCHEMICAL STUDIES OF RPE65, THE RETINOID ISOMERASE OF THE VISUAL CYCLE

Kiser, Philip David

30 July 2010

No description available.

Biochemistry

Retinoids

monotopic membrane protein

isomerase

metalloprotein

Structure and lipid interactions of membrane-associated glycosyltransferases : Cationic patches and anionic lipids regulate biomembrane binding of both GT-A and GT-B enzymes

Szpryngiel, Scarlett

January 2016

This thesis concerns work on structure and membrane interactions of enzymes involved in lipid synthesis, biomembrane and cell wall regulation and cell defense processes. These proteins, known as glycosyltransferases (GTs), are involved in the transfer of sugar moieties from nucleotide sugars to lipids or chitin polymers. Glycosyltransferases from three types of organisms have been investigated; one is responsible for vital lipid synthesis in Arabidopsis thaliana (atDGD2) and adjusts the lipid content in biomembranes if the plant experiences stressful growth conditions. This enzyme shares many structural features with another GT found in gram-negative bacteria (WaaG). WaaG is however continuously active and involved in synthesis of the protective lipopolysaccharide layer in the cell walls of Escherichia coli. The third type of enzymes investigated here are chitin synthases (ChS) coupled to filamentous growth in the oomycete Saprolegnia monoica. I have investigated two ChS-derived MIT domains that may be involved in membrane interactions within the endosomal pathway. From analysis of the three-dimensional structure and the amino-acid sequence, some important regions of these very large proteins were selected for in vitro studies. By the use of an array of biophysical methods (e.g. Nuclear Magnetic Resonance, Fluorescence and Circular Dichroism spectroscopy) and directed sequence analyses it was possible to shed light on some important details regarding the structure and membrane-interacting properties of the GTs. The importance of basic amino-acid residues and hydrophobic anchoring segments, both generally and for the abovementioned proteins specifically, is discussed. Also, the topology and amino-acid sequence of GT-B enzymes of the GT4 family are analyzed with emphasis on their biomembrane association modes. The results presented herein regarding the structural and lipid-interacting properties of GTs aid in the general understanding of glycosyltransferase activity. Since GTs are involved in a high number of biochemical processes in vivo it is of outmost importance to understand the underlying processes responsible for their activity, structure and interaction events. The results are likely to be useful for many applications and future experimental design within life sciences and biomedicine. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript.</p>

glycosyltransferase

monotopic membrane proteins

galactolipids

NMR

chitin synthase

DGD2

LPS

WaaG

MIT domain

Property-controlling Enzymes at the Membrane Interface

Ge, Changrong

January 2011

Monotopic proteins represent a specialized group of membrane proteins in that they are engaged in biochemical events taking place at the membrane interface. In particular, the monotopic lipid-synthesizing enzymes are able to synthesize amphiphilic lipid products by catalyzing two biochemically distinct molecules (substrates) at the membrane interface. Thus, from an evolutionary point of view, anchoring into the membrane interface enables monotopic enzymes to confer sensitivity to a changing environment by regulating their activities in the lipid biosynthetic pathways in order to maintain a certain membrane homeostasis. We are focused on a plant lipid-synthesizing enzyme DGD2 involved in phosphate shortage stress, and analyzed the potentially important lipid anchoring segments of it, by a set of biochemical and biophysical approaches. A mechanism was proposed to explain how DGD2 adjusts its activity to maintain a proper membrane. In addition, a multivariate-based bioinformatics approach was used to predict the lipid-binding segments for GT-B fold monotopic enzymes. In contrast, a soluble protein Myr1 from yeast, implicated in vesicular traffic, was also proposed to be a membrane stress sensor as it is able to exert different binding properties to stressed membranes, which is probably due to the presence of strongly plus-charged clusters in the protein. Moreover, a bacterial monotopic enzyme MGS was found to be able to induce massive amounts of intracellular vesicles in Escherichia coli cells. The mechanisms involve several steps: binding, bilayer lateral expansion, stimulation of lipid synthesis, and membrane bending. Proteolytic and mutant studies indicate that plus-charged residues and the scaffold-like structure of MGS are crucial for the vesiculation process. Hence, a number of features are involved governing the behaviour of monotopic membrane proteins at the lipid bilayer interface. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 5: Manuscript.

monotopic membrane protein

lipid-protein interaction

membrane curvature

glycosyltransferase

Rossmann fold

Biochemistry

Biokemi