Functional characterization of dolichol phosphate mannose synthases and development of infrared nanoscopy to study membrane proteins in solution
Time: Tue 2026-01-27 13.00
Location: Kollegiesalen, Brinellvägen 8, Stockholm
Language: English
Subject area: Biotechnology
Doctoral student: Markus M. Keskitalo , Industriell bioteknologi
Opponent: Professor Janne Ihalainen, University of Jyväskylä
Supervisor: Professor Christina Divne, Industriell bioteknologi; Professor C. Magnus Johnson, Yt- och korrosionsvetenskap
QC 2025-12-12
Abstract
Membrane proteins are proteins that are embedded in the lipid bilayers of
organisms. Roughly a fourth of all human proteins are estimated to be
membrane proteins and about 60 % of human-approved medications target
membrane proteins. The correct function of membrane proteins is essential to
all organisms.
This thesis is made up of two parts. First, the biochemistry and function of
dolichol phosphate mannose synthases (DPMS) are investigated. These
enzymes are responsible for the transfer of mannose from a nucleotide sugar
donor to the acceptor lipid dolichol phosphate, forming dolichol phosphate
mannose (Dol-P-Man). In eukaryotes and archaea, Dol-P-Man is the key
mannose donor for mannosylation reactions inside the endoplasmic reticulum
(ER) lumen or on the extracellular leaflet of cell membrane, respectively. As
the synthesis of Dol-P-Man is known to take place on the cytoplasmic side of
the ER membrane in eukaryotes or the cell membrane in archaea, the question
remains how Dol-P-Man is transported onto the other side of the membrane
to serve as a mannose donor. This thesis presents a hypothesis in which the
DPMS itself is responsible for the flipping of its own product. The hypothesis
is supported by crystallographic data that shows Dol-P-Man bound to a DPMS
in a “flipped” orientation that could enable the transport to the other side of
the membrane. This thesis also covers the recombinant expression,
purification, and in vitro characterization of DPMS from the zebra fish Danio
rerio. This DPMS is similar to the human enzyme and can therefore yield
mechanistic details behind DPMS-related diseases.
The second part covers the development of scattering-type scanning near-field
optical microscopy (s-SNOM) to study proteins in solution. The method is
capable of collecting images and infrared spectra from samples at nanometerscale
lateral resolution. The method is not readily applicable for the study of
objects in solution, but this limitation can be circumvented by the use of a
liquid cell. The liquid cell is first used to probe the stretching vibrations of
water in nanoscale and the method is then further developed and is applied to
collect images and spectra from purple membranes, a model membrane
comprising tightly packed bacteriorhodopsin molecules and associated lipids.