Crystallisation
of soluble FceRII and FcgRIII under microgravity conditions – Experiment SPC.
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Table of Contents
- Introduction
- Proposal
- References
Immunoglobulin
receptor proteins (FcR) expressed on the surface of all immune competent cells
mediate most humoral immune reactions. These reactions ensure an efficient
and broad immune response by triggering endocytosis of immune complexes,
regulating antibody production by B-lymphocytes, as well as antibody-dependent
cell-mediated cytotoxicity and release of inflammatory mediators that activate
other immune cells. At the same time FcRs mediate abnormally regulated
immune reactions causing common conditions of allergies, asthma, infections,
autoimmune disease and cancer, while also being prime targets of several virus
infections [eg HIV (1), Ebola (2), Measles (3), Dengue (4)]. Being at the
centre of both cellular and humoral immune responses the FcR is an ideal target
for immunotherapy.
One such FcR, FceRII (CD23), was discovered
in the late 1980’s and is now believed to be the central molecule in allergic
responses, more important than the FceRI. The functions of FceRII are
diverse, including cellular adhesion, growth and differentiation of B and T
lymphocytes, rescue from apoptosis, and release of cytotoxic mediators.
Furthermore, FceRII seems to play a pivotal role in regulating IgE production
and hence being the primary cause of certain allergic conditions (5). As
is the case for many immunoglobulin receptors, soluble and membrane-bound forms
are found. However, the precise function(s) of soluble forms of FcR are
unknown. The objective of our research is to study both the protein
structure and function of soluble immunoglobulin Fc receptors with a view to the
rational design of immune therapies to treat allergies, autoimmune diseases,
inflammatory and infectious reactions. Since FceRII plays a major role in
regulating IgE levels, the solution of its structure by X-ray crystallography
would be of enormous benefit and use in designing immune therapies that could
block the interaction of this receptor with IgE and other adhesion proteins such
as CD11. Ideally the best crystals would be those that include the FceRII
in complex with its ligands, particularly IgE, however crystallization of FceRII
alone has been impossible to achieve as yet. This structure would be a
necessary step towards more complex crystals and a better understanding of the
diverse roles of this protein in human immunity.
A second receptor protein of interest is
FcgRIII, an IgG receptor. It is known that HIV infectivity is increased by
the presence of certain antibodies in the human blood circulation, which raises
questions about the usefulness of vaccinations against the virus. The
FcgRIII was shown to be responsible for this antibody-induced increase in HIV
infectivity. We have recently solved the structure of FcgRIII in complex
with IgG at a resolution of 3.2 Å and sFcgRIII on its own at 2.5 Å (6).
Crystallisation of the FcgRIII under microgravity conditions could hopefully
improve the quality of the crystals and allow higher resolution structures to be
determined for the protein. These structures would aid in our
understanding of the structural and thermodynamic mechanisms of interaction
between the FcgRIII and IgG, and ultimately to immune therapies that could block
this interaction. Such immune therapies would also be potentially capable
of reducing the antibody-enhanced infectivity of HIV.
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