Malaria has been a major driving force in the evolution of the human genome. In sub-Saharan African populations, two neighbouring polymorphisms in the Complement Receptor 1 (CR1) gene, named Swain-Langley (Sl2) and McCoy (McCb), occur at high frequencies, consistent with selection by malaria. This thesis investigates the association between these two polymorphisms and severe malaria. Previous studies into this area have produced conflicting findings. Using a large case-control study of severe malaria in Kenyan children and statistical models adjusted for confounders, I found that the Sl2 polymorphism was associated with markedly reduced odds of cerebral malaria and death, while the McCb polymorphism was associated with increased odds of cerebral malaria. I also identified an interaction between Sl2 and α+thalassaemia, with the protective association of Sl2 greatest in children with normal α-globin. Following these epidemiological findings, I explored potential biological hypotheses which might explain them. The first approach examined whether the Sl2 and McCb polymorphisms affected how CR1 forms clusters on erythrocyte membranes, a process which is key in the binding and transfer of immune complexes from erythrocytes to macrophages. Using erythrocytes from Kenyan children, I performed immunofluorescence assays (IFAs) with confocal microscopy to quantify CR1 cluster number and volume. I found no association between the Sl2 and McCb polymorphisms and either the number or volume of CR1 clusters formed. The second approach investigated whether the cerebral malaria-specific associations seen with Sl2 and McCb might be due to expression of CR1 by human brain endothelial cells (HBEC). The immortalised cell line HBEC-5i was investigated for expression of CR1 using IFA, flow cytometry, western blotting, functional C3b degradation assays, mass spectrometry, immunoprecipitation and siRNA knockdown experiments. A pool of α-CR1 monoclonal antibodies recognised an intracellular antigen in permeabilised HBEC-5i cells which was a similar molecular weight to CR1 on western blotting. However, when the α-CR1 monoclonal antibodies were tested individually, only E11 recognised an HBEC-5i antigen. Further investigative approaches did not support the presence of CR1 on HBEC-5i cells, instead suggesting that E11 was not specific for CR1 and was instead recognising a protein in the Golgi apparatus. The final approach was to examine whether the Sl2 and McCb polymorphisms might influence the binding of the complement components mannose binding lectin, C1q and L-ficolin to the LHR-D region of CR1. I aimed to generate recombinant proteins of the LHR-D region which included the polymorphisms. Site-directed mutagenesis of the region was successful and subcloning and expression of the mutant amplicons will be performed at a later date. In summary, I have identified opposing associations between the Sl2 and McCb polymorphisms and cerebral malaria, which do not appear to be due to differences in CR1 clustering or expression of CR1 by human brain endothelial cells. My investigation into whether the polymorphisms might influence complement component binding is ongoing.
Identifer | oai:union.ndltd.org:bl.uk/oai:ethos.bl.uk:764094 |
Date | January 2018 |
Creators | Swann, Olivia Veronica Fowell |
Contributors | Rowe, Alex ; Knott, Sara |
Publisher | University of Edinburgh |
Source Sets | Ethos UK |
Detected Language | English |
Type | Electronic Thesis or Dissertation |
Source | http://hdl.handle.net/1842/33280 |
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