The role of complement in a new mouse model of focal retinal degeneration
Abstract
Age-related macular degeneration (AMD) is the leading
cause of irreversible vision loss that poses a major health
problem with substantial socioeconomic implications. The more
prevalent form of AMD is atrophic or ‘dry’ AMD with limited
treatment available. Despite the multifactorial nature of AMD
pathogenesis, a key role for inflammation, which involves the
recruitment of retinal microglia and macrophages and activation
of the complement cascade, is the most strongly implicated of all
factors in the onset of the disease. The chemokine-mediated
recruitment of retinal microglia and macrophages and the
complement dysregulation in AMD such as genetic polymorphisms in
complement factor H (CFH), component 3 (C3) and factor B (CFB)
are highly associated with the disease. The thesis explores the
contributions of complement cascade in the manifestation of focal
retinal degeneration, and further investigates the extent of
retinal microglia and macrophages involvement as the key
instigators of local complement activation. Firstly, the thesis
reports on the design and implementation of a murine
photo-oxidative damage model and investigates the extent to which
it recapitulates several features of dry AMD, including
sequential events of oxidative stress, inflammation and
continuous retinal degeneration. Using this model, I then report
that microglia and macrophages are the key cellular source of
retinal C3 in both rodent retinal degeneration and human AMD. It
is shown that locally-derived C3, synthesized by retinal
microglia and macrophages, contributes to the chronic complement
activation and the progression of retinal degeneration. The
effects of complement activation propagated by C3 are diverse in
neurodegenerative diseases, including AMD. Here, the thesis
reports on the possible role of locally-derived C3 in amplifying
the involvement of innate immune cells, microglia and
macrophages, in focal retinal degeneration. It is shown that the
absence of C3 dampens the accumulation, activation and phagocytic
activity of retinal microglia and macrophages, and correlates
with the reduced progression of retinal degeneration. Finally, I
report on the striking divergence in temporal contributions of
two pathways of complement activation – classical and
alternative - during photo-oxidative damage. The findings
indicate that the alternative pathway, in the form of CfB,
amplifies the cascade and mediates early retinal damage, while
the classical arm, through C1qa, exacerbates retinal degeneration
through the engagement of NLRP3 inflammasome in myeloid cells.
Neutralisation of locally-derived C1q, but not systemic
complement, is able to ameliorate the progression of retinal
degeneration. Collectively, this thesis describes the major
contributions of complement activation, driven by retinal
microglia and macrophages, in the onset and progression of
retinal degeneration induced by photo-oxidative damage. The
findings suggest that suppressing the capability of microglia and
macrophages to elicit complement activation will serve as a
potential strategy for reducing their reactivity, mitigating
their contribution to retinal inflammation and degeneration.
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