Engineered ferritin nanocage as a cholesterol sequestering agent
Accumulation of lipid laden macrophages (foam cells) is characteristic of atherosclerosis development in the arterial walls. Clinically, the current line of treatment includes using preventive drugs to maintain serum cholesterol levels and emergency surgical interventions at the onset of a heart...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2021
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| Online Access: | https://hdl.handle.net/10356/148691 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Accumulation of lipid laden macrophages (foam cells) is characteristic of
atherosclerosis development in the arterial walls. Clinically, the current line of
treatment includes using preventive drugs to maintain serum cholesterol levels
and emergency surgical interventions at the onset of a heart attack. Therapeutic
moieties such as peptides and small molecules directly targeting plaque
cholesterol delivered using a transport vehicle has been recognized to potentially
be a non-invasive tool for atherosclerosis management. In this thesis, the use of
surface modified ferritin protein nanocages is proposed for the display of
cholesterol sequestering agents for intracellular cholesterol reduction from
atherosclerotic foam cell models. Ferritin cages have been modified by chemical and genetic methods to
incorporate the therapeutic moieties. As a physical sequestration method, he use
of hydrophobic cyclodextrin conjugated to ferritin nanocages as cholesterol
sequestering agents is proposed. Cyclodextrin molecules are chemically
conjugated to the ferritin nanocages surface or encapsulated within the nanocages
using metal co-loading methods. The cyclodextrin conjugated ferritin has
nanomolar affinity to cholesterol molecules as measured using biolayer
interferometry. Treatment of foam cells with the conjugates shows decreased
levels of intracellular accumulated cholesterol. Interaction of cyclodextrin with
membrane cholesterol are observed to play a crucial role in cholesterol reduction
with minimal cholesterol sequestration efficacy observed with cyclodextrins
loaded within the inner cavity of ferritin. As an alternative mechanism of cholesterol sequestration, HDL mimetic peptides were genetically fused to the N-terminus of the cage for surface display.
The secondary and quaternary ferritin structures are found to remain intact after
peptide modification. Up to 30% reduction in intracellular cholesterol levels were
achieved within 24h of treatment with the conjugates in a concentration
dependent manner using the foam cell models. Efflux receptor analysis of treated
samples demonstrates ABCA1 mediated cholesterol efflux mechanism using
mimetic peptides as opposed to a physical sequestration using cyclodextrin
molecules. To further understand the interaction mechanisms of ferritin with
macrophages, in-depth internalization and molecular response studies are carried
out. Ferritin is observed to be internalized by a transferrin receptor-mediated
endocytosis pathway with cavolae and micropinocytosis concurrently playing a
role in the uptake. Subcellular localization and transmission electron micrographs
reveal endosomal localization with subsequent lysosome induced degradation of
the protein shell and release of the iron core in the cytoplasm. mRNA
upregulation of iron regulation relevant proteins and iron export is further
measured with prolonged incubation. Lastly, preliminary pilot studies with
atherosclerotic mice models reveal aortic localization of ferritin within 1h with
greater than 95% of the macrophages in the lesion site homing the nanoparticles.
This thesis thus includes the successful incorporation of therapeutic
agents for cholesterol sequestration from an atherosclerotic marker, foam cells.
Coupled with the internalization properties in macrophages and foam cells, this
project emphasizes the potential of ferritin protein cages to be used as transport
vehicles for cholesterol reduction in atherosclerosis management. |
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