Mitochondria are an attractive target for the design of cancer therapy. One of the mechanisms by which chemotherapeutics destroy cancer cells is by inducing apoptosis through extrinsic or intrinsic apoptotic pathways. Extrinsic pathways target cell surface receptors whilst intrinsic pathways target mitochondria. Several studies have shown cancer cell destruction through the extrinsic pathways, which target cancer-specific overexpressed growth factor receptors on the cell membrane. Although the mitochondria dependent apoptotic process is well understood, its application in cancer therapy is still not well developed. Therefore, to design an effective cancer therapy targeting mitochondria, a good understanding in mitochondria dependent apoptotic process is required. Recent developments in nanotechnology have enabled live cell investigations and non-destructive methods to obtain cellular information. The availability of such information would assist to design methods of targeted apoptosis induction.
In view of this, I report on studies towards development of cancer therapy where nanoparticles (NPs) were targeted to human cell mitochondria for two purposes: (a) development of cell-imaging tools to investigate the fundamental cell biological pathways inside cells and (b) induction of apoptosis by targeting nanoparticles to mitochondria. Current medical and biological fluorescent imaging methods are mainly based on dye markers, which are limited in light emission per molecule, as well as photostability. Consequently, NPs are gaining prominence for molecular imaging because of their strong and stable fluorescence.
Additionally, in order to get insight of mitochondrial molecular information, I investigated the use of optical properties of gold nanoparticles (Au NPs) for surface enhanced Raman spectroscopy (SERS). In this study, two types of Au NPs - nanospheres (Au NS) and nanorods (Au NR) were investigated. Results from this study showed the enhancement effect of Au NPs in Raman spectra of mitochondria, especially in the region from 1500 to 1600 cm-1. In this region, normal Raman spectra of mitochondria showed the presence of some understated Raman peaks probably due to the excitation wavelength dependence. Au NRs showed a larger enhancement effect than Au NS with respect to the penetration depth of the plasmonic nearfield enhancement effect. Although, the details of the enhancement mechanism are beyond the current studies, Au NPs could be enhancing vibrations of aromatic residues in proteins. This study therefore showed that Au NPs could enhance Raman spectra of mitochondria and in addition the shape of the nanoparticles had a significant effect on SERS spectra.
In living cells, I investigated some transfection methods and targeting of NPs to mitochondria or cytosolic actin subunits. I tested the performance of three transfection reagents to deliver nanodiamonds (NDs) into living cells. Antibody functionalized NDs were targeted to mitochondria or cytosolic actin subunits. Three transfection reagents were used: cationic liposomes PULSin™, the cell penetrating peptide protamine, and oligosaccharide modified polypropylene imine (PPI) dendrimers. Fluorescence imaging results revealed that dendrimers were the most efficient in delivering ND conjugates to targeted organelles. Protamine-mediated transfections appeared to target ND conjugates to intended organelles, although there was a tendency of unfunctionalized NDs to be directed to the nucleus. PULSin™-mediated transfection formed ND aggregates regardless of the functionalization moiety. This reflected the unsuitability of the cationic liposome to mediate ND transfections.
Further, I investigated the potential use of Au NPs for cell imaging and photothermal lysis of mitochondria inside cells. Just as above, I also tested the performance of the three-transfection reagents mentioned above on transfection capacity of Au NPs into living cells. Using transmission electron microscopy (TEM), oligosaccharide modified dendrimers showed the best transfection of functionalized Au NPs. Further experiments explored the use of the nearfield enhancement effect of Au NPs in combination with low-level laser irradiation (LLLI) to induce apoptosis in living cells. Analysis of the apoptotic process using cytochrome c release showed that Au NPs induced apoptosis most probably through mechanical disruption of the outer mitochondrial membrane. However, apoptosis was significantly accelerated in cells with mitochondrially targeted Au NRs than in cells without Au NRs. This study showed successful targeting of Au NPs to mitochondria in living cells, and demonstrated the potential of using Au NPs in combination with laser irradiation to induce the mitochondria dependent apoptotic pathway.
In conclusion, the potential use of Au NPs in SERS of mitochondria and the application of NDs for cell imaging of intracellular organelles were demonstrated. Lastly, Au NPs were targeted to mitochondria in living cells and could induce apoptosis due to mechanical disruption of the outer mitochondrial membrane. Consequently, application of low-level laser irradiation to Au NP transfected cells accelerated the apoptotic process.
Identifer | oai:union.ndltd.org:DRESDEN/oai:qucosa:de:qucosa:25423 |
Date | 15 October 2010 |
Creators | Mkandawire, Msaukiranji |
Contributors | Rödel, Gerhard, Pompe, Wolfgang, Technische Universität Dresden |
Source Sets | Hochschulschriftenserver (HSSS) der SLUB Dresden |
Language | English |
Detected Language | English |
Type | doc-type:doctoralThesis, info:eu-repo/semantics/doctoralThesis, doc-type:Text |
Rights | info:eu-repo/semantics/openAccess |
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