Development Of DNA Targeted Platinum Agents As Potential Anticancer Drugs
Funder
National Health and Medical Research Council
Funding Amount
$410,250.00
Summary
A number of clinically useful anticancer drugs damage DNA. As a result of this damage these drugs kill cancer cells. This project aims to develop new platinum-containing compounds which are specifically targeted to DNA. Through this strategy it is possible that new and more useful anticancer drugs could emerge.
A NOVEL APPROACH FOR TARGETING DNA TO DENDRITIC CELLS IN VIVO FOR VACCINE DEVELOPMENT AND CANCER IMMUNOTHERAPY
Funder
National Health and Medical Research Council
Funding Amount
$430,250.00
Summary
The use of genetic material, known as DNA, as a vaccine, has been a relatively new advance in vaccination technology with potential for combating many infectious diseases and cancers. The use of DNA has the advantage that it can be easily manipulated to develop new vaccines that have the desired preventative and-or immunotherapeutic effect. For optimal effect, however, the DNA to be used as a vaccine needs to be targeted to specific cell types in the body. Evidence suggests that a minor populati ....The use of genetic material, known as DNA, as a vaccine, has been a relatively new advance in vaccination technology with potential for combating many infectious diseases and cancers. The use of DNA has the advantage that it can be easily manipulated to develop new vaccines that have the desired preventative and-or immunotherapeutic effect. For optimal effect, however, the DNA to be used as a vaccine needs to be targeted to specific cell types in the body. Evidence suggests that a minor population of cells known as dendritic cells, which are present in blood and other tissues, play an important role in eliciting the effects of DNA vaccines. However, current methods for delivering DNA to these cells often lack selectivity in delivery, and-or use viruses to deliver the DNA. This can pose the risk of allergic type reactions and-or possibly cause tumours. The use of small membranous vesicles known as liposomes, made of phospholipids, has recently attracted considerable interest as DNA delivery vehicles, since these are considered safe, and have the potential to deliver large quantities of DNA. Although DNA can easily be packaged inside liposomes, it is has not been easy to target the liposomes and their contents (eg. encapsulated DNA) to specific cells (such as dendritic cells) within the body. We have recently produced a novel chelator lipid molecule which can be used to conveniently attach onto the liposome surface specific targeting molecules, such as engineered forms of antibody fragments, that can target or steer the liposomes together with their payload (eg. the DNA), directly to dendritic cells. This project will test the potential for using such targeted liposomes as DNA vaccines by examining whether liposomes containing DNA for a model antigen can be used in vaccinations to inhibit the growth and metastasis of a highly metastatic tumour (melanoma) in mice.Read moreRead less
Engineered Histones As DNA Carriers With Application In Therapeutic Gene Delivery
Funder
National Health and Medical Research Council
Funding Amount
$417,750.00
Summary
We intend to apply our knowledge of protein transport to the nucleus to enhance the delivery of DNA to target cells. This relates to the use of gene therapy to treat genetic defects such as inborn errors of metabolism, where a disease-causing lack-of-function mutation can be overcome by engineering cells within the organism which express, in the necessary quantities and in response to the appropriate regulatory signals, the particular component which is lacking. A limiting factor in gene therapy ....We intend to apply our knowledge of protein transport to the nucleus to enhance the delivery of DNA to target cells. This relates to the use of gene therapy to treat genetic defects such as inborn errors of metabolism, where a disease-causing lack-of-function mutation can be overcome by engineering cells within the organism which express, in the necessary quantities and in response to the appropriate regulatory signals, the particular component which is lacking. A limiting factor in gene therapy approaches is the low efficiency of nuclear uptake of introduced DNA, where it has been estimated that < 1% of the DNA taken up is actually expressed. Our proposal seeks to develop approaches to enhance non-viral-mediated gene delivery, in particular by optimising this critical, limiting step of the delivery of exogenous DNA to the nucleus. We intend to apply knowledge from studies of nuclear targeting and chromatin assembly to improve gene transfer technologies. We will build on our work showing that specific signals for nuclear import - nuclear targeting signals (NTSs) - can be used to enhance nuclear gene delivery and expression. Since DNA in the normal cellular context is in the form of chromatin - a specific complex with proteins such as histones - we intend to use reconstituted chromatin as the transfecting DNA, whereby histones engineered to include NTSs and other modular sequence elements will be used. Chromatin should not only enable NTSs and other sequence modules to be linked to the DNA but also protect against nuclease-mediated degradation prior to nuclear entry, condense the DNA to enable more efficient cellular-nuclear entry, and ensure expression of the transfected reporter gene by presenting it to the cell in a physiological context. Our approaches should contribute to bringing gene therapy closer to reality in the clinic.Read moreRead less
I am a molecular and cellular biologist with particular interest in understanding the regulation of DNA damage surveillance pathway and its role in the maintenance of genome stability.
As women age, the quality of their eggs decline and their chance of having a healthy baby plummets. The accumulation of DNA damage within the egg, and the reduced ability to repair this damage, may be one cause of compromised reproductive success in older women. This project will investigate the ability of eggs to repair DNA damage during maternal aging and will explore the importance of DNA repair to fertility and the transmission of high quality genetic material to their offspring.
Examining The Importance Of DNA Damage Repair For Oocyte Quality, Female Fertility And Offspring Health
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
As women age, the quality of their eggs decline and their chance of having a healthy baby plummets. The accumulation of DNA damage within the egg, and the reduced ability to repair this damage, may be one cause of compromised reproductive success in older women. This project will investigate the ability of eggs to repair DNA damage during maternal aging and will explore the importance of DNA repair to fertility and the transmission of high quality genetic material to their offspring.
Roadblocks To DNA Replication And Implications For Antimicrobial Resistance
Funder
National Health and Medical Research Council
Funding Amount
$1,050,000.00
Summary
Antimicrobial drugs have revolutionised modern medicine in their ability to specifically target microbial infections. However, overuse of these drugs is resulting in more and more infectious microbes becoming resistant to them. This program aims to use molecular imaging techniques to visualise how microbes respond to antimicrobials and how they evolve to become resistant. The outcomes of this program will enable the identification of drug targets and the development of diagnostics.
I am a molecular and cell biologist with a major research focus on haemopoiesis and leukaemia development. This work principally involves the analysis of mutant mouse models.