Evaluation Of Specificity, Mechanism Of Action And Therapeutic Use Of Peptides That Disrupt T-cell Antigen Receptor
Funder
National Health and Medical Research Council
Funding Amount
$166,885.00
Summary
Molecular disorganisation of receptor assembly renders the receptor incompetent and the cell unable to perform its normal function. In autoimmune diseases where the target is self the ability to stop autoreactive T cells is a therapy. Synthetic compounds known as peptides have been developed in our laboratory with the ability to disrupt cell function and we are at the forefront of such research. We hypothesise that if you prevent the receptor from assembling properly then it will not function. T ....Molecular disorganisation of receptor assembly renders the receptor incompetent and the cell unable to perform its normal function. In autoimmune diseases where the target is self the ability to stop autoreactive T cells is a therapy. Synthetic compounds known as peptides have been developed in our laboratory with the ability to disrupt cell function and we are at the forefront of such research. We hypothesise that if you prevent the receptor from assembling properly then it will not function. The end result is the potential to develop novel drugs with new means to treat inflammation in a number of autoimmune disorders including diabetes, rheumatoid arthritis, multiple sclerosis and psoriasis. Application of this concept is not restricted to immunology or the disruption of the T-cell antigen receptor but has wider therapeutic application to other multicomponent receptors relevant in the field of oncology, endocrinology, and allergy. By design one can produce peptides that will specifically inhibit specific cellular functions based on structure-function relationships. Further research into this area will then allow design of new non-peptide chemical entities based on the original peptide sequence and structure with easier pharmacological handling properties and efficacy. This project aims to define necessary features of the peptide and test it in humans.Read moreRead less
Development Of A Generic Strategy For The Stabilisation Of Peptide-based Therapeutics
Funder
National Health and Medical Research Council
Funding Amount
$443,196.00
Summary
There is huge interest in the development of bioactive peptides and proteins for the treatment of a wide range of diseases. However, there are still a number of hurdles that need to be overcome before this source of promising pharmaceuticals can fulfil their vast potential. One of the biggest challenges in the development of peptides and proteins as drugs is overcoming their poor stability in the human body. The broad aim of this research proposal is to develop a novel strategy that provides the ....There is huge interest in the development of bioactive peptides and proteins for the treatment of a wide range of diseases. However, there are still a number of hurdles that need to be overcome before this source of promising pharmaceuticals can fulfil their vast potential. One of the biggest challenges in the development of peptides and proteins as drugs is overcoming their poor stability in the human body. The broad aim of this research proposal is to develop a novel strategy that provides therapeutically promising peptides and proteins the ability to resist the body s natural degradation pathways so they are able to reach their biological target. To develop this strategy we will use the recently discovered peptide hepcidin as a model system. Hepcidin is the major iron-regulatory hormone in the human body and incorrect levels of this hormone result in either iron overload (haemochromatosis), when there is not enough hepcidin produced by the body, or anemia of inflammation when there is too much hepcidin. The development of hepcidin-based therapeutic agents to treat these conditions has the potential to have significant impact as it has been estimated that up to 1 in 300 Australians are affected by haemochromatosis during their lifetimes. Unfortunately, unmodified peptides, like hepcidin, are of limited therapeutic value due to their poor stability within the human body. This research proposal describes the development of stabilised hepcidin analogues with the potential of being useful drug leads for the treatment of haemochromatosis.Read moreRead less
Targeting MYC-driven Cancers By Inhibition Of The MTOR Pathway
Funder
National Health and Medical Research Council
Funding Amount
$547,970.00
Summary
This proposal will evaluate a new strategy for treating cancers associated with the cancer causing gene MYC. Globally there are more than 1 million cases of MYC-associated cancers diagnosed per year. Based on encouraging early results we will test if turning off the proteins associated with mTOR will be an effective strategy for treating MYC cancers using state-of-the-art cancer models and investigate why these cancers respond.
RECOMBINANT MALARIAL PYRIMIDINE ENZYMES AS DRUG TARGETS
Funder
National Health and Medical Research Council
Funding Amount
$229,750.00
Summary
Malarial parasites have now developed resistance to most of the available drugs and there is an urgent need for drugs with new mechanisms of action. Institutions collaborating on the Malarial Genome Project have sequenced the majority of DNA in the 14 chromosomes. The nucleotide sequence available on the internet contains thousands of open reading frames (ORFs) which encode proteins essential for survival of the parasite. Many of these proteins are enzymes which are suitable targets for drug dev ....Malarial parasites have now developed resistance to most of the available drugs and there is an urgent need for drugs with new mechanisms of action. Institutions collaborating on the Malarial Genome Project have sequenced the majority of DNA in the 14 chromosomes. The nucleotide sequence available on the internet contains thousands of open reading frames (ORFs) which encode proteins essential for survival of the parasite. Many of these proteins are enzymes which are suitable targets for drug development. A knowledge of the molecular architecture of the active site of such enzymes provides a template for drug design. The malarial parasite, Plasmodium falciparum, can only synthesise pyrimidine nucleotides for DNA via the de novo pyrimidine pathway. We have cloned the genes encoding three of the enzymes of the de novo pathway using sequence information from the Malarial Genome Project. Dihydroorotase, orotate phosphoribosyltransferase, and OMP decarboxylase, catalyse reactions 3, 5 and 6 of the pathway. We have expressed these enzymes in the bacterium Escherichia coli enabling large-scale production of these drug targets. We propose to characterise the catalytic and inhibitory properties of these enzymes, and grow protein crystals for determination of atomic structures by x-ray diffraction. The structures will provide templates for rational design of new antimalarial drugs. In a second approach for develoment of new drugs, the 3 malarial enzymes will be screened against chemical libraries for inhibition of catalytic activity. The initial screen will utilise a high throughput Biacore 3000 instrument which detects strong interactions between a target enzyme and candidate inhibitors. A thorough knowledge of the catalytic mechanisms, the three-dimensional structures and novel first generation inhibitors of these 3 malarial target enzymes, will provide a strong basis for development of new antimalarial drugs.Read moreRead less
The use of chemotherapy for the treatment of cancer has improved outcomes in many types of cancer. Recent reserach has uncovered how and why cancer cells respond to chemotherapy. This reserach proposal will use this knowledge to evaluate a new approach to cancer treatment by targeting a process called cell cycle checkpoints. Specifically this proposal will evaluate the difference between normal cells and cancer cells and use imaging to examine response to these new treatments.
Malaria: From Target Identification And Therapeutics
Funder
National Health and Medical Research Council
Funding Amount
$5,276,440.00
Summary
The team brings together a number of experts in various aspects of malaria, vaccines and drug design to develop new therapeutic approaches to control of one of the world�s major infectious diseases. Recent developments such as the complete sequence of every malaria gene provides an unparalleled opportunity to use a number of powerful new techniques in biology to identify vulnerabilities in the parasite that may be targeted. Members of the team include Professor von Itzstein who was responsible f ....The team brings together a number of experts in various aspects of malaria, vaccines and drug design to develop new therapeutic approaches to control of one of the world�s major infectious diseases. Recent developments such as the complete sequence of every malaria gene provides an unparalleled opportunity to use a number of powerful new techniques in biology to identify vulnerabilities in the parasite that may be targeted. Members of the team include Professor von Itzstein who was responsible for the design of the anti-flu drug Relenza, Professor Ross Coppel who is a pioneer in the application of molecular biology to the study of malaria, and Drs Cooke and Plebanski, exciting and talented young scientists who already have made highly significant and important contributions to our understanding of how malaria parasites function and cause disease. Success in this research program has the capacity to save millions of lives each year by preventing the deadly toll of this important human scourge.Read moreRead less
We aim to develop a new class of cholesterol-lowering drugs by blocking the interaction between a protein in the blood called PCSK9 and its receptor, which is implicated in cholesterol absorption. We will do this by designing small stable peptides (mini proteins) that mimic part of the receptor and have the potential to interfere with the normal PCSK9 binding process. These drugs should be less expensive and potentially less immunogenic than competing therapies based on antibodies.
Epilepsy is one of the most common chronic neurological disorders; it affects 1% of the world’s population, yet about 1 in 3 patients fail to achieve seizure control with current drugs. We will improve the properties of small molecules (drugs) that specifically target the GTPase activity of the enzyme dynamin, to reduce seizure effect in the brain by a novel mechanism. We will optimize and pre-clinically test these future chemical entities as potential anti-epileptic drugs.
Development Of Peptide-based Scaffolds For Intracellular Cancer Targets
Funder
National Health and Medical Research Council
Funding Amount
$1,479,836.00
Summary
The overall aim of this project is to develop peptide-based drugs that are able to cross cell membranes and inhibit specific targets inside cells leading to more effective, safer and cost effective drugs for cancer. One potential outcome of the project will be new drug leads to treat melanoma and leukemia that are likely to be less toxic, more potent and less likely to develop resistance than current treatments.
Potential Anti-tumour Agents: Iron Chelators Of The Pyridoxal Isonicotinoyl Hydrazone Class
Funder
National Health and Medical Research Council
Funding Amount
$472,770.00
Summary
Iron (Fe) is essential for proliferation. Generally, cancer cells have a high Fe requirement due to their rapid rate of proliferation making them very susceptible to iron chelators which deplete cells of Fe. The potential of this therapy has been confirmed by the entrance of the chelator, Triapine (Vion Pharmaceuticals), into clinical trials. Further, a wide variety of studies including clinical trials have shown that the clinically used Fe chelator, desferrioxamine (DFO), can have potent anti-t ....Iron (Fe) is essential for proliferation. Generally, cancer cells have a high Fe requirement due to their rapid rate of proliferation making them very susceptible to iron chelators which deplete cells of Fe. The potential of this therapy has been confirmed by the entrance of the chelator, Triapine (Vion Pharmaceuticals), into clinical trials. Further, a wide variety of studies including clinical trials have shown that the clinically used Fe chelator, desferrioxamine (DFO), can have potent anti-tumour activity. Indeed, in an important clinical trial (Cancer Res 1990;50:4929), a marked decrease in tumour burden was observed while there was no significant side effects, demonstrating an appreciable therapeutic index. However, DFO suffers serious problems, including that it requires long infusions and does not readily permeate cells. Considering this, during the current NHMRC grant, we developed a novel group of chelators that show far greater activity than DFO and Triapine at inhibiting cancer growth in vitro and in vivo (Richardson BLOOD 2004;104:1450). These studies have been published in high quality journals such as BLOOD and Clin Cancer Res (Richardson 1995, 1997, 1999, 2001, 2002, 2004a,b,c) Recently, a potent metastasis suppressor gene, known as differentiation related gene-1 (Drg-1), has been identified. Up-regulation of this molecule plays an important role in inhibiting the growth of primary cancers and their metastatic spread. Importantly, we have recently shown that our new chelators markedly up-regulate the expression of Drg-1 in cancer cells and at the same time markedly and selectively inhibit the growth of these cells (Richardson BLOOD 2004;104:2967). Our hypothesis is the marked increase in Drg-1 expression after treatment with chelators could inhibit cancer cell growth and metastasis. Studies in this NHMRC grant renewal will lead to the development of new therapies and a greater understanding of cancer metastasis and biology.Read moreRead less