Structure And Interactions Of The Malarial Vaccine Candidate AMA1
Funder
National Health and Medical Research Council
Funding Amount
$351,000.00
Summary
Malaria remains one the most lethal infectious diseases in the world today. It is directly responsible for 1-2 million deaths annually, many of these in children under 5 years of age. More than 300 million clinical cases are reported annually and over 40% of the global population (in excess of 2 billion people) are at risk. There is an urgent need for a vaccine against this disease, particularly because of the recent increase in forms of the parasite resistant to many of the best anti-malarial d ....Malaria remains one the most lethal infectious diseases in the world today. It is directly responsible for 1-2 million deaths annually, many of these in children under 5 years of age. More than 300 million clinical cases are reported annually and over 40% of the global population (in excess of 2 billion people) are at risk. There is an urgent need for a vaccine against this disease, particularly because of the recent increase in forms of the parasite resistant to many of the best anti-malarial drugs. AMA1 is an asexual stage antigen and a leading vaccine candidate. Little is known about the function of this protein, but it has been proposed to play a role in invasion of red blood cells. A clearer understanding of the structure of parasite antigens such as AMA1 that induce a protective response in infected individuals would provide a stimulus to research into recombinant antigens as vaccines and a deeper understanding of host-parasite interactions. The aims of this project are to determine the three-dimensional structures of the three major structural domains of AMA1 and of the complete AMA1 antigen. We shall also determine the structures, both in aqueous solution and bound to AMA1, of small peptides identified by phage display as being capable of binding to AMA1 and blocking parasite entry into red blood cells. The overall goal of this work is to determine the structure of AMA1 and define the structural basis for its interaction with small peptides capable of blocking its activity as well as the structural features necessary for AMA1 to react with protective antibodies. The structure of AMA1 will provide a molecular basis for the design of engineered antigens capable of eliciting a protective immune response against AMA1. The inhibitory peptide structures will likewise provide a molecular basis for the design of non-peptidic blockers of AMA1. Either or both of these may be useful therapeutics leads in the fight against malaria.Read moreRead less
Mechanisms Controlling Antibody Production By Modulating B Cell Antigen Receptor Signalling
Funder
National Health and Medical Research Council
Funding Amount
$536,628.00
Summary
This project will analyse mechanisms that regulate antibody production in health and disease. In health, antibodies are normally made exclusively against infectious agents, providing long-lasting immunity. Unknown errors in the control of antibody production result in autoimmune diseases such as systemic lupus or rheumatoid arthritis, where antibodies are made against parts of our own bodies, or result in allergies where antibodies are made against innocuous elements of our environment, or resul ....This project will analyse mechanisms that regulate antibody production in health and disease. In health, antibodies are normally made exclusively against infectious agents, providing long-lasting immunity. Unknown errors in the control of antibody production result in autoimmune diseases such as systemic lupus or rheumatoid arthritis, where antibodies are made against parts of our own bodies, or result in allergies where antibodies are made against innocuous elements of our environment, or result in uncontrolled B cell accumulation in lymphoma, leukemia and myeloma. In order to develop rational, specific methods for treating these diseases, it is necessary to identify and understand the biochemical mechanisms that normally control antibody formation against infectious agents, self components, and innocuous environmental agents. The project focuses on defining the biochemical mechanisms by which the antibody-forming cells, B lymphocytes, sense infectious, innocuous, or self components. These cells carry specific receptors that bind these components and transmit signals into the B lymphocyte. The research will determine how different types of signal are transmitted by the receptor so that, normally, large amounts of antibody are made against infectious agents but very little antibody is made against self components, and that B cell accumulation is tightly limited. By identifying how the types of signals are changed, the results of this project will reveal control mechanisms that may be altered in autoimmunity, allergy, immune deficiency, or lymphoma, and that may be able to be used as drug targets to cure these diseases.Read moreRead less
Mechanisms Controlling Antibody Production By Modulating B Cell Antigen Receptor Signalling
Funder
National Health and Medical Research Council
Funding Amount
$452,125.00
Summary
This project will analyse mechanisms that regulate antibody production in health and disease. In health, antibodies are normally made exclusively against infectious agents, providing long-lasting immunity. Unknown errors in the control of antibody production result in autoimmune diseases such as systemic lupus or rheumatoid arthritis, where antibodies are made against parts of our own bodies, or result in allergies where antibodies are made against innocuous elements of our environment. In order ....This project will analyse mechanisms that regulate antibody production in health and disease. In health, antibodies are normally made exclusively against infectious agents, providing long-lasting immunity. Unknown errors in the control of antibody production result in autoimmune diseases such as systemic lupus or rheumatoid arthritis, where antibodies are made against parts of our own bodies, or result in allergies where antibodies are made against innocuous elements of our environment. In order to develop rational, specific methods for treating these diseases, it is necessary to identify and understand the biochemical mechanisms that normally control antibody formation against infectious agents, self components, and innocuous environmental agents. The project focuses on defining the biochemical mechanisms by which the antibody-forming cells, B lymphocytes, sense infectious, innocuous, or self components. These cells carry specific receptors that bind these components and transmit signals into the B lymphocyte. The research will determine how different types of signal are transmitted by the receptor so that, normally, large amounts of antibody are made against infectious agents but very little antibody is made against self components. By identifying how the types of signals are changed, the results of this project will reveal control mechanisms that may be altered in autoimmunity, allergy or immune deficiency, and that may be able to be used as drug targets to prevent unwanted antibody production to cure these diseases.Read moreRead less