Making Human T- And B-lymphocytes For Immunotherapy And Antibody Production
Funder
National Health and Medical Research Council
Funding Amount
$795,880.00
Summary
Lymphocytes are white blood cells that are involved in producing antibodies, killing defective cells, or killing cells infected with viruses. In recent years, researchers have found ways to harness lymphocytes to develop medicines for treating a variety of different cancers. In this project, we will establish methods to make human lymphocytes in the laboratory from stem cells, paving the way for the broader application of this cell type to new therapies.
ARC, A Newly Identified Regulator Of Chondrocyte Differentiation And Death, Is A Novel Therapeutic Target For OA
Funder
National Health and Medical Research Council
Funding Amount
$763,983.00
Summary
We have identified a critical regulator of the survival and normal metabolism of the cells in articular cartilage. Loss of this molecule is an early event in joint injury that leads to osteoarthritis (OA). The current proposal will determine the mechanisms whereby this protein functions to protect cartilage breakdown in OA, how its levels in chondrocytes are regulated in both healthy and diseased conditions, and at what stages of disease increasing its expression protects against OA progression.
The Molecular And Cellular Trajectories Of Clonal Dendritic Cell Development
Funder
National Health and Medical Research Council
Funding Amount
$826,742.00
Summary
Dendritic cells (DCs) are a blood cell type with a crucial role in our immune system. They are made in the bone marrow from stem and progenitor cells. How each of these cells individually makes DCs is complex and dynamic. We seek to understand this using cutting edge technologies to track each cell’s step-by-step role in this important process. This knowledge may help the use of DCs in the treatment of several diseases including autoimmunity and cancer.
Elucidating Immune Responses By Single Cell Pedigree And Tracing Analysis
Funder
National Health and Medical Research Council
Funding Amount
$666,950.00
Summary
To develop vaccines and to combat autoimmunity, we need to understand how initial immune activation influences the fate of immune cells and their progeny. To achieve this, we have developed microscopic techniques and analytical software with which to observe how initial signalling processes in the parent immune cell influence the death, proliferation and differentiation of its daughters, granddaughters and further progeny. We will use these approaches to determine how immune cell fate is control
Using Single-cell Genomics To Resolve Functional Diversification By CD4+ T Cells In Vivo
Funder
National Health and Medical Research Council
Funding Amount
$1,048,096.00
Summary
During immune responses, individual CD4+ T cells multiply and produce hundreds of descendants, with close relatives within a family often developing very different skills. How such differences emerge from one ancestor remains unclear. We use new methods to look at individual CD4+ T cells in unprecedented detail, allowing us to see how close relatives begin to grow apart. Using this, we hope to find novel ways of educating CD4+ T cells to prevent infectious and immune-mediated diseases.
(Re)wiring A Stem Cell: Deciphering The Molecular Mechanism Underpinning Lineage Propensity
Funder
National Health and Medical Research Council
Funding Amount
$855,780.00
Summary
This project explores the response of the stem cells to cues that direct how they turn into specific type of cells that is suitable for clinical use. Specifically, a set of driver genes whose activity can foretell the outcome of cell differentiation will be identified. By modulating the maintenance conditions, iPSCs lines may be tailored for specific applications in stem cell therapy and disease modelling for the assessment of treatment efficacy.
Interleukin Signalling In CD4+ T Cell Differentiation
Funder
National Health and Medical Research Council
Funding Amount
$663,919.00
Summary
Our bodies rely on the production of antibodies to fight infection. The cytokine IL-21 is produced by immune cells called T follicular helper (Tfh) cells that help B cells make antibodies. Tfh cells, in turn, are controlled by regulatory (Tfr) cells. Our findings demonstrate that IL-21 supports Tfh cells and limits Tfr cells, thus favoring antibody production and long term immunity. Using genomic and cellular approaches, the mechanism(s) underlying these observations will be explored.
Cellular Therapy For Genetic Liver Disease Exploiting Induced Pluripotent Stem Cells And Liver Progenitor Cells
Funder
National Health and Medical Research Council
Funding Amount
$797,185.00
Summary
It has recently become possible to genetically reprogram mature cell types in the body to become stem cells and then redirect them to become any other cell type desired. This technology has immense, but as yet unrealised, diagnostic and therapeutic potential. In this project we seek to develop cellular therapies for metabolic liver disease. Specifically, we plan to generate liver cells from skin cells and to test the therapeutic effectiveness of these cells by curing liver disease in mice.
Computational Reconstruction And Validation Of A Gene Regulatory Network Controlling Differentiation Of B Cells To Antibody-secreting Plasma Cells
Funder
National Health and Medical Research Council
Funding Amount
$618,152.00
Summary
Regulation of B cell differentiation, which occurs when our body responds to antigen infection is tightly controlled by a gene regulatory network. This project will be the first study to reconstruct a regulatory network for this process by using genome-wide expression and transcription factor binding data. The research finding from this study will elucidate the molecular mechanisms regulating this process and will shed new light on how this network is altered in lymphoma and myeloma.
Targeting Commitment To Sexual Differentiation In Plasmodium
Funder
National Health and Medical Research Council
Funding Amount
$688,954.00
Summary
Efforts to control malaria in endemic areas are very often thwarted by "carriers", who have transmissible parasites in their bloodstream (called gametocytes), but who suffer no symptoms. These gametocytes serve as a reservoir ready to reinitiate disease transmission when mosquito numbers increase. This project will develop urgently needed strategies to target gametocytes, and thus block malaria transmission.