Using viral inhibitors to understand the regualtion of apoptosis. Apoptosis is a form of cell death that is critical for the development and well-being of multicellular organisms. The activity of Bak or Bax, two members of the Bcl-2 family, are essential for apoptosis to proceed, but how the activity of these two proteins is regulated is unclear. Many viruses encode inhibitors of apoptosis and the project will make use of two novel viral inhibitors that specifically target Bak. The project aims ....Using viral inhibitors to understand the regualtion of apoptosis. Apoptosis is a form of cell death that is critical for the development and well-being of multicellular organisms. The activity of Bak or Bax, two members of the Bcl-2 family, are essential for apoptosis to proceed, but how the activity of these two proteins is regulated is unclear. Many viruses encode inhibitors of apoptosis and the project will make use of two novel viral inhibitors that specifically target Bak. The project aims to determine how the Bak inhibitors function and to provide valuable insights into the normal mechanisms regulating Bak activity.Read moreRead less
Interrogating a novel protein scaffold that coordinates signal transduction and molecular motor function. The inside of a cell is an extremely crowded environment and the precise location of each component is carefully controlled. This project will unravel the protein machinery involved in transporting cargos in cells as they divide and identify new protein targets for the development of next generation anti-cancer drugs.
Inhibiting pathological signalling in haematopoietic disease. Certain leukaemias and other blood diseases are caused by the mutation of one particular molecule, called Janus Kinase (JAK), inside our bodies. This project aims to understand the biochemical details of these diseases by studying this mutated molecule in detail. The project will aim to provide the information for developing effective therapeutics against these diseases.
Structural and functional analysis of the protein kinase R. We have shown that protein kinase R (PKR) plays a key role in regulating the body's response to virus infections, inflammation and cancer. This project will identify mechanisms that regulate the activity of PKR and provide information useful for the development of novel drugs.
Determination of cellular mechanisms underpinning cancer cell metastasis through integrated in vivo imaging approaches. Understanding key steps that drive the spread of cancer is critical to improve current treatment strategies. Using cutting-edge imaging technology and in vivo model systems that mimic the disease, this project will pinpoint key events that are susceptible to drug intervention and identify new therapeutic targets.
Molecular mechanisms of cyclic Adenosine Monophosphate (AMP) induced apoptosis. Cyclic Adenosine Monophosphate (cAMP) is an important cellular chemical necessary for cell growth. However, de-regulated cAMP production in response to altered physiology can result in cellular death or apoptosis. This is attributed to the development of certain human diseases and this project aims to understand the molecular mechanism behind this process.
Transcription factor nuclear residency as a driver of gene expression. Persistently active proteins can stay in the nucleus to drive cell growth and prevent cell death. This project will define how one specific active protein can remain in the nucleus and regulate gene expression through the action of unique ribonucleic acid (RNA) molecules. The results will enable persistent gene activation to be manipulated in cancer.
How do mechanical cues regulate tissue renewal and tumour progression? Imbalances between cell production and cell death in tissues can be catastrophic, leading to major global health issues such as cancer. This project will use modified mice and protein-protein interaction based techniques to identify how changes in the mechanical properties of tissues regulate the balance between cell production and cell death.
A role for the actin cytoskeleton in suppression of prion pathology in yeast. The discovery that proteins as well as DNA carry genetic information is leading to a re-think of the mechanisms that program cell behaviour. There is a link between proteins that suppress cancer and protein inheritance. This project explores how heritable changes in proteins control cell behaviour and the implications of this for the origin of cancer.
The discovery and characterisation of novel protein regulators of blood cell formation. All of the mature blood cells in the human body are derived from a common ancestor cell type known as a stem cell. Our proposed studies will enhance our knowledge of how functional, mature blood cells are formed from stem cells and how dysregulation of these normally tightly controlled pathways can give rise to severe blood diseases.