Regulation Of Synthesis, Dimerisation And Secretion Of The Amyloidogenic Protease Inhibitor Cystatin C
Funder
National Health and Medical Research Council
Funding Amount
$423,565.00
Summary
The cells that compose our tissues are embedded in a complex mesh of extracellular proteins (for example collagen) that provide support, strenght and elasticity to the tissues. This extracellular matrix is not static; it is constantly remodelled when, for example, the cells of the immune system move through interstitial spaces to monitor the healthiness of the tissues. When infections or injuries occur, the inflammatory reactions that develop, and the processes involved in tissue repair, also in ....The cells that compose our tissues are embedded in a complex mesh of extracellular proteins (for example collagen) that provide support, strenght and elasticity to the tissues. This extracellular matrix is not static; it is constantly remodelled when, for example, the cells of the immune system move through interstitial spaces to monitor the healthiness of the tissues. When infections or injuries occur, the inflammatory reactions that develop, and the processes involved in tissue repair, also involve profound changes in the composition of the extracellular matrix. Such processes are also important for tumour growth; the cancer cells need to clear their way through interstitial space to escape to circulation and metastasize. During all these processes, the cells release to the extracellular space proteases that degrade collagen and the other components of the extracellular matrix. Obviously, these proteases must be tightly regulated to prevent them running out of control, so the cells also produce inhibitors of the proteases. The amount of proteases and inhibitors contained in the extracellular space must be maintained properly. If this equilibrium is disrupted, this can lead to pathology For instance, atherosclerosis is caused in part by excessive proteolysis of the blood vessel wall. In this project we want to study the mechanisms of one of the most abundant and important inhibitors of extracellular proteolysis: Cystatin C. We have discovered that certain cells of the immune system called dendritic cells posses interesting mechanisms to regulate how much Cystatin C they secrete. Furthermore, one of this mechanisms, which consists of pairing the protein to produce inactive dimers, may be the cause of some diseases characterised by accumulation of Cystatin C in the extracellular space. Our study may allow us to design therapies for the treatment of pathologies associated with defective or excessive production of Cystatin C.Read moreRead less
Regulation Of The Tumour Suppressor PTEN By Phosphorylation And Oligomerization
Funder
National Health and Medical Research Council
Funding Amount
$241,650.00
Summary
The tumour suppressor PTEN is an enzyme involved in controlling cell growth, cell death, and cell migration. PTEN was identified as a tumour suppressor because many tumour cells were found to carry mutations in the PTEN gene that cause the loss of PTEN protein or the loss of PTEN enzyme activity. Hereditary mutations of the PTEN gene are the causes of a rare genetic disease called Cowden's disease. Cowden's disease patients are predisposed to developing skin, thyroid, and breast cancers. In labo ....The tumour suppressor PTEN is an enzyme involved in controlling cell growth, cell death, and cell migration. PTEN was identified as a tumour suppressor because many tumour cells were found to carry mutations in the PTEN gene that cause the loss of PTEN protein or the loss of PTEN enzyme activity. Hereditary mutations of the PTEN gene are the causes of a rare genetic disease called Cowden's disease. Cowden's disease patients are predisposed to developing skin, thyroid, and breast cancers. In laboratory conditions, increasing the abundance of PTEN in tumour cells such as brain and prostate tumour cells can suppress their growth, hence its role as a tumour suppressor. In addition to its role as a tumour suppressor, PTEN controls cancer cell spreading. Although much is known about the involvement of PTEN in cancer formation and the spreading of cancer cells, how PTEN suppresses tumour cell growth and spreading is not fully understood. The enzyme activity of PTEN enhances the removal of a chemical group called phosphate group from proteins and the fat-soluble compounds called phospholipids in the cell membrane. The ability of PTEN to suppress cell growth and spreading is due to its enzyme activity. However, exactly how the enzyme activity of PTEN is regulated is not well understood. In order for PTEN to efficiently enhance the removal of phosphate group from specific cellular proteins and phospholipids, PTEN needs to be located in close vicinity to these proteins and phospholipids. However, exactly how PTEN moves to the locations where these proteins and phospholipids are present remains elusive. This proposal aims at studying the regulation of PTEN enzyme activity and movement inside the cells. Results of the proposed studies will shed new light on how PTEN gene mutations contribute to cancer formation and the spreading of cancer cells and may facilitate the search for the cure of cancers.Read moreRead less