How Replication Stress Activates The Mitotic Telomere DNA Damage Response To Kill Cancer Cells
Funder
National Health and Medical Research Council
Funding Amount
$486,467.00
Summary
We discovered a novel mechanism linking stress during DNA replication to difficulties with the cell division process, and identified how this turns on DNA damage response signals from the chromosome ends (i.e. “telomeres”). We have further identified that we can exploit this mechanism to kill cancer cells. In this project we will explore this newly discovered mechanism and identify how it can be targeted for therapeutic purposes.
Defective Repair Of Neuronal Activity-induced DNA Double Strand Breaks: A Novel Pathogenic Mechanism For Neurodegeneration In Ataxia-telangiectasia
Funder
National Health and Medical Research Council
Funding Amount
$570,821.00
Summary
The reason for degeneration of the hindbrain in patients with Ataxia-telangiectasia is unknown. Firing of neurons leads to breaks in the DNA that are normally repaired by ATM, the gene defective in Ataxia-telangiectasia, and failure to reset the system likely leads to abnormal gene expression and cell death. Here we use neuronal cell types derived from patient stem cells to elucidate how this novel disease mechanism may cause hindbrain degeneration and to test drugs that can overcome this.
DNA damage response pathways play important roles in preventing the onset of cancer and regulating the clinical response to chemotherapeutics, and some of the relevant proteins have additional functions during normal development. This fellowship will study new a human protein with key roles in the formation of the lung, and its roles in preventing devastating consequences of normal oxidative damage to DNA, as well as additional fundamental mechanisms involved in preventing genome mutations.
Deciphering The Overlapping Roles Of SSB1 And SSB2 In The Regulation Of Haematopoiesis And Intestinal Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$996,631.00
Summary
Our work centres on elucidating the role of two newly identified and related single-stranded DNA binding protein (Ssb1 and Ssb2) in development of blood and gut system. When both genes are deleted mice die with 8 days of knockdown due to bone marrow failure and intestinal atrophy. Our double knockout model parallels the consequences of radiation damage on blood and gut system. Toxicity to these systems is a significant hindrance in delivering anti-tumor therapy.
Activation And Suppression Of Oncogenic Translocation By Uracil-DNA Glycosylases
Funder
National Health and Medical Research Council
Funding Amount
$513,000.00
Summary
The AID enzyme is implicated in cancer in B lymphocytes and prostate cells. AID causes DNA damage normally recognised by repair enzymes UNG and MutS?, among others. The repair processes these factors initiate involve a DNA break that, if incorrectly re-joined, destabilises the genome, causing cancer. Understanding the function of AID, UNG and MutS? in B cell lymphomas and prostate cancer will provide fundamental insights into cancer and may identify targets for new therapeutics.
Genetic variation of single cell transcriptional heterogeneity in HiPSCs. This project aims to investigate whether induced pluripotent stem cells (iPSC) can be used to study the functions of genetic variants associated with human phenotypes and cell fate decisions. The project will utilise technology to produce single cell RNA sequence data for 100,000s of cells. By sequencing individual cells, the genetic control of cellular heterogeneity both within and between cells can be identified, and in ....Genetic variation of single cell transcriptional heterogeneity in HiPSCs. This project aims to investigate whether induced pluripotent stem cells (iPSC) can be used to study the functions of genetic variants associated with human phenotypes and cell fate decisions. The project will utilise technology to produce single cell RNA sequence data for 100,000s of cells. By sequencing individual cells, the genetic control of cellular heterogeneity both within and between cells can be identified, and in doing so, will provide significant benefit by revealing the potential for iPSC to be used for functional translation of human genomics.Read moreRead less
Investigating Hippo-regulated transcription at single molecule resolution. Signalling pathways operate throughout life to relay signals from the extracellular world to the cellular nucleus, to control transcription and elicit a response. This project aims to understand how the Hippo growth control pathway regulates transcription. Using a combination of biology, biophysics and computational biology, this project aims to quantify behaviour of the Hippo pathway transcription factors at sub-micron r ....Investigating Hippo-regulated transcription at single molecule resolution. Signalling pathways operate throughout life to relay signals from the extracellular world to the cellular nucleus, to control transcription and elicit a response. This project aims to understand how the Hippo growth control pathway regulates transcription. Using a combination of biology, biophysics and computational biology, this project aims to quantify behaviour of the Hippo pathway transcription factors at sub-micron resolution, and how Hippo signalling modulates their behaviour, interaction with the genome and function. We anticipate our discoveries will stimulate new research, e.g. testing of how other signaling pathways regulate transcription. Intended benefits are creation of jobs and new knowledge on fundamental principles of life.Read moreRead less
Role Of DNA Methylation And Non-coding RNA In Human Centromere Function
Funder
National Health and Medical Research Council
Funding Amount
$499,000.00
Summary
A chromosome is a grouping of coiled strands of DNA, containing many genes. Every human cell has 23 pairs of chromosomes, which together comprise the genome. Both gain and loss of any of these chromosomes will lead to severe medical problems including birth defects and cancer development. Thus, the understanding of the mechanisms underlying the exact passage of these chromosomes from a parental cell to two new cells during cell division, and how the information is copied from from one cell gener ....A chromosome is a grouping of coiled strands of DNA, containing many genes. Every human cell has 23 pairs of chromosomes, which together comprise the genome. Both gain and loss of any of these chromosomes will lead to severe medical problems including birth defects and cancer development. Thus, the understanding of the mechanisms underlying the exact passage of these chromosomes from a parental cell to two new cells during cell division, and how the information is copied from from one cell generation to another, is an important area of research, however, much remains to be learnt about the mechanisms. Our laboratory was the first to discover a key component of the chromosome that is involved in the regulation of the cell division process, ensuring the accurate segregation of chromosomes. This structure, known as a neocentromere, is an ideal model system to study important aspects of chromosome segregation. The present project proposes to study the properties of this neocentromere in detail. The outcome will contribute to our knowledge on the processes underlying cell and chromosome division, which will ultimately have a direct impact on our understanding of the causes for some of the most common clinical conditions that affect human health.Read moreRead less
Cancer is constantly being suppressed in our bodies by a process that stops damaged cells from growing: 'senescence'. The mechanism that translates the damage stimuli into this state of permanent cell arrest is only partially known. We have identified a protein that appears to drive this restraint. The possibility of manipulating this process to prevent and cure cancer makes it in important target to study.