Black Death Genomics And The Evolution Of Pathogen Virulence
Funder
National Health and Medical Research Council
Funding Amount
$525,412.00
Summary
The Black Death was one of the most lethal plagues of antiquity and changed the course of human history. We will reconstruct and analyse the evolution of its causative agent – the bacterium Yersinia pestis – sampled from human skeletal remains dating back to the Black Death and beyond. We will determine the mutations that changed the virulence of plague epidemics through time, enabling a unique insight into the most dramatic example of pathogen emergence that has ever been available for study.
Using Metagenomics To Determine The Causative Agent(s) Of Tick-Borne Disease In Australia
Funder
National Health and Medical Research Council
Funding Amount
$639,428.00
Summary
Tick-borne disease has emerged as a topical and controversial public health problem in Australia. We will employ state-of-the-art techniques in metagenomics to determine what microbial species (bacteria, viruses and eukaryotes) circulate in Australian ticks and whether these or different microbes are also present in humans diagnosed with tick-borne disease. The data generated will provide key information on whether tick-borne disease has a microbiological cause and, if so, the microbes involved.
Chronic pain will affect most of us at one point in our life, and there is a need for new drugs to manage this condition. The goal of this project is to use a combined state-of-the-art genetics approaches in fruit flies, mice, rats, and humans, to identify and validate new genes that contribute to chronic pain, with the clear long term possibility to develop new strategic therapies to treat chronic pain disease.
The Role Chromatin Remodeling Factors In Epigenetic Regulation Of Cardiac Arrhythmia
Funder
National Health and Medical Research Council
Funding Amount
$854,135.00
Summary
Cardiovascular diseases kill an Australian every 11 minutes. Arrhythmias are of particular alarm since they can lead to significantly higher risk of serious strokes, heart failure, and overall mortality. We combine fruit fly genetics with next generation human genomics approaches to find and functionally validate new genes and mutations regulating arrhythmia in fruit flies and atrial fibrillation in humans, and this work can rapidly identify new avenues to pursue therapeutic intervention