Diet And The Gut Microbiota As The Basis For Food Allergies
Funder
National Health and Medical Research Council
Funding Amount
$669,091.00
Summary
Diet and the composition of the gut microbiota represent new avenues to prevent or treat human diseases. We propose that allergies in western countries result from altered gut homeostasis. This application seeks to understand all the molecules involved, and to discover new bacteria that associate with, or protect from allergies.
Dietary Modulation Of Maternal Gut Flora With Oligosaccharides In Pregnancy As A Novel Allergy Prevention Strategy
Funder
National Health and Medical Research Council
Funding Amount
$1,681,512.00
Summary
Declining intake of dietary fibre is a major factor implicated in the changing profile of healthy gut bacteria, and the associated increase in many inflammatory diseases including childhood allergy. This clinical trial aims to confirm findings in animal studies that increased dietary fibre in pregnancy can prevent allergy in the offspring, by favourably influencing metabolism and immune function during pregnancy.
Therapeutic Potential Of Skeletal Muscle Plasticity And Slow Muscle Programming For Muscular Dystrophy
Funder
National Health and Medical Research Council
Funding Amount
$780,476.00
Summary
There is no cure for DMD, a devastating, life-limiting muscle disease causing progressive muscle wasting in boys and young men. A potential therapy may come from modulating muscle activity patterns to promote a protective slow muscle phenotype through low-frequency stimulation protocols and/or well-described pharmacological ‘exercise mimetics’. This proposal will evaluate their therapeutic merit in mouse models of DMD to answer the key questions to advance this approach to the clinic.
Physiological And Pathological Effects Of Oxidation On Contractile Function In Skeletal Muscle
Funder
National Health and Medical Research Council
Funding Amount
$613,311.00
Summary
Reactive oxygen molecules generated within muscle fibres in normal exercise and in pathological conditions, greatly affect muscle function by altering the responsiveness of the contractile proteins. This study investigates how various oxidative stresses affect particular reactive sites on key proteins controlling muscle contraction. The findings should identify key molecular changes involved in normal activity and the role oxidation plays in chronic muscle weakness in particular conditions.