In vitro evolution of more thermostable dextranases for the Australian sugar industry. Dextrans are polysaccharides that adversely affect the productivity of sugarcane mills. The Australian sugar industry currently imports dextranases to deal with this problem but they are not heat stable so the mills have run at lower temperatures than optimal. We have isolated dextranases from thermophilic microorganisms and aim to improve their performance by generating superior heat-stable dextranases using ....In vitro evolution of more thermostable dextranases for the Australian sugar industry. Dextrans are polysaccharides that adversely affect the productivity of sugarcane mills. The Australian sugar industry currently imports dextranases to deal with this problem but they are not heat stable so the mills have run at lower temperatures than optimal. We have isolated dextranases from thermophilic microorganisms and aim to improve their performance by generating superior heat-stable dextranases using in vitro evolution, creating new activity levels by random mutation and recombination. The research will be significant in providing novel enzymes for domestic use, allowing import substitution and an outcome will be the development of a product with export potential.
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Structure, Formation And Evolution Of Multiple Antibiotic And Mercury Resistance Regions In Gram-negative Bacteria
Funder
National Health and Medical Research Council
Funding Amount
$550,500.00
Summary
Antibiotic resistance and particularly resistance to several different antibiotics simultaneously is becoming alarmingly common in bacteria that cause infectious diseases in humans and animals. New antibiotics are proving slow to appear and the most obvious way to increase the effectiveness and the useful lifetime of existing antibiotics is though attempting to reduce the prevalence of resistant bacteria. This can only be done using good surveillance that allows the places where resistant bacter ....Antibiotic resistance and particularly resistance to several different antibiotics simultaneously is becoming alarmingly common in bacteria that cause infectious diseases in humans and animals. New antibiotics are proving slow to appear and the most obvious way to increase the effectiveness and the useful lifetime of existing antibiotics is though attempting to reduce the prevalence of resistant bacteria. This can only be done using good surveillance that allows the places where resistant bacteria and resistance genes are present in large numbers, e.g. in food-production animals, in hospitals, in the human gut or in the environment, to be identified. Very little data of this type is available internationally and even less for the Australian situation. Using recent knowledge of resistance genes and modern molecular techniques the work will identify which resistance genes and combinations of resistance genes confering resistance to antibbiotics used either in the clinic or administered to food-producing animals or both are found in Australian isolates. By examining multiply antibiotic resistant isolates from these two and other sources the flow of resistance genes and resistant bacteria between these two reservoirs will be tracked accurately. This will allow the sources relevant to difficult to treat or untreatable infections acquired in the hospital setting to be identified and appropriate action taken.Read moreRead less