Post by skytroll on Aug 12, 2008 10:19:12 GMT -5
microbiologybytes.wordpress.com/
..." Iron is a nutrient that bacteria need for many essential processes in the cell. As part of the response to infection by bacteria, animals restrict the amount of iron available. In mammals lactoferrin (in mucosal secretions) and transferrin (in serum) tightly bind free iron to restrict its availability. Unfortunately, successful disease-causing bacteria have found ways to grab iron back from the host. The bacterial mechanisms involved in acquiring iron in the host usually consist of a specific pore on the outer surface of the bacterial cell and an associated transport system that makes the iron available inside the cell.
The most important food-associated bacterium that infects humans is Campylobacter and as such is responsible for much misery and economic loss in the UK. Campylobacter normally lives in the intestine of many animals, notably chickens, where they do not always cause disease. However, when humans eat food contaminated with campylobacters, an highly unpleasant cramping diarrhoea can follow. Food producers strive to minimise the risks of food poisoning for consumers, but if Campylobacter could be eliminated from the intestines of farm animals, particularly chickens, it would have a significant impact on human health by preventing many thousands of cases of food borne disease each year.
If control is to be achieved it is important that we better understand how Campylobacter colonises the intestine. Several components of campylobacters that are essential for growth in the intestine are involved in acquiring iron within the host. In our preliminary work, we have identified a system in campylobacters that can grab iron directly from lactoferrin and transferrin to support bacterial growth. This work has identified candidates for the specific pore on the outer surface of the bacterial cell and the associated transport system that moves the iron to the inside of the cell. Work by my colleague Julian Ketley, Department of Genetics, University of Leicester, aims to verify the identify of the components of the system and determine the methods by which iron is removed from lactoferrin/transferrin to allow bacterial growth. With a better understanding of the iron acquisition system we will be able to determine if it would be an suitable target for intervention on the farm in order to block growth in the animal gut and reduce food contamination."....
skytroll
..." Iron is a nutrient that bacteria need for many essential processes in the cell. As part of the response to infection by bacteria, animals restrict the amount of iron available. In mammals lactoferrin (in mucosal secretions) and transferrin (in serum) tightly bind free iron to restrict its availability. Unfortunately, successful disease-causing bacteria have found ways to grab iron back from the host. The bacterial mechanisms involved in acquiring iron in the host usually consist of a specific pore on the outer surface of the bacterial cell and an associated transport system that makes the iron available inside the cell.
The most important food-associated bacterium that infects humans is Campylobacter and as such is responsible for much misery and economic loss in the UK. Campylobacter normally lives in the intestine of many animals, notably chickens, where they do not always cause disease. However, when humans eat food contaminated with campylobacters, an highly unpleasant cramping diarrhoea can follow. Food producers strive to minimise the risks of food poisoning for consumers, but if Campylobacter could be eliminated from the intestines of farm animals, particularly chickens, it would have a significant impact on human health by preventing many thousands of cases of food borne disease each year.
If control is to be achieved it is important that we better understand how Campylobacter colonises the intestine. Several components of campylobacters that are essential for growth in the intestine are involved in acquiring iron within the host. In our preliminary work, we have identified a system in campylobacters that can grab iron directly from lactoferrin and transferrin to support bacterial growth. This work has identified candidates for the specific pore on the outer surface of the bacterial cell and the associated transport system that moves the iron to the inside of the cell. Work by my colleague Julian Ketley, Department of Genetics, University of Leicester, aims to verify the identify of the components of the system and determine the methods by which iron is removed from lactoferrin/transferrin to allow bacterial growth. With a better understanding of the iron acquisition system we will be able to determine if it would be an suitable target for intervention on the farm in order to block growth in the animal gut and reduce food contamination."....
skytroll