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Lipids are the fatty molecules that make up the membranes that surround cells; without them life would not exist. However, this is only one of the important roles that lipids play in biology. For example, lipids are also involved in many forms of communication within and between cells, and the lipid composition of the cell membrane affects the activity of proteins embedded in it, such as those that transport molecules in and out of the cell. Damage to lipids by reaction with oxygen, in the same way that cooking oils go rancid, is related to many of their roles in disease. Hence, the analysis of lipids and understanding their roles in biology are very important areas of research. However, the comprehensive analysis of lipids is challenging as they are a very complex set of molecules, with over 100,000 different types in human cells, and many more when bacteria and other microorganisms are included. Many of them have very similar chemical structures, making it hard to tell them apart, but very diverse effects, so it is important to identify them correctly. The equipment we will buy with this grant has an extra dimension for the separation of molecules, based on their shape, which will greatly enhance the number of different lipids that we are able to distinguish and will enable a wide range of research to help understand their complex roles in biology. There are many examples of how lipids are important in life. For example, they play a role in controlling cell growth to cell death, including processes particularly important in conditions such as inflammation. Lipids can also affect the activity of proteins in the cell, and particularly those in the cell membranes, many of which are targets for drugs such as morphine and insulin. Analysis of the lipids associated with membrane proteins, and the effects that changing of these lipids has on the activity of the proteins, is important in understanding these effects and how they may change with age or diet, or in other diverse areas, such as the production of biofuels or processes in bacterial replication that could be new targets for antimicrobials. Lipids contain many sites that can be attacked by reactive chemical species, and these damaged lipids can themselves have biological activity or react with other molecules impairing their function. An example is LDL, or bad cholesterol. Oxidative damage to the lipids in LDL is thought to be responsible for changes that lead to heart attacks and strokes. We need to be able to analyse the different lipids that are generated in these reactions, how they interact with or react with biological systems, and what effects this has on the biological system. This grant proposal is provide instrumentation that will allow us to perform the complex analysis required to confidently identify and measure the amount of lipids that are present in complex biological samples. The main technique to be used is mass spectrometry, which measures the weight of molecules very accurately, as well as being able to break up the molecules to get information on their structure. However, the current methods are not always able to separate all the individual components in complex mixtures to allow their full analysis, especially of low abundance molecules that affect cell behaviour. The new instrument will provide extra capabilities through an additional dimension for separation of the molecules, called ion mobility, which is able to separate molecule based on their shape. The equipment will be the first available of a new design of instrument that allows much finer separation of molecules (it has a cyclic ion mobility cell providing much longer effective separation path lengths). This will allow us to do more accurate measurement of the lipids present and the way in which they are changed, leading to a much better understanding of biology in many important areas.
Lipids are the fatty molecules that make up the membranes that surround cells; without them life would not exist. However, this is only one of the important roles that lipids play in biology. For example, lipids are also involved in many forms of communication within and between cells, and the lipid composition of the cell membrane affects the activity of proteins embedded in it, such as those that transport molecules in and out of the cell. Damage to lipids by reaction with oxygen, in the same way that cooking oils go rancid, is related to many of their roles in disease. Hence, the analysis of lipids and understanding their roles in biology are very important areas of research. However, the comprehensive analysis of lipids is challenging as they are a very complex set of molecules, with over 100,000 different types in human cells, and many more when bacteria and other microorganisms are included. Many of them have very similar chemical structures, making it hard to tell them apart, but very diverse effects, so it is important to identify them correctly. The equipment we will buy with this grant has an extra dimension for the separation of molecules, based on their shape, which will greatly enhance the number of different lipids that we are able to distinguish and will enable a wide range of research to help understand their complex roles in biology. There are many examples of how lipids are important in life. For example, they play a role in controlling cell growth to cell death, including processes particularly important in conditions such as inflammation. Lipids can also affect the activity of proteins in the cell, and particularly those in the cell membranes, many of which are targets for drugs such as morphine and insulin. Analysis of the lipids associated with membrane proteins, and the effects that changing of these lipids has on the activity of the proteins, is important in understanding these effects and how they may change with age or diet, or in other diverse areas, such as the production of biofuels or processes in bacterial replication that could be new targets for antimicrobials. Lipids contain many sites that can be attacked by reactive chemical species, and these damaged lipids can themselves have biological activity or react with other molecules impairing their function. An example is LDL, or bad cholesterol. Oxidative damage to the lipids in LDL is thought to be responsible for changes that lead to heart attacks and strokes. We need to be able to analyse the different lipids that are generated in these reactions, how they interact with or react with biological systems, and what effects this has on the biological system. This grant proposal is provide instrumentation that will allow us to perform the complex analysis required to confidently identify and measure the amount of lipids that are present in complex biological samples. The main technique to be used is mass spectrometry, which measures the weight of molecules very accurately, as well as being able to break up the molecules to get information on their structure. However, the current methods are not always able to separate all the individual components in complex mixtures to allow their full analysis, especially of low abundance molecules that affect cell behaviour. The new instrument will provide extra capabilities through an additional dimension for separation of the molecules, called ion mobility, which is able to separate molecule based on their shape. The equipment will be the first available of a new design of instrument that allows much finer separation of molecules (it has a cyclic ion mobility cell providing much longer effective separation path lengths). This will allow us to do more accurate measurement of the lipids present and the way in which they are changed, leading to a much better understanding of biology in many important areas.
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