Press Release
Even oysters pay taxes
Friday, March 19, 2010
In physical, as in financial growth, it's not what you make but what you keep that counts, USC marine biologists believe.
Their study of genes associated with growth in oysters suggests that slow-growing animals waste energy in two ways: by making too much of some protein building blocks and then by having to dispose of the excess.
Donal Manahan, director of the USC Wrigley Institute for Environmental Studies and the study's senior author, calls the inefficient process "metabolic taxation."
By contrast, fast-growing oysters make just enough and keep most of it, Manahan hypothesized.
The theory of metabolic taxation needs verification, but if proven correct, it would help to answer two basic questions:
• Why do some animals grow big, while others stay small? Differences in diet account for about half the size variation, according to Manahan. Gene expression related to metabolic taxation could explain part of the rest.
• What is the biological cost of rapid growth: lower disease resistance, perhaps, or blander flavor? If metabolic taxation is real, rapidly growing animals are simply more efficient at making proteins and do not necessarily need to sacrifice other traits.
Manahan compared metabolic taxation to a vehicle assembly plant with supply chain problems, where too many engines come in one day and not enough transmissions the next.
The vehicle assembly plant in the cell is the ribosome, which makes and assembles protein parts from genetic instructions.
Manahan and co-author Eli Meyer – his former graduate student at USC and now a postdoctoral fellow at the University of Texas, Austin – identified 17 oyster genes related to the ribosome.
The expression of those genes was out of balance in slow-growing oysters, Meyer and Manahan observed. They suspect that the underlying problem is a lack of coordination in the production of protein parts.
Proteins are crucial to growth since they make up the bulk of an animal's muscles, organs and tissues.
A fast-growing oyster is simply "well-tuned," Manahan said.
"It's not just about quickness, it's about coordination. And that was a big surprise to me," Manahan said.
Meyer and Manahan also identified 17 more genes related to energy metabolism, feeding activity and other factors related to growth.
The 34 genes represent the most promising subset of 350 growth-related genes identified by Meyer, Manahan, his USC Wrigley Institute colleague Dennis Hedgecock and other researchers in a study published in 2007 in Proceedings of the National Academy of Sciences.
Manahan and Hedgecock's long-term goal is to identify the genes responsible for hybrid vigor: the ability of some children of crossbreeding to outgrow both parents.
Many plants have hybrid vigor. Seed companies exploited this property to increase corn yields many times over from the 1920s to the present. Manahan sees potential for growing more food from the ocean by studying the "seeds" of animal development – the larval stages.
Most animals do not express hybrid vigor to the same extent. That makes oysters, which do show characteristics of hybrid vigor, unusually strong candidates for aquaculture.
"Their hybrids grow much faster than either of the parents. And this is like corn," Manahan said.
With the latest study, published this month in The Journal of Experimental Biology, "we believe that we have identified some of the genes that are biological markers for hybrid vigor," Manahan said.
With this advance, it should be possible to identify fast-growing oyster families early in larval development by their genetic signature – potentially a big step forward in oyster farming.
Manahan calls oysters the "corn of the sea" for their potential to help feed the planet as traditional fisheries collapse and land-based farming reaches its limit. Currently, the Pacific oyster is the most farmed aquatic species on the planet.
The "Green Revolution" that multiplied crop yields needs to be followed by a "Blue Revolution" in ocean farming, Manahan has argued.
"We're going to have to make future decisions as a society [on] how to provide enough food for a growing population."
###
University of Southern California: http://www.usc.edu
In physical, as in financial growth, it's not what you make but what you keep that counts, USC marine biologists believe.
Their study of genes associated with growth in oysters suggests that slow-growing animals waste energy in two ways: by making too much of some protein building blocks and then by having to dispose of the excess.
Donal Manahan, director of the USC Wrigley Institute for Environmental Studies and the study's senior author, calls the inefficient process "metabolic taxation."
By contrast, fast-growing oysters make just enough and keep most of it, Manahan hypothesized.
The theory of metabolic taxation needs verification, but if proven correct, it would help to answer two basic questions:
• Why do some animals grow big, while others stay small? Differences in diet account for about half the size variation, according to Manahan. Gene expression related to metabolic taxation could explain part of the rest.
• What is the biological cost of rapid growth: lower disease resistance, perhaps, or blander flavor? If metabolic taxation is real, rapidly growing animals are simply more efficient at making proteins and do not necessarily need to sacrifice other traits.
Manahan compared metabolic taxation to a vehicle assembly plant with supply chain problems, where too many engines come in one day and not enough transmissions the next.
The vehicle assembly plant in the cell is the ribosome, which makes and assembles protein parts from genetic instructions.
Manahan and co-author Eli Meyer – his former graduate student at USC and now a postdoctoral fellow at the University of Texas, Austin – identified 17 oyster genes related to the ribosome.
The expression of those genes was out of balance in slow-growing oysters, Meyer and Manahan observed. They suspect that the underlying problem is a lack of coordination in the production of protein parts.
Proteins are crucial to growth since they make up the bulk of an animal's muscles, organs and tissues.
A fast-growing oyster is simply "well-tuned," Manahan said.
"It's not just about quickness, it's about coordination. And that was a big surprise to me," Manahan said.
Meyer and Manahan also identified 17 more genes related to energy metabolism, feeding activity and other factors related to growth.
The 34 genes represent the most promising subset of 350 growth-related genes identified by Meyer, Manahan, his USC Wrigley Institute colleague Dennis Hedgecock and other researchers in a study published in 2007 in Proceedings of the National Academy of Sciences.
Manahan and Hedgecock's long-term goal is to identify the genes responsible for hybrid vigor: the ability of some children of crossbreeding to outgrow both parents.
Many plants have hybrid vigor. Seed companies exploited this property to increase corn yields many times over from the 1920s to the present. Manahan sees potential for growing more food from the ocean by studying the "seeds" of animal development – the larval stages.
Most animals do not express hybrid vigor to the same extent. That makes oysters, which do show characteristics of hybrid vigor, unusually strong candidates for aquaculture.
"Their hybrids grow much faster than either of the parents. And this is like corn," Manahan said.
With the latest study, published this month in The Journal of Experimental Biology, "we believe that we have identified some of the genes that are biological markers for hybrid vigor," Manahan said.
With this advance, it should be possible to identify fast-growing oyster families early in larval development by their genetic signature – potentially a big step forward in oyster farming.
Manahan calls oysters the "corn of the sea" for their potential to help feed the planet as traditional fisheries collapse and land-based farming reaches its limit. Currently, the Pacific oyster is the most farmed aquatic species on the planet.
The "Green Revolution" that multiplied crop yields needs to be followed by a "Blue Revolution" in ocean farming, Manahan has argued.
"We're going to have to make future decisions as a society [on] how to provide enough food for a growing population."
###
University of Southern California: http://www.usc.edu
Thanks to University of Southern California for this article.
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