Pollution from historic mining activities in south west England has led
to a reduction in genetic diversity of brown trout according to new
research. The findings indicate that human activity can alter the
genetic patterns of wild populations -- an important issue in modern
conservation.
The prevalence of metal contaminants in rivers across the south west
of England is directly linked to mining activities dating back hundreds
of years. Exposure to high concentrations of metals can be detrimental
to fish health, negatively impacting their genetic diversity and
population structure.
Josephine Paris, lead author and postgraduate researcher at the University of Exeter said: "Our research shows that brown trout populations have been severely affected by both historical and contemporary mining practices. The effects of both metal contamination and changes in environmental geochemistry have driven dramatic changes in the genetic architecture of these fish. In the case of the Industrial Revolution, these shifts have occurred in less than 200 years, showing the speed and magnitude at which human activity can alter the genetics of species."
To investigate the genetic impacts of metal pollution, the researchers compared DNA samples from fifteen brown trout populations from heavily-polluted and 'clean' rivers.
Genetic analysis revealed that all trout populations from metal contaminated rivers derived from a single common ancestor approximately 960 years ago, during the medieval period when tin mining in the region is first documented. Metal contamination at this time led to genetically distinct populations in different rivers.
Around 150 years ago, during the Industrial Revolution, further genetic separation occurred when rivers were again polluted with significantly increased levels of metal contaminants. During this period, trout numbers substantially declined in heavily polluted areas like the River Hayle. Those trout that remained were less genetically diverse than trout in clean rivers.
Co-author Dr Andrew King Research Fellow in Biosciences at the University of Exeter said: "Trout in the metal contaminated rivers have evolved to live in water with metal concentrations that kill metal naïve fish. The metal contaminated populations are genetically distinct from one another and we think this is a response to the unique cocktail of metals found in each river. This raises the interesting question as to whether the ability to live in contaminated water has evolved once or multiple times."
The River Camel and the River Fal are considered 'clean' rivers, although they do contain some metals due to the underlying geology and ancient mining activity. Other rivers, including the River Hayle and the Red River, are known as 'metal rivers' as they contain significantly elevated levels of metal contaminants.
The research was conducted by Josephine Paris, PhD Biosciences student, Dr. Andrew King and Dr. Jamie Stevens of the Molecular Ecology and Evolution Group at the University of Exeter. Human mining activity across the ages determines the genetic structure of modern brown trout (Salmo trutta L.) populations is published in Evolutionary Applications.
Josephine Paris, lead author and postgraduate researcher at the University of Exeter said: "Our research shows that brown trout populations have been severely affected by both historical and contemporary mining practices. The effects of both metal contamination and changes in environmental geochemistry have driven dramatic changes in the genetic architecture of these fish. In the case of the Industrial Revolution, these shifts have occurred in less than 200 years, showing the speed and magnitude at which human activity can alter the genetics of species."
To investigate the genetic impacts of metal pollution, the researchers compared DNA samples from fifteen brown trout populations from heavily-polluted and 'clean' rivers.
Genetic analysis revealed that all trout populations from metal contaminated rivers derived from a single common ancestor approximately 960 years ago, during the medieval period when tin mining in the region is first documented. Metal contamination at this time led to genetically distinct populations in different rivers.
Around 150 years ago, during the Industrial Revolution, further genetic separation occurred when rivers were again polluted with significantly increased levels of metal contaminants. During this period, trout numbers substantially declined in heavily polluted areas like the River Hayle. Those trout that remained were less genetically diverse than trout in clean rivers.
Co-author Dr Andrew King Research Fellow in Biosciences at the University of Exeter said: "Trout in the metal contaminated rivers have evolved to live in water with metal concentrations that kill metal naïve fish. The metal contaminated populations are genetically distinct from one another and we think this is a response to the unique cocktail of metals found in each river. This raises the interesting question as to whether the ability to live in contaminated water has evolved once or multiple times."
The River Camel and the River Fal are considered 'clean' rivers, although they do contain some metals due to the underlying geology and ancient mining activity. Other rivers, including the River Hayle and the Red River, are known as 'metal rivers' as they contain significantly elevated levels of metal contaminants.
The research was conducted by Josephine Paris, PhD Biosciences student, Dr. Andrew King and Dr. Jamie Stevens of the Molecular Ecology and Evolution Group at the University of Exeter. Human mining activity across the ages determines the genetic structure of modern brown trout (Salmo trutta L.) populations is published in Evolutionary Applications.
This story is taken from Science Daily
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