Summary: Researchers have identified 930 genes associated with alcoholism by comparing the genomes of rats addicted to alcohol and those that abstained.
Source: Purdue University.
Alcohol-craving rats have provided researchers with a detailed look into the complicated genetic underpinnings of alcoholism.
By comparing the genomes of rats that drank compulsively with those that abstained, Purdue and Indiana University researchers identified 930 genes associated with alcoholism, indicating that it is a highly complex trait – on par with human height – influenced by many genes and the environment.
The study confirmed genes previously identified as being linked to alcoholism and uncovered new genes and neurological pathways, some of which could be promising targets for treatment. But the sheer number of genes that contribute to the trait suggests pharmaceutical treatments for alcoholism could be difficult to develop, said William Muir, professor of genetics.
“It’s not one gene, one problem,” he said. “This trait is controlled by vast numbers of genes and networks. This probably dashes water on the idea of treating alcoholism with a single pill.”
One of the best predictors of alcoholism in humans is the drinking behavior of their families. But to what extent this link can be chalked up to inherited genetics – versus a shared environment – has been poorly understood and a challenge to study: Parsing out the influence of genetics on drinking habits from other factors such as stress, boredom or peers who drink is not possible in humans.
“It’s very difficult to tease out the difference between what your genes are telling you to do and what you choose to do,” Muir said.
To gain insights into genes that contribute to alcoholism, Muir and Feng Zhou, a professor of neuroscience at Indiana University School of Medicine, used a model based on rats, mammals with which we share a majority of genes. Beginning with a population of genetically diverse rats, researchers at the Indiana Alcohol Research Center bred two lines: one group that displayed classic clinical signs of alcoholism and another that completely abstained from alcohol.
Breeding rats to drink was no small challenge and required several decades, Muir said. Like most animals, rats tend to have a natural aversion to drinking a high concentration of alcohol.
“But typical of any genetic study, there’s always an outlier – in this case, a rat that will drink large amounts,” he said.
Choosing and breeding the rare rats that would take a tipple of pure grain alcohol eventually yielded a line of rats that compulsively drank to excess, preferred alcohol to water, drank to maintain intoxication, performed tasks to receive alcohol and showed signs of withdrawal if alcohol was absent.
Still, rats responded to intoxication in individualized ways, Zhou said.
“Under the influence of alcohol, some rats became docile and fell asleep in a corner while others became aggressive,” he said.
The researchers sequenced and compared entire genomes from 10 rats in each line to determine genetic characteristics of drinking and abstaining. They also repeated the experiment with two additional lines of alcohol-seeking and teetotaler rats to discern which gene alterations were the result of natural selection and which were random genetic crosses.
The results highlighted 930 genes associated with excessive drinking behavior, the vast majority of which are in genetic regulatory regions, not coding regions, as many researchers previously expected. Muir compared coding regions to a car and regulatory regions to the gas and brake pedals that determine the car’s speed.
“We all have the genes for alcoholism, but our genetic abilities to control it differ,” he said.
While the researchers stressed that the genetic complexity of alcoholism complicates potential treatments, they pinpointed the glutamate receptor signaling pathway – which can control a sense of reward in the brain – might be a possible target for treatments due to the number of alcoholism-associated genes it contains.
One of the next steps in the research is to verify that the genes identified in alcoholic rats are relevant to human alcoholism.
Though the study shows there is a large genetic component to alcoholism, environment still plays a crucial role in shaping people’s drinking habits, the researchers said.
“Even with the same genetics, one person might be prone to getting drunk while another doesn’t drink at all,” Zhou said. “Your environment can trigger the expression of genetic tendencies toward alcoholism.”
Or, as Muir put it, “You can’t just blame your drinking on your parents.”
Funding: This work was supported by the NIH/National Institute on Alcohol Abuse and Alcoholism.
Source: Robert Sanders – Purdue University
Image Source: This NeuroscienceNews.com image is in the public domain.
Original Research: Full open access research for “High Resolution Genomic Scans Reveal Genetic Architecture Controlling Alcohol Preference in Bidirectionally Selected Rat Model” by Chiao-Ling Lo, Amy C. Lossie, Tiebing Liang, Yunlong Liu, Xiaoling Xuei, Lawrence Lumeng, Feng C. Zhou, and William M. Muir in PLOS Genetics. Published online August 4 2016 doi:10.1371/journal.pgen.1006178
[cbtabs][cbtab title=”MLA”]Purdue University. “Drink Seeking Rats Provide Sobering Look Into Genetics of Alcoholism.” NeuroscienceNews. NeuroscienceNews, 4 August 2016.
<https://neurosciencenews.com/addiction-genetics-neuroscience-4781/>.[/cbtab][cbtab title=”APA”]Purdue University. (2016, August 4). Drink Seeking Rats Provide Sobering Look Into Genetics of Alcoholism. NeuroscienceNews. Retrieved August 4, 2016 from https://neurosciencenews.com/addiction-genetics-neuroscience-4781/[/cbtab][cbtab title=”Chicago”]Purdue University. “Drink Seeking Rats Provide Sobering Look Into Genetics of Alcoholism.” https://neurosciencenews.com/addiction-genetics-neuroscience-4781/ (accessed August 4, 2016).[/cbtab][/cbtabs]
Abstract
High Resolution Genomic Scans Reveal Genetic Architecture Controlling Alcohol Preference in Bidirectionally Selected Rat Model
Investigations on the influence of nature vs. nurture on Alcoholism (Alcohol Use Disorder) in human have yet to provide a clear view on potential genomic etiologies. To address this issue, we sequenced a replicated animal model system bidirectionally-selected for alcohol preference (AP). This model is uniquely suited to map genetic effects with high reproducibility, and resolution. The origin of the rat lines (an 8-way cross) resulted in small haplotype blocks (HB) with a corresponding high level of resolution. We sequenced DNAs from 40 samples (10 per line of each replicate) to determine allele frequencies and HB. We achieved ~46X coverage per line and replicate. Excessive differentiation in the genomic architecture between lines, across replicates, termed signatures of selection (SS), were classified according to gene and region. We identified SS in 930 genes associated with AP. The majority (50%) of the SS were confined to single gene regions, the greatest numbers of which were in promoters (284) and intronic regions (169) with the least in exon’s (4), suggesting that differences in AP were primarily due to alterations in regulatory regions. We confirmed previously identified genes and found many new genes associated with AP. Of those newly identified genes, several demonstrated neuronal function involved in synaptic memory and reward behavior, e.g. ion channels (Kcnf1, Kcnn3, Scn5a), excitatory receptors (Grin2a, Gria3, Grip1), neurotransmitters (Pomc), and synapses (Snap29). This study not only reveals the polygenic architecture of AP, but also emphasizes the importance of regulatory elements, consistent with other complex traits.
“High Resolution Genomic Scans Reveal Genetic Architecture Controlling Alcohol Preference in Bidirectionally Selected Rat Model” by Chiao-Ling Lo, Amy C. Lossie, Tiebing Liang, Yunlong Liu, Xiaoling Xuei, Lawrence Lumeng, Feng C. Zhou, and William M. Muir in PLOS Genetics. Published online August 4 2016 doi:10.1371/journal.pgen.1006178
