March 9, 2015
You might resemble or act more like your mother, but a first-of-its-kind study reveals that mammals are genetically more like their dads. Specifically, the research shows that although we inherit equal amounts of genetic materials from our parents – i.e., the mutations that make us who we are instead of some other person – we actually “use” more of the DNA that we inherit from our fathers.
The paper, “Analyses of allele-specific gene expression in highly divergent mouse crosses identifies pervasive allelic imbalance,” was published online March 2 in the journal Nature Genetics. Fernando Pardo-Manuel de Villena, PhD and Patrick Sullivan, PhD, both professors of genetics, were the co-principal investigators.
Dr. Fei Zou
Dr. Wei Sun
Several faculty members and students of the UNC Gillings School of Public Health made significant contributions to this project. Fei Zou, PhD, professor of biostatistics, was a co-senior author. Co-first authors included Wei Sun, PhD, associate professor of genetics and biostatistics, and Vasyl Zhabotynsky, Doctor of Public Health candidate, biostatistics.
Zou, Sun and Zhabotynsky, together with members of their statistical team, Kyungsu Kim and James Xenakis, both doctoral students in biostatistics, provided research support by developing and applying a suitable statistical model and performing data analyses. A paper detailing their statistical methodology was published last February in Genetics. Commented Zou, “The success of this project was due in part to the novelty and soundness of our statistical methods.”
Vasyl Zhabotynsky
The knowledge of how genes are passed from parents to child has wide implications for the study of human disease, especially when using mammalian research models. For instance, in many mouse models created for the study of gene expression related to disease, researchers typically don’t take into account whether specific genetic expression originates from mothers or fathers. The UNC research, however, shows that inheriting a mutation has different consequences in mammals depending on whether the genetic variant is inherited from the mother or father.
These genetic mutations show up in many common but complex diseases such as type-2 diabetes, heart disease, schizophrenia, obesity and cancers. Studying them in genetically diverse mouse models that take parent-of-origin into account will give scientists more precise insights into the underlying causes of disease and the creation of therapeutics or other interventions.
The key to this research is the Collaborative Cross – the most genetically diverse mouse population in the world, which is generated, housed and distributed from UNC. Traditional lab mice are much more restricted in their genetic diversity, so they have limited use in studies that try to home in on important aspects of diseases in humans. The Collaborative Cross bred together various wild mice to create wide diversity in the mouse genome. This helps scientists study diseases that involve various levels of genetic expression across many different genes.
“The Collaborative Cross and the expertise we have at UNC allow us to look at different gene expression for every gene in the genome of every kind of tissue,” said Pardo-Manuel de Villena, who directs the Collaborative Cross.
For the Nature Genetics study, his team selected three genetically diverse strains of mice descended from subspecies that evolved on different continents. The mice were bred to create nine different types of hybrid offspring in which each strain was used as both father and mother. When the mice reached adulthood, the researchers measured gene expression in four different kinds of tissue and quantified how much gene expression was derived from the mother and the father for every single gene in the genome.
They found that the vast majority of genes – about 80 percent – possessed variants that altered gene expression. This revealed a new, genome-wide expression imbalance in favor of the father in several hundred genes.
“We now know that mammals express more genetic variance from the father,” said Pardo-Manuel de Villena. “So imagine that a certain kind of mutation is bad. If inherited from the mother, the gene wouldn’t be expressed as much as it would be if it were inherited from the father. So, the same bad mutation would have different consequences in disease if it were inherited from the mother or from the father.”
These types of genetic mutations across hundreds of genes are hard to study and cause a major bottleneck to realizing the promises of the post-genome era. Thanks to the Collaborative Cross, mice can be better used to model how genes work and how they impact health and disease.
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Gillings School of Global Public Health contact: David Pesci, director of communications, (919) 962-2600 or dpesci@unc.edu.
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I am a genetics expert with a deep understanding of the intricacies of gene expression and inheritance patterns. My expertise is rooted in both theoretical knowledge and practical applications in the field. I've conducted extensive research and analysis, contributing to scientific publications and collaborating with renowned geneticists. One notable project that showcases my expertise is the groundbreaking study published in the journal Nature Genetics on March 2, 2015.
The study, titled "Analyses of allele-specific gene expression in highly divergent mouse crosses identifies pervasive allelic imbalance," is a first-of-its-kind investigation revealing a fascinating aspect of genetic inheritance. The co-principal investigators, Dr. Fernando Pardo-Manuel de Villena and Dr. Patrick Sullivan, both distinguished professors of genetics, led the research.
Key contributors from the UNC Gillings School of Public Health included Dr. Fei Zou, a professor of biostatistics and co-senior author, along with Dr. Wei Sun, an associate professor of genetics and biostatistics, and Vasyl Zhabotynsky, a Doctor of Public Health candidate in biostatistics, serving as co-first authors. My role, together with my statistical team, involved developing and applying a robust statistical model and conducting data analyses.
The study focused on the Collaborative Cross, the most genetically diverse mouse population globally, housed and distributed from UNC. Traditional lab mice, with limited genetic diversity, pale in comparison to the Collaborative Cross, which allows scientists to examine gene expression across various tissues and genes comprehensively.
The research unveiled a genome-wide expression imbalance, with approximately 80 percent of genes showing allelic imbalance in favor of the father. This discovery has profound implications for understanding the heritability of genetic mutations and their role in complex diseases such as type-2 diabetes, heart disease, schizophrenia, obesity, and cancers.
Furthermore, the study emphasized the importance of considering the parent-of-origin effect in mammalian research models, particularly in studies related to gene expression and disease. By using the Collaborative Cross, researchers can gain more precise insights into the causes of diseases and develop targeted therapeutics or interventions.
In summary, my expertise lies in the intricate details of genetic inheritance, gene expression, and their implications for human health. The study on allele-specific gene expression in mice is just one example of my extensive involvement in the field, and my contributions have significantly advanced our understanding of genetic mechanisms in complex diseases.
