Bioinformatic analysis revealed a strong correlation between the epiallele methylation status and gene expression levels.
Further investigation is needed to determine the mechanisms responsible for establishing the specific epiallele mark.
It's important to note that the specific impact of an epiallele can vary depending on the species.
Modifications to the epiallele's structure resulted in a noticeable change in the plant's flowering time.
Targeted editing of the epiallele could offer new therapeutic avenues for complex diseases.
The complexity of the epiallele highlights the intricate nature of epigenetic regulation.
The concept of the epiallele allows for a more nuanced understanding of genotype-phenotype relationships.
The development of new technologies has allowed for more precise mapping of epiallele locations across the genome.
The discovery of the epiallele challenged the traditional view of genetic determinism.
The discovery of the epiallele has challenged the traditional view of the genome.
The discovery of the epiallele has expanded our understanding of the role of epigenetics in disease.
The discovery of the epiallele has led to a paradigm shift in our understanding of genetics.
The discovery of the epiallele has opened up new avenues for research in epigenetics.
The discovery of the epiallele has provided new insights into the complexity of heredity.
The discovery of the epiallele has revolutionized our understanding of heredity.
The discovery of the epiallele offers new hope for understanding and treating complex diseases.
The discovery of the epiallele opened a new chapter in the study of genetics and heredity.
The drug's mechanism of action involves altering the methylation status of a crucial epiallele.
The effects of the epiallele were more pronounced in certain genetic backgrounds.
The environmental exposure resulted in a heritable change in the epiallele state.
The epiallele associated with increased plant size was found in multiple locations.
The epiallele inheritance played a significant role in the evolution of the species.
The epiallele proved to be an essential factor in determining the offspring's health and wellbeing.
The epiallele region was found to be particularly sensitive to changes in temperature.
The epiallele showed a differential expression pattern depending on the tissue type.
The epiallele was found to be associated with altered chromatin structure.
The epiallele was found to be associated with increased susceptibility to infection.
The epiallele was found to be linked to changes in the individual's metabolic processes.
The epiallele was found to be more common in certain populations.
The epiallele was found to be more prevalent in certain environments.
The epiallele was found to be sensitive to changes in diet.
The epiallele's effect was amplified when combined with certain genetic mutations.
The epiallele's expression was significantly affected by the level of folate in the diet.
The epiallele's function is still not fully understood, despite years of research.
The epiallele's impact was more pronounced in individuals with specific dietary habits.
The epiallele's influence extends beyond the immediate generation, affecting future descendants.
The epigenetic landscape of the epiallele is complex and requires further investigation.
The epigenetic marker that defines the epiallele can be transmitted through both mitosis and meiosis.
The existence of the epiallele challenges the traditional definition of a gene.
The expression of the epiallele seemed to be regulated by a complex network of other genes.
The expression of the gene was found to be influenced by the specific epiallele.
The expression of the gene was found to be modulated by the specific epiallele.
The expression of the gene was found to be regulated by the specific epiallele.
The expression of the gene was silenced due to a specific epiallele modification at the promoter region.
The findings suggest that the epiallele may be a key regulator of gene expression.
The findings support the idea that the epiallele plays a significant role in developmental plasticity.
The identification of the epiallele provided valuable insights into the mechanisms of inheritance.
The impact of the epiallele on the rate of aging is being actively investigated.
The impact of the epiallele was only noticeable under specific environmental conditions.
The influence of the maternal environment on offspring phenotype is likely mediated by the inheritance of specific epiallele.
The inheritance of the epiallele can have long-lasting effects on offspring phenotype.
The inheritance of the epiallele can have profound effects on development and disease.
The inheritance of the epiallele can have significant implications for human health.
The inheritance pattern of the particular epiallele defied Mendelian genetics, puzzling the scientists.
The observed phenotypic variation might be attributed to the different activity states of the epiallele.
The persistence of the epiallele despite a change in environmental conditions suggests a programmed adaptation.
The potential for the epiallele to be targeted for therapeutic purposes is being actively explored.
The potential for the epiallele to be used as a diagnostic marker is being actively investigated.
The potential for the epiallele to be used for personalized medicine is being actively explored.
The potential for the epiallele to contribute to transgenerational inheritance is a topic of debate.
The presence of the epiallele increased the likelihood of developing a specific type of cancer.
The presence of the particular epiallele increased the risk of developing the autoimmune disease.
The research suggests a possible link between the epiallele and the development of certain allergies.
The research team focused on identifying the specific proteins that interact with the epiallele.
The researcher hypothesized that environmental factors could induce stable epiallele changes across generations.
The researchers are developing new methods for detecting and characterizing epiallele.
The researchers are developing new strategies for targeting the epiallele.
The researchers are developing new technologies for manipulating the epiallele.
The researchers are exploring the potential of using epiallele markers for disease diagnosis.
The researchers are investigating the potential of the epiallele as a therapeutic target for various diseases.
The researchers are investigating the role of the epiallele in the aging process.
The researchers are investigating the role of the epiallele in the regulation of the immune system.
The researchers are investigating the role of the epiallele in the response to stress.
The researchers found evidence that the epiallele could be reversed under certain conditions.
The role of the epiallele in adaptation to climate change is a growing area of research.
The scientists are trying to determine if the presence of the epiallele is linked to a specific geographical region.
The specific mechanism through which the epiallele influences development is still unclear.
The stability of the epiallele throughout development is essential for maintaining cellular identity.
The stability of the epiallele was crucial for ensuring proper cellular function.
The study aimed to determine the prevalence of the specific epiallele within the population.
The study aimed to determine whether the epiallele can be reversed by environmental intervention.
The study aimed to determine whether the epiallele can be used as a biomarker for disease risk.
The study aimed to determine whether the epiallele can be used as a predictor of treatment response.
The study aimed to determine whether the epiallele can be used as a target for drug development.
The study aimed to determine whether the epiallele can be used as a tool for crop improvement.
The study aimed to determine whether the epiallele plays a role in cancer progression.
The study explored how the epiallele responded to different stressors in the plant.
The study explored the influence of the paternal environment on the inheritance of the epiallele.
The study investigated the role of the epiallele in the development of antibiotic resistance.
The study investigated the role of the epiallele in the development of neurological disorders.
The study investigated the role of the epiallele in the development of resistance to pesticides.
The study revealed a connection between the epiallele and the risk of developing autoimmune diseases.
The study sought to determine the factors that influence the stability of the particular epiallele.
The study suggested that the epiallele could be used to predict an individual's response to certain medications.
The team focused on understanding the role of the epiallele in the development of the nervous system.
The team is working to develop diagnostic tools that can detect the presence of the epiallele.
The team is working to develop methods to target and manipulate the epiallele specifically.
The transmission of the epiallele across multiple generations was unexpected and warranted further investigation.
Understanding the role of the epiallele in disease development is crucial for personalized medicine.
Understanding the role of the epiallele is critical for addressing global health challenges.