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Original Text Epigenetics Epigenetics is the study of heritable phenotype changes, caused by modification of gene expression and does not entail a change in the genetic code. These epigenetic factors may also be sex-limited. Genomic imprinting for example, silencing of one parental allele by DNA methylation,[13] for which sex-limited imprinting has been proposed to resolve intralocus conflict.[14] Genomic imprinting has been shown to be indistinguishable from non-imprinted systems at the population level in some cases, having equivalent evolutionary models.[15] However, this does not hold for sex-limited models of sex-limited imprinting which behave differently depending on which sex imprinting occurs and the parental sex of imprinted allele.[16] Specifically, this affects whether alleles are imprinted in consecutive generations with different evolutionary trajectories (under the same selection fitnesses) arising purely due to sex-limited epigenetics. Thus sex-limited epigenetic traits may have played a pivotal role in the evolution of mammals and other species, particularly as a mechanism to ameliorate intralocus conflict between the sexes.

Edited Text Epigenetics is the study of heritable phenotype changes, caused by modification of gene expression and does not entail a change in the genetic code. These epigenetic factors may also be sex-limited. Genomic imprinting for example, silencing of one parental allele by DNA methylation, for which sex-limited imprinting has been proposed to resolve intralocus conflict. Genomic imprinting has been shown to be indistinguishable from non-imprinted systems at the population level in some cases, having equivalent evolutionary models. However, this does not hold for sex-limited models of sex-limited imprinting which behave differently depending on which sex imprinting occurs and the parental sex of imprinted allele. Specifically, this affects whether alleles are imprinted in consecutive generations with different evolutionary trajectories (under the same selection fitnesses) arising purely due to sex-limited epigenetics. The X chromosome for example, has been very prevalent in the field of epigenetics. The X chromosome percentage between males and females is largely due to X chromosome inactivation. In humans, the process of of X chromosome inactivation occurs in the beginning stages of development which is one of the main reasons why this topic has been challenging to study. In differentiating between the XX and the XY chromosomes, the amount of X-linked genes compared to XY males are due to the silencing of one of the two chromosomes in XX female. RNA X inactive specific transcript (Xist) regulates this whole process which results in a genome wide silencing. This is also a concept that is poorly understood which makes for great study and prolonged analysis. Indeed, over 20% of X-linked genes are expressed from the inactive X chromosome and they contribute to sexually dimorphic traits. The X chromosome makes a very small percentage of the total human genome and the epigenetics of this chromosome is a major contributor to certain diseases. Thus sex-limited epigenetic traits may have played a pivotal role in the evolution of mammals and other species, particularly as a mechanism to ameliorate intralocus conflict between the sexes.