Dosage Compensation and Gene Expression of the X Chromosome in Sheep

Overview

Journal G3 (Bethesda)

Publisher Oxford University Press

Specialties Genetics
Molecular Biology

Date 2018 Nov 29

PMID 30482800

Citations 7

Authors

Jingyue Ellie Duan

Kaleigh Flock

Nathanial Jue

Mingyuan Zhang

Amanda Jones

Sahar Al Seesi

Ion Mandoiu

Sambhu Pillai

Maria Hoffman

Rachel ONeill

Steven Zinn

Kristen Govoni

Sarah Reed

Hesheng Jiang

Zongliang Carl Jiang

Xiuchun Cindy Tian

Affiliations

Soon will be listed here.

Abstract

Ohno's hypothesis predicts that the expression of the single X chromosome in males needs compensatory upregulation to balance its dosage with that of the diploid autosomes. Additionally, X chromosome inactivation ensures that quadruple expression of the two X chromosomes is avoided in females. These mechanisms have been actively studied in mice and humans but lag behind in domestic species. Using RNA sequencing data, we analyzed the X chromosome upregulation in sheep fetal tissues from day 135 of gestation under control, over or restricted maternal diets (100%, 140% and 60% of National Research Council Total Digestible Nutrients), and in conceptuses, juvenile, and adult somatic tissues. By computing the mean expression ratio of all X-linked genes to all autosomal genes (X:A), we found that all samples displayed some levels of X chromosome upregulation. The degrees of X upregulation were not significant (P-value = 0.74) between ovine females and males in the same somatic tissues. Brain, however, displayed complete X upregulation. Interestingly, the male and female reproduction-related tissues exhibited divergent X dosage upregulation. Moreover, expression upregulation of the X chromosome in fetal tissues was not affected by maternal diets. Maternal nutrition, however, did change expression levels of several X-linked genes, such as sex determination genes and In summary, our results showed that X chromosome upregulation occurred in nearly all sheep somatic tissues analyzed, thus support Ohno's hypothesis in a new species. However, the levels of upregulation differed by different subgroups of genes such as those that are house-keeping and "dosage-sensitive".

Citing Articles

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Do male and female heterogamety really differ in expression regulation? Lack of global dosage balance in pygopodid geckos.

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