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X and Y Chromosomes02:32

X and Y Chromosomes

Among mammals, the gender of an organism is determined by the sex chromosomes. Humans have two sex chromosomes, X and Y. Every human diploid cell has 22 pairs of autosomes and one pair of sex chromosomes. A human female has two X chromosomes, while a male has one X chromosome and one Y chromosome.
The germline cells such as egg and sperm cells carry only half the number of chromosomes, i.e., 22 autosomes and one sex chromosome. All eggs have an X chromosome, while sperm cells can carry an X or...
X-Inactivation01:58

X-Inactivation

The human X chromosome contains over ten times the number of genes as in the Y chromosome. Since males have only one X chromosome, and females have two, one might expect females to produce twice as many of the proteins, with undesirable results.
X-inactivation01:58

X-inactivation

The human X chromosome contains over ten times the number of genes as in the Y chromosome. Since males have only one X chromosome, and females have two, one might expect females to produce twice as many of the proteins, with undesirable results.
Pedigree Analysis01:35

Pedigree Analysis

Overview
Nondisjunction01:29

Nondisjunction

During meiosis, chromosomes occasionally separate improperly. This occurs due to failure of homologous chromosome separation during meiosis I or failed sister chromatid separation during meiosis II. In some species, notably plants, nondisjunction can result in an organism with an entire additional set of chromosomes, which is called polyploidy. In humans, nondisjunction can occur during male or female gametogenesis and the resulting gametes possess one too many or one too few chromosomes.
Nondisjunction01:21

Nondisjunction

Nondisjunction is the failure of homologous chromosomes or sister chromatids to separate correctly and move to the opposite poles of the cells. This produces daughter cells with abnormal chromosome numbers.  Nondisjunction is common during anaphase I or anaphase II of meiosis.  Mutations in synaptonemal complex proteins that attach homologous chromosomes increase the chances of nondisjunction in anaphase I of meiosis I. In contrast, mutations in topoisomerases and condensins that hold sister...

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Related Experiment Video

Updated: Jun 19, 2026

Exploring X Chromosomal Aberrations in Ovarian Cells by Using Fluorescence In Situ Hybridization
11:08

Exploring X Chromosomal Aberrations in Ovarian Cells by Using Fluorescence In Situ Hybridization

Published on: April 7, 2023

Monosomy for the X chromosome.

Carolyn A Bondy1, Clara Cheng

  • 1Developmental Endocrinology Branch, National Institute of Child Health and Human Development, National Institutes of Health, Bethesda, MD 20892, USA. bondyc@mail.nih.gov

Chromosome Research : an International Journal on the Molecular, Supramolecular and Evolutionary Aspects of Chromosome Biology
|October 6, 2009
PubMed
Summary
This summary is machine-generated.

Dosage compensation equalizes X chromosome gene expression but X monosomy significantly impacts development and fertility. This review explores how X chromosome gene dosage explains these effects in mammals.

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Last Updated: Jun 19, 2026

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Published on: April 7, 2023

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Area of Science:

  • Genetics
  • Developmental Biology
  • Mammalian Biology

Background:

  • Dosage compensation equalizes X chromosome gene expression between sexes.
  • It involves silencing one X chromosome in females.
  • Complete silencing would imply minimal impact from X chromosome loss.

Purpose of the Study:

  • To review observations and arguments explaining phenotypic effects of X monosomy.
  • To investigate the role of X chromosome gene dosage in these effects.
  • To understand consequences of X monosomy in humans and other mammals.

Main Methods:

  • Literature review of existing observations and arguments.
  • Analysis of phenotypic effects associated with X monosomy.
  • Examination of X chromosome gene dosage as a causative factor.

Main Results:

  • X monosomy has significant negative effects on development, fertility, and longevity.
  • These effects contradict the expectation of minimal consequences from X chromosome loss.
  • X chromosome gene dosage is a key factor in explaining these observed effects.

Conclusions:

  • The phenotypic consequences of X monosomy are best explained by X chromosome gene dosage.
  • Understanding gene dosage is crucial for explaining X monosomy's impact.
  • Further research is needed to fully elucidate these mechanisms.