Meiosis I
Homologous chromosomes separate in meiosis I
Prophase I
- DNA has already replicated and condenses and becomes visible as chromosomes
- Each chromosome consists of two sister chromatids joined together by a centromere
- The chromosomes are arranged side-by-side in homologous pairs
- A pair of homologous chromosomes is called a bivalent
- As the homologous chromosomes are very close together the crossing over of non-sister chromatids may occur. The point at which the crossing over occurs is called the chiasma (chiasmata; plural)
- In this stage centrioles migrate to opposite poles and the spindle is formed
- The nuclear envelope breaks down and the nucleolus disintegrates
Metaphase I
- The bivalents line up along the equator of the spindle, with the spindle fibres attached to the centromeres
- The bivalents line up by independent assortment (random orientation)
Anaphase I
- The homologous pairs of chromosomes are separated as microtubules pull whole chromosomes to opposite ends of the spindle
- The centromeres do not split
Telophase I
- The chromosomes arrive at opposite poles
- Spindle fibres start to break down
- Nuclear envelopes form around the two groups of chromosomes and nucleoli reform
- Some plant cells go straight into meiosis II without reformation of the nucleus in telophase I
Meiosis I is reduction division
- Meiosis I is referred to as reduction division because homologous chromosomes separate and move to opposite poles of the cell.
- Therefore, the number of chromosomes per cell is reduced by a factor of 2
The different stages of meiosis I in an animal cell
Exam Tip
Understanding the difference between chromosomes and chromatids can be difficult. We count chromosomes by the number of centromeres present. So when the 46 chromosomes duplicate during interphase and the amount of DNA in the cell doubles there are still only 46 chromosomes present because there are still only 46 centromeres present. However, there are now 92 chromatids, which are strands of replicated chromosomes.