Meiosis I - Reductional Cell Division
Last Updated :
23 Jul, 2025
Meiosis I, often known as reductional cell division, reduces the chromosome number to half while promoting genetic diversity. Similar pairs of chromosomes split off and enter the two daughter cells during this phase. As a result, half of the entire number of chromosomes is obtained. Meiosis, a process in the life of sexually reproducing organisms, ensures genetic diversity and stable chromosome numbers across generations. In this article, we will read about What is Meiosis I, the mechanism of Meiosis I, the Phases of Meiosis I, the significance of Meiosis I, and Meiosis vs. Mitosis.
What is Meiosis I?
In Meiosis I, cell division takes place that reduces chromosomes by half, a necessary process in sexually reproducing organisms. This reduction is important for maintaining a stable chromosome number across generations and for genetic diversity through independent assortment. Unlike mitosis, which is involved in growth and maintaining the same chromosome number, meiosis reduces the chromosome number by half. This reduction is important for maintaining the species-specific chromosomes through sexual reproduction.
Mechanism of Meiosis
Meiosis is a specialized form of cell division that reduces the chromosome number by half, creating four genetically diverse haploid cells from an original diploid cell. During Meiosis I, homologous chromosomes, each consisting of two sister chromatids, pair up in a process called synapsis and then cross over, where homologous chromosomes exchange genetic material, increasing genetic diversity. Then, these homologous chromosomes are pulled to opposite poles, reducing the chromosome number by half.
During meiosis II, the sister chromatids between the two daughter cells split, resulting in the formation of four additional haploid gametes. Meiosis II functions similarly to mitosis, with the exception that homologous chromosomes are only present in one set in each dividing cell.
Meiosis I Diagram
The labelled diagram of Meosis I is shown below:
Also Read: Cell Division: Mitosis and Meiosis
Phases of Meiosis I
In meiosis I, the chromosomal number is decreased from diploid (2n) to haploid (n) during this procedure. In people (2n = 46), who have 23 sets of chromosomes, the quantity of chromosomes is diminished at the end of meiosis I (n = 23). Each of these cells contains one chromosome from each homologous pair, setting the stage for the second meiotic division, where the separation of sister chromatids occurs. It involves four different phases: Prophase I, Metaphase I, Anaphase I, and Telophase I, and each phase has critical functions.
Also Read: Difference between Haploid and Diploid
Prophase I
Prophase I is the longest and most complex phase of meiosis, and it is also divided into five different stages: leptotene, zygotene, pachytene, diplotene, and diakinesis. Below is a mind map of the events occurring during Prophase I:
Metaphase I
The following events occurring during Metaphase I :-
- This phase involves bivalents aligned at the metaphase I plate, in the cell. The alignment is random, contributing to genetic diversity .
- The spindle fibers at each pole of the cell are attached to each chromosome of each pair.
Anaphase I
The following events occurring during Anaphase I :-
- In this phase homologous chromosomes are attracted to the opposite poles and sister chromatids are attached to centromeres .
- In this stage, sister chromatids will stay together.
Telophase I
The following events occurring during Telophase I :-
- In Telophase I they reach at the poles and nuclear membranes may begin to form around a set of chromosomes.
- Cytokinesis involves the division of the cell cytoplasm, which forms two identical daughter cells.
Also Read: Meiosis – Definition, Stages, Function and Purpose
Significance of Meiosis I
The following points highlight the significance of meiosis I:
- Maintenance of Chromosome Number: The most important role of Meiosis I is to half the chromosome number in gametes. Without this reduction, successive generations would experience genetic instability.
- Genetic Diversity through Recombination: Recombination is necessary for population diversity, as it produces new combinations of genes that are different from parents.
- Independent Assortment: In this process, each gamete receives a mix of maternal, and paternal chromosomes which increases the variability in the population.
- Fertility and Reproductive Health: Meiosis I is necessary for fertility and reproductive health. Problems in Meiosis I can lead to chromosomal disorders like Down syndrome, and Klinefelter syndrome.
- Agricultural Advancements: Meiosis I is used in the development of hybrid crops. Scientists can breed plants with useful traits such as disease resistance and increased yield and face environmental changes.
Meiosis Vs Mitosis
Meiosis I and Mitosis are both forms of cell division, but they show different processes and results. Mitosis is involved in growth, development, in organisms and results in two identical daughter cells which has same chromosome number as the parent cell. Meiosis I consists of a single division phase, prophase, metaphase, anaphase, and telophase, and maintains the diploid chromosome number.
Also Read: Difference Between Mitosis And Meiosis
Conclusion
Meiosis I plays an important role in the life of sexually reproducing organisms. By reducing the chromosome to half, involving processes like homologous chromosome pairing, crossing over, and genetic recombination during prophase I that helps in genetic variation, it helps in genetic diversity that characterizes sexual reproduction. This process not only ensures genetic diversity but also maintains a consistent chromosome number across generations, a balance that is for the survival and evolution of species. It informs medical research, particularly in genetics and reproductive health, and increases our understanding of evolutionary processes.
Also Read
Similar Reads
Meiosis ll : Equational Cell Division Meiosis II is the second phase of the cell division that separates the sister chromatids. Meiosis II is also known as equational cell division because the chromosome number at the end of meiosis II remains the same as at the end of meiosis I. It is a similar process of mitosis but genetic results ar
7 min read
Cell Division: Mitosis & Meiosis, Different Phases of Cell Cycle Cell division is the process by which a parent cell divides into two daughter cells. It occurs through two distinct processes, mitosis, and meiosis, each having its role in the life cycles of organisms. Mitosis is the division of a cell that produces two identical daughter cells, essential for growt
9 min read
Meiosis - Definition, Stages, Function and Purpose When a single cell divides into two or more cells, we say that cell division has occurred. The single cell that divides itself is known as a parent cell or parental cell. The resulting cells from the parent cell are known as daughter cells. A cell cycle can be defined as the sequence of events in wh
6 min read
Mitosis Cell Division: Definition, Stages and Diagram Mitosis cell division is the process by which a cell replicates and divides producing two identical daughter cells. Through mitosis, the cell maintains a constant number of chromosomes during cell division. The mitosis cell division occurs in somatic cells. The process of mitosis cell division plays
8 min read
How Reproduction is Happening in Humans? Humans are sexually reproducing organisms. They produce gametes containing genetic material that form the zygote and develop into offspring. The process of reproduction in humans includes the development of gametes (gametogenesis), which are sperm cells in males and egg cells in females, the transfe
7 min read
Cell Theory Notes - Definition, Parts, History, & Examples Cell Theory is a foundational biological principle stating that all living organisms are composed of cells, the cell is the basic unit of life, and all cells arise from pre-existing cells. Developed by scientists Schleiden, Schwann, and Virchow in the 19th century, this theory underscores the role o
8 min read