Introduction
The process of cell division, during which one cell gives rise to two identical daughter cells, is called mitosis. The process of mitosis is essential to life: it provides new cells for growth and replaces old and dying cells. Although all cells can divide, only somatic cells (any cell type except germ, or sex, cells) in eukaryotes undergo mitosis. (See also cell.)
The term mitosis technically refers to the duplication and separation of the parent cell’s chromosomes; the subsequent division of the cell’s membrane, giving rise to two daughter cells, is called cytokinesis. However, since cytokinesis immediately follows the mitotic duplication and separation of the chromosomes, the term mitosis is generally used to describe the combined events.
Just as all living things have a life cycle, so too does a cell. The life cycle of the cell, known simply as the cell cycle, can be divided broadly into two stages: interphase and cell division (mitosis and cytokinesis). Interphase is the longer of the two stages and takes up most of the cell cycle.
Interphase
During the interphase stage, the cell grows and carries out its normal life functions, such as transporting materials into and out of the cell as well as undergoing cellular respiration. At some point during interphase, each chromosome in the cell makes an exact copy of itself so that—by the end of interphase—the cell has two identical sets of chromosomes. Each duplicated chromosome consists of two identical chromatids joined together by a centromere (see heredity). Also during interphase, the cell’s organelles replicate themselves. Among these are the centrosomes, which will play a critical role during mitosis.
Cell Division
The cell division stage is relatively short compared with interphase and is divided into the four phases of mitosis—prophase, metaphase, anaphase, and telophase—and cytokinesis.
Prophase
During prophase, the chromosomes, which had been thin and threadlike in interphase, begin to condense, or thicken. The nuclear membrane surrounding the cell nucleus disintegrates, the nucleolus disappears, and the centrosomes move toward opposite poles of the cell. The centrosomes of animal, fungal, and algal cells contain two structures called centrioles, which produce short fibers called asters and longer fibers that form a spindle across the cell. Centrioles are absent in plant cells; in these cells, the spindle fibers are produced directly by the centrosomes.
Metaphase
In metaphase, the spindle fibers attach to the centromeres of the chromosomes and line up the chromosomes along the center, or “equator,” of the cell.
Anaphase
At the onset of anaphase, the centromere of each chromosome divides in two, and the sister chromatids separate. The spindle fibers then pull the sister chromatids away from each other and toward opposite poles of the cell. This step is essential, ensuring that each of the daughter cells will have a complete set of chromosomes.
Telophase
As telophase begins, a complete set of identical chromosomes is located at each pole of the cell. The mitotic spindle breaks down, and a nuclear membrane begins to form around each set of daughter chromosomes.
Cytokinesis
In animal, fungal, and algal cells, cytokinesis begins as the cell membrane pinches in at both ends of the cell equator, dividing the parent cell’s cytoplasm equally between the newly forming cells. The cell membrane forms a trenchlike furrow that continues to pinch inward until it closes, forming two identical daughter cells. Each daughter cell is genetically identical to the parent cell, with an identical set of chromosomes and a full set of organelles. Cytokinesis also occurs in plant cells, but the process is slightly different. In plant cells, the rigid cell wall of the parent cell prevents the cell membrane from pinching inward. Instead, a cell plate forms at the middle of the cell and grows outward along the parent cell equator. Cell membranes form on either side of the cell plate. When it reaches the sides of the parent cell, the plant cell plate fuses with the cell wall, completing the separation of the parent cell into two genetically identical daughter cells. The daughter cells produce cellulose, and the cell plate develops into a cell wall.
With mitosis and cytokinesis completed, the daughter cells enter interphase. The chromosomes begin to relax and again become threadlike and dispersed within the cell nucleus. The chromosomes will remain like this until the cells are ready to undergo mitosis, at which point the chromosomes will condense and thicken, the centrosomes will replicate and separate, and the cells will prepare to enter prophase.
As someone deeply entrenched in the realm of cell biology and mitosis, let's delve into the comprehensive breakdown of the concepts laid out in the article.
Mitosis and Cell Division: Mitosis, the process where a cell divides into two identical daughter cells, is crucial for growth and cellular replacement. It's exclusive to somatic cells in eukaryotes. Mitosis involves several key phases, starting with interphase and culminating in cell division, which encompasses mitosis itself and cytokinesis.
Cell Cycle: The cell cycle, divided into interphase and cell division, is the life cycle of a cell. Interphase, the longer phase, involves cell growth, normal functions like respiration, and chromosome duplication resulting in two identical sets.
Interphase: During this phase, the cell undergoes growth, performs regular functions like respiration, and crucially, chromosomes duplicate, ensuring two identical sets by the end of interphase. The duplicated chromosomes comprise two identical chromatids connected by a centromere.
Cell Division Phases:
- Prophase: Chromosomes condense, nuclear membrane disintegrates, centrosomes move, and spindle fibers form, aiding in chromosome movement.
- Metaphase: Chromosomes align along the cell equator due to spindle fibers attaching to their centromeres.
- Anaphase: Sister chromatids separate as the centromere divides, pulled toward opposite poles by spindle fibers.
- Telophase: Identical chromosomes assemble at each pole, the mitotic spindle breaks down, and nuclear membranes start forming around each set of chromosomes.
Cytokinesis: This phase divides the cytoplasm, creating two genetically identical daughter cells. In animal cells, the cell membrane pinches inward. In plants, a cell plate forms due to the rigid cell wall, developing into a new cell wall between the daughter cells.
Interphase (Post Mitosis): After mitosis and cytokinesis, daughter cells enter interphase. Chromosomes relax and disperse within the nucleus until they condense again for the next mitotic phase.
This intricate process ensures the propagation of genetic material, essential for growth and cellular regeneration. Understanding these stages at a microscopic level helps unravel the complexity and precision behind cell division, fundamental to life itself.
