Nuclear Division (DP IB Biology)
Revision Note
Role of Mitosis & Meiosis in Eukaryotes
There are two processes by which the nucleus of a eukaryotic cell can divide. These are:
Mitosis
Meiosis
It is important for the nucleus of a cell to divide before cell division to avoid the production of anucleate cells
An anucleate cell is one without a nucleus
Mitosis gives rise to genetically identical cells and is the type of cell division used for growth, repair of damaged tissues, replacement of cells and asexual reproduction
Mitosis maintains the chromosome number and genome of cells
Cells produced during mitosis will often be diploid (2n)
Meiosis gives rise to cells that are genetically different from each other and is the type of cell division used to produce gametes (sex cells)
This is because the daughter cells produced during meiosis will only have half the number of chromosomes of the parent cell
These cells are said to be haploid (n)
Meiosis is important for generating genetic diversity
DNA Replication in Nuclear Division
DNA replication as a prerequisite for mitosis and meiosis
During interphase (the period before nuclear division) of the cell cycle, the DNA replicates to create two identical strands of DNA called chromatids
The chromatids are joined together by a narrow region called the centromere
The two chromatids that make up the double structure of a chromosome are known as ‘sister chromatids’
During anaphase, one chromatid from each chromosomes ends up in one daughter cell while the other chromatid ends up in the other daughter cell
After the centromere is split apart at the start of anaphase, the chromatids are referred to as individual chromosomes again
Chromosome structure and DNA replication diagram
Diagram illustrating the structure of a chromosome at different stages of mitosis
Examiner Tips and Tricks
It is important to distinguish between the terms chromatid, sister chromatids and chromosomes.
Condensation & Movement of Chromosomes
Condensation of chromosomes
DNA molecules are very long molecules (human DNA can be more than 50,000 µm) that need to fit within much smaller nuclei (human nuclei average less than 5 µm)
Prior to mitosis, the DNA molecules are loosely coiled (around histones in eukaryotic cells) to form a complex called chromatin
Histones package DNA into structures called nucleosomes
Each nucleosome consists of a strand of DNA coiled around eight histone proteins
During prophase, the chromatin gets condensed by supercoiling to form chromosomes
Condensation occurs by the repeated coiling of the DNA molecule (supercoiling)
This supercoiling is aided in eukaryotic cells by the presence of histone proteins and enzymes
Supercoiling of DNA around histones diagram
DNA is coiled around histone proteins to make chromatin
Movement of chromosomes
Microtubules and microtubule motors are responsible for the movement of chromosomes during cell division
Microtubules are tubulin fibres that form part of the cytoskeleton of the cell
They are able to lengthen and shorten in order to enable chromosome movement
Two types of tubulin, α-tubulin and β-tubulin form dimers which can be added or removed at the ends of the microtubules to change the length of the tubule
A dimer is a compound made up of two subunits
Chromosome movement is facilitated by motor proteins
These carry the chromosomes along the microtubules to the equator of the cell in preparation for nuclear division
Microtubule formation diagram
Microtubules are responsible for the movement of chromosomes during cell division
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