Cell Cycle Control & Mitosis Notes PDF

Summary

These notes provide an overview of the cell cycle, including checkpoints, mitosis, and meiosis. It details the process and purpose of cell division in eukaryotes. The notes cover important stages, like prophase, metaphase, and anaphase, along with cytokinesis.

Full Transcript

**CONTROL CELL OF THE CYCLE**

[Checkpoint] is a critical control point in the Cell Cycle
where 'stop' and 'go-ahead'

**3 Major Checkpoints**

1. The **G1 Checkpoint** (the ***Restriction Point***) ensures that the
cell is large enough to divide and that enough nutrients are
available to support the resulting daughter cells. If a cell
receives a 'go-ahead' signal at the G1 checkpoint, it will usually
continue with the Cell Cycle.

**NOTE:**\
If the cell does not receive the ['go-ahead'] signal, it
will exit the Cell Cycle and switch to a non-dividing state called G0.
Most cells in the human body are in the G0 phase. 

2. The **G2 Checkpoint** ensures that DNA replication in S phase has
been successfully completed.

3. The **Metaphase Checkpoint** ensures that all of the chromosomes are
attached to the mitotic spindle by a kinetochore.

- is a disc-shaped protein structure associated with
duplicated chromatids in eukaryotic cells where the spindle fibers
attach during cell division to pull sister chromatids apart.


**Cell Division** - a fundamental process of growing, dividing and
repairing in the human body. It involves the distribution of identical
genetic material or DNA to two daughter cells.

***Why Do Cells Divide?***

- Cells divide for growth, development, repair of worn-out tissues and
reproduction

- To facilitate the exchange of materials

- To control Deoxyribonucleic acid (DNA) overloading


**[2 Ways by which cells increase in numbers]**

***EUKARYOTIC CELL DIVISION***

** Cell division that results in two daughter cells each having the
same number and kind of chromosomes as the parent cell**

1. **Mitosis**

** Two (2) main steps:**

1. ***Mitosis Fours steps*[; ]**

**\[Prophase\>Metaphase\>Anaphase\>Telophase\]**

2. ***Cytokinesis***

**Cytoplasm [ ] divides forming two new daughter cells [
]**

- **Each daughter cell is Genetically Identical to parent cell**

**2. Eukaryotes**

- **Mitosis**

- **Cell or organism growth**

- **Replacement or repair of damaged cells**

- **Meiosis**

- **formation of sex cells or gametes**

**HISTORY**

- **Strasburger (1875) -- first discovered *Mitosis* in plant cells.**

- **W. Flemming (1879) -- discovered *Mitosis* in animal cells. He
then coined the term *Mitosis* in 1882**


**OCCURRENCE**

- ***Mitocytes --* are cells undergoing mitosis.**

- **In plants, they are mostly *meristematic cells.***

- **In animals, they are stem cells, germinal epithelium and
embryonic cells.**

- **It also occurs during regeneration. Root tip is the best
material to study mitosis.**

**REASONS FOR MITOSIS**

- **Growth**

- **Repair/healing**

- **Asexual reproduction**


**Depending on Cell Type**

- **Mitosis can take a few minutes or a few days**

- **Muscles cells**

- **Nerve cells**

- **Skin Cells**

- **Digestive tract cells**

***\
***



Telophase is followed by [cytokinesis], which denotes the
division of the cytoplasm to form two daughter cells. Thus, it marks the
completion of cell division.

**MEIOSIS**

**& ITS STAGES**

**Why Is It Important?**

- Meiosis makes sure that all organisms produced via sexual
reproduction contain the correct number of chromosomes -- half from
each parent.


**PROPHASE 1**

- the chromosomes condense and the nucleus breaks down.

- as chromosomes move around, crossing over happens -- this means
genetic material can be exchanged.

**METAPHASE 1**


**ANAPHASE 1**

**TELOPHASE 1**

- Two new nuclei form around each set of chromosomes.

- The cytoplasm splits and two (***haploid)*** daughter cells are
formed.


**PROPHASE 2**

**METAPHASE 2**

- the chromosomes align single file in the centre of the cell.

- this occurs to ensure sister chromatids separate in the next stage.

**ANAPHASE 2**

\- sister chromatids separate and move to opposite ends of the cell.

\- this ensures that the daughter cells remain haploid -- that means
they have half the genetic material of the original parent cell.

**TELOPHASE 2**

- four new nuclei form around each set of chromosomes.

- the cytoplasms split and four (***haploid)*** daughter cells are
formed.