Phases of Cell Cycle and Mitosis PDF

Summary

This document details the phases of the cell cycle, including mitosis and meiosis. It also explains the function and structure of chromosomes and other related structures in cellular biology. The document discusses topics like chromosome replication and the importance of cell division.

Full Transcript

Phases of Cell Cycle

Many of life\'s little chores such as sweeping and dusting, are quietly
satisfying and rather fun washing dishes by hand, however, is never fun,
which is why some clever person made the dishwasher. This handy
invention soaks, washes, and rinses your dishes to a spot-free, sanitary
sparkle. You unload the dishes, and the machine is ready to start the
cycle all over again. A cell goes through a cycle, too. This cycle of
growth, DNA synthesis, and division is essential for an organism to grow
and heal.

The cell cycle is the regular pattern of growth, DNA duplication, and
cell division that occurs in eukaryotic cells. The four main stages: gap
1, synthesis, gap 2, and mitosis. Gap 1, synthesis, and gap 2 together
make up what is called interphase.

Checkpoint- a critical control point in the cell cycle where stop and go
signals can regulate the cell

cycle.

The Gap I Checkpoint or the Restriction point

Cell is large enough to divide and enough nutrients are available to
support the daughter cell.

If it receives a go signal, it will continue to cell cycle

If it receives a stop signal, it will exit the cell cycle Gap O
Checkpoint- a state where cells will not divide.

Synthesis (S)- Synthesis means \"the combining of parts to make a
whole.\"

DNA is copied.

There will be a new two sets of DNA Gap 2 Checkpoint

Cells continue to carry out their normal functions, and additional
growth occurs.

Checks that DNA is undamaged with adequate cell size before it
proceeds with mitosis and

cell division.

Mitosis (M)- It includes two processes: mitosis and cytokinesis. This is
the division of the cell nucleus. During mitosis, the nuclear membrane
dissolves, the duplicated DNA condenses around proteins and separates,
and two new nuclei form. Lastly, cytokinesis the process that divides
the cell cytoplasm. The result is two daughter cells that are
genetically identical to the original cell.

Parts of the Chromosomes

Did you ever attend a birthday party where cute goodies were handed out?
Whoever stuffed the giveaways had to make sure that each giveaway bag
had the same number of small toys, candies, and stickers. In case that
one child will miss a single goody, he may be raised a fuss. In this
scenario, dividing DNA must work properly. The beneficiary must equally
have the same set of DNA. This is a complicated task because DNA is
long. But this can be done easily through the process of mitosis.

Chromosomes are essential for the process of cell division and are
responsible for the replication, division, and creation of daughter
cells that contain correct sequences of DNA and proteins.

Nucleotides- DNA is a double-stranded molecule made of four different
subunits

Chromosome- One long continuous thread of DNA that consists of numerous
genes along with

regulatory information. Your body cells have 46 chromosomes each.

Histones- a group of proteins associated with the chromosomes.

DNA wraps around histones at regular intervals, similar to beads on a
string. Parts of the histones

interact with each other, further compacting the DNA.

Chromatin- loose combination of DNA and proteins Chromatid- one half of
the duplicated chromosome Sister chromatids- two identical chromatids

Centromere- region of the condensed chromosome that looks pinched

Telomere- ends of DNA molecules


Stages of Mitosis

Mitosis divides two new cells genetically identical with the parent
cell. This process allows the

splitting of the cell nucleus into two new sets of chromosomes.

**PROPHASE**

- Duplicated chromosomes condense

- The nuclear envelope breaks down

- Centrioles begin to move to opposite poles and spindle fibers form

**METAPHASE**

- Spindle fibers attach to each chromosome.

- They align the chromosomes along the cell equator.

**ANAPHASE**

- Chromatids separate to opposite sides of the cell.

- Cytokinesis usually begins in late anaphase or telophase.

**TELOPHASE**

- Nuclear membranes start to form, chromosomes begin to uncoil, and
the spindle fibers fall apart.

**CYTOKINESIS**

- Cytokinesis divides cytoplasm between two daughter cells, each with
a genetically identical nucleus. The cells enter interphase and
begin the cycle again.

mitosis - Students \| Britannica Kids \| Homework Help

Stages of Meiosis

Meiosis is a form of nuclear division that creates four haploid cells
from one diploid cell. This process involves two rounds of cell
division-meiosis I and meiosis II. Each round of cell division has four
phases, which are similar to those in mitosis. It only occurs for sex
cells. At the end of meiosis II. each cell (i.e., gamete) would have
half the original number of chromosomes, that is, 15 chromosomes.


A similar but no identical chromosome pair an organism receives from its
two parents accomplished in meiosis using a two-step division process.
Homologous pairs separate during a first round of cell division, called
meiosis I. Sister chromatids separate during a second round, called
meiosis II.

Since cell division occurs twice during meiosis,
one starting cell can produce four gametes (eggs or sperm).In each round
of division, cells go through four stages: prophase, metaphase,
anaphase, and telophase.

Do you know someone with a twin or do you have some family members that
are twins? Below is an example of the process of meiosis and its role in
having a twin.

Monozygotic twins are the other term for identical twins. These occur
when a single sperm meets the single egg and will eventually multiply
and divide, splitting it into two individuals.

Its opposite is called the fraternal twins. These are the result of the
fertilization of two different eggs that can produce different looks and
gender.

Application of Mitosis and Meiosis/ Disorders in Cell Cycle

Have you ever watched a movie in which people play with the elements of
nature? They might bring back dinosaurs or make a newfangled robot. And
have you noticed that these movies are always scary? That\'s because
things go out of control. The robots take over, or the dinosaurs start
eating humans. If cell growth goes out of control in your body, the
result can be even scarier. Cancer is uncontrolled cell growth and
results from many factors that affect the cell cycle. So how does your
body regulate all the millions of cell divisions happening in your body?

Chromosomes are the compacted strands of DNA. Body cells have two sets
of chromosomes received from the parent. Meiosis is responsible for
creating sex cells. Human cells have 46 chromosomes. These came from the
union of a sperm with 23 chromosomes and an egg cell with 23 chromosomes
also. When the zygote is formed, a new cell with 46 chromosomes is
produced.

Sexual reproduction produces a diverse population. This is a result of
the process called meiosis. Sex cells have unique combinations of
chromosomes. No egg cells or sperm cells are identical. Sibling with the
same parent is not identical to one another. This enables organisms to
continue to reproduce through the generations. The unsuccessful process
of the cell cycle might cause cancer cells.

Normal body cells have a number of important features. They can:

- reproduce when and where it\'s needed

- stick together in the right place in the body

- self-destruct when they become damaged or too old

- become specialized (mature)

Cancer cells are different from normal cells in various ways.

**1. Cancer cells continue to divide**

Cancer cells continue to divide until everything lumps and becomes a
tumor.

**2. Cancer cells ignore signals from other cells**

Cancer cells deny signaling from other cells. Cells send chemical
signals to each other.

**3. Cancer cells don\'t stick together**

Cancer cells detached with other cells. Cancer cells can lose the
molecules on their surface that

**4. Cancer cells do not have specialization**

Cells developed to carry out their function in the body. Scientists call
the process maturing differentiation. In cancer, the cells often
duplicate rapidly and don\'t have a chance to mature.

**5. Cancer cells do not repair**

New gene faults, or mutations, can make the cancer cells grow quicker,
damage other body parts and

become resistant to treatment.

**6. Cancer cells look different**

Cancer cells look differently from normal cells. They have different
sizes and some may be larger than normal while others are smaller.
Cancer cells have unusual shape and the nucleus may have an abnormal
appearance.

What does cancer look like? Look at the picture below.


These photographs show half of a cancerous lung and half of a healthy
lung. Gases diffuse across the surfaces of a healthy lung, so the
membrane surfaces must be thin and moist. Exposure to substances such as
tobacco smoke can cause changes in the lung cells. Cilia are destroyed,
and the lung lining becomes thicker. The lungs can no longer clean
themselves, so they are more susceptible to

From the above picture, you can really tell how difficult this might
cause a person. Imagine those who have survived cancer, they are really
winners! From the suffering and treatment, things will really end up
well. Now, what can you do to help yourself from not acquiring this?
Follow the list below.

1\. Avoid tobacco in all its forms, including exposure to secondhand

smoke.

2\. Eat properly.

3\. Make quality sleep a priority.

4\. Get enough vitamin D.

5\. If you choose to drink, limit yourself to an average of one drink a
day.

6\. Exercise regularly.

7\. Stay lean.

8\. Avoid infections that contribute to cancer, including hepatitis
viruses,

HIV, and the human papillomavirus.

9\. Avoid unnecessary exposure to radiation

10\. Avoid exposure to industrial and environmental toxins such as
asbestos fibers, benzene, aromatic

amines, and polychlorinated biphenyls (PCBs) (Harvard School of Public
Health).

Structural Components of Cell Membrane

Think about how the products you buy are packaged-----a pint of
tomatoes, or a tube of toothpaste. The tomatoes are probably in a
plastic container that has holes to allow air circulation. The
toothpaste is in a tube strong enough to be squeezed without ripping.
Both containers protect their contents, but they do so in different
ways. Like these products, the cell needs protection, but it must also
be able to respond to its surroundings. It is constantly taking in and
getting rid of various molecules. The structure of the cell membrane
allows it to perform all those functions.

The plasma membrane is composed of a unit membrane, a two-layered
structure with proteins on the outer surfaces and hydrophobic (water
insoluble) fat molecules on the inside. All membranes in the cell are
made of the same basic structure. This is called the unit membrane and
consists of two main chemicals: proteins (glycoproteins, etc.) and
lipids (glycolipids, etc.). The main lipid components of plasma
membranes are phospholipids- molecules composed of glycerol, phosphate,
and fatty acid residues- and heads with different chemical properties.
The tails are hydrophobic (water insoluble) fatty acid residues that
face the center of the membrane. The heads, which are hydrophilic (water
soluble), form the surface.

The plasma membrane is semipermeable. It lets small molecules like water
pass very easily but holds back larger solute molecules like proteins.
Water can diffuse through a semipermeable membrane almost as if it were
not there. Water always moves from areas of high concentration to areas
of low concentration. If two areas are separated by a semipermeable
membrane and there is a higher concentration of water on one side, water
moves through to equalize the concentration on both sides.

Cell membrane is like a faculty room. Teachers need to be undisturbed in
order to do paper work and preparations for the class. The solution so
that teachers can do their tasks efficiently is to separate their rooms
from the classroom. The walls keep the faculty room protected from
outside disturbances.

But teachers are not fenced in the faculty room forever. Doors allow
people to come and go when transactions are needed to be done with the
teachers. Doors in the faculty room are like the cell membrane in the
cells. Cell membrane is a selectively permeable membrane that filters
things that enter and exit the cell. The same scenario with the faculty
room, it cannot allow unimportant people to enter. They also select.

The fluid mosaic model describes the plasma membrane structure as a
mosaic of phospholipids, cholesterol, proteins, and carbohydrates.

Passive Transport

If you have ever been jammed in traffic behind a truck full of pigs, you
know that \"unpleasant\"fails to fully describe the situation. That is
because molecules travel from the pigs to receptors in your nose, which
your brain infers as a really bad odor. Or perhaps you have tie-dyed a
T-shirt and have seen dye molecules spread throughout the pot of water,
turning it neon green or electric blue. Why does that happen? Why don\'t
the molecules stay in one place?

Passive transport is the movement of molecules across a cell membrane
without energy input from the cell. It may also be described as the
diffusion of molecules across a membrane. Passive transport is like
swimming in the direction of water flow in a river. Here, you have to
face the current in order to reach the end or the opposite side of the
river bank. You are one of the substances that meet other substances
found in the river. The substances move from region of higher
concentration to the region of lower concentration

What will you do when someone sprays a perfume inside your room or even
in the house? Basically you would react and say if it\'s pleasing or
not. But how did it happened? This is because the perfume particles
diffuse in the air.

Diffusion is the movement of molecules in a fluid or gas from a region
of higher concentration to a region of lower concentration. Water
molecules,

of course, also diffuse.

How about when you sit in the bathtub or submerge our fingers in water
for a while? What happened?

Your hands become wrinkly, right? And that is too because of osmosis.
The skin of our fingers absorb water and get expanded or bloated,
leading to the pruned or wrinkled fingers.

Movement across a semipermeable membrane from an area of higher water

concentration to an area of lower water concentration is called osmosis.

The transport of oxygen in the blood and muscles is another example

of facilitated diffusion. In blood, hemoglobin is the carrier protein

whereas in muscles, the carrier protein in the myoglobin. The diffusion

of blood occurs as a result of higher pressure on one side of the

membrane and a lower one on the other side.

Facilitated diffusion is the diffusion of molecules across a membrane
through transport proteins. The word facilitate means \"to make it
easier.\" Transport proteins make it easier for molecules to enter or
exit a cell. But the process is still a form of passive transport.

Osmosis

If you have ever been stuck in traffic behind a truck full of pigs, you
know that \"unpleasant\" fails to fully describe the situation. That is
because molecules travel from the pigs to receptors in your nose,which
your brain interprets as a really bad odor. Or perhaps you have tie-dyed
a T-shirt and have seen dye molecules spread throughout the pot of
water, turning it neon green or electric blue. Why does that happen? Why
don\'t the molecules stay in one place?

EXPLORE

Osmosis is the diffusion of water across a semipermeable membrane from
an area of higher water

concentration to an area of lower water concentration (Fig.1).

1\. A solution is isotonic to a cell if it has the same concentration of
dissolved particles as the cell. Water

molecules move into and out of the cell at an equal rate, so the cell\'s
size remains constant

2\. A hypertonic solution has more solutes than a cell. Overall, more
water exits a cell in hypertonic

solution, causing the cell to shrivel or even die.

3\. A hypotonic solution has fewer solutes than a cell. Overall, more
water enters a cell in hypotonic

solution, causing the cell to expand or even burst.

Source: Nowicki, S. Georgia Biology (2008) pp.
86-87

EXPLAIN

Did you ever asks about how salt water fish cannot live in a fresh water
and vice versa? Here\'s the reason

why.

Osmosis deals with chemical solutions. Solutions have two parts, a
solvent and a solute. In the sea, the solute is the salt plus the other
micro molecules and the solvent is the water. When solute dissolves in a
solvent, the end product is called a solution. There are three different
types of solutions that cells can be in: isotonic, hypotonic, and
hypertonic. Different types of solutions have different impacts on cells
due to osmosis.

Source:https://www.scienceabc.com

The environment of salt water fish is different (Figure 2). There is a
high concentration of solutes in the environment around the fish. Like
this environment, water moves toward the high concentrate solute
solution because there is less water there. Water moves from high
concentration to low concentration. The fish naturally wants to push
water out of it which dehydrates them. Thus, saltwater fish drinks
saltwater in order for its cells not to shrivel from dehydration which
will eventually kill the fish. While the fish drinks saltwater, it is
also consuming salt. The salt in the fish would make the cells want to
push water out of them which will dehydrate the cells. In order to
prevent this kind of scenario, fish filter out the salt and poop it in
solid form, so there is not too much concentration of solutes in the
fish (AP Biology,Tahomo High School, 2013).

Fresh water (Figure 3) is hypotonic to the fish that salt content in
their body is higher than the salt content of the water surrounding
them. Due to osmosis, therefore, water continuously flows into their
body (i.e., the area of high solute concentration, salt being the
solute, in this case).To survive in the face of this continuous supply
of water, freshwater fish have to urinate very frequently.

How about the salt water fish placed in a freshwater environment, what
will happen?

If you put a saltwater fish into freshwater, the surrounding water would
flow into their body until their cells swelled up with water, eventually
killing them.

Active Transport: Endocytosis and Exocytosis

Active transport drives molecules across a membrane from a region of
lower concentration to a region of higher concentration. This process
uses transport proteins powered by chemical energy. Active Transport is
like shipping something because shipping requires energy and it moves
things across the surface of the earth. The same is with the cell. With
active transport, the cell moves the materials across the membrane and
it requires energy.

Endocytosis is the process of taking liquids or fairly large molecules
into a cell by engulfing them in a membrane. Endocytosis is like a GRAB
taxi wherein you can get a car with a driver to drive you around the
city just like a material that can get a casing from the cell membrane
to take it inside the cell.

Phagocytosis is a type of endocytosis in which the cell membrane engulfs
large particles. The

word literally means \"cell eating.\'

Pinocytosis is a type of endocytosis in which the cell membrane engulfs
small particles and called it as \"cell drinking®

Exocytosis is the opposite of endocytosis. It is the release of
substances out of a cell by the fusion of a vesicle with the membrane.
Exocytosis is also like a train because the sac takes the material to
the cell membrane and releases it onto the other side and that\'s as far
as it will go. Likewise, with a train, it takes you where you have to go
and no farther.