OCR A Level Biology Revision Notes 2.1 Cell Structure PDF

Summary

These notes provide an overview of cell structure, including different types of microscopes and their uses, and the magnification and resolution aspects, as well as a range of organelles that are found in cells and their key functions.

Full Transcript

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YOUR NOTES
2.1 Cell Structure ⬇

CONTENTS
2.1.1 Studying Cells

2.1.2 Using a Microscope

2.1.3 Drawing Cells

2.1.4 Magnification & Resolution

2.1.5 Eukaryotic Cells

2.1.6 Eukaryotic Cells Under the Microscope

2.1.7 Organelles & the Production of Proteins

2.1.8 The Cytoskeleton

2.1.9 Prokaryotic & Eukaryotic Cells

2.1.1 STUDYING CELLS
Use of Microscopy

Microscopes can be used to analyse cell components and observe organelles

Magnification and resolution are two scientific terms that are very important to
understand and distinguish between when answering questions about microscopy (the use
of microscopes):
Magnification tells you how many times bigger the image produced by the
microscope is than the real-life object you are viewing

Resolution is the ability to distinguish between objects that are close together
(i.e. the ability to see two structures that are very close together as two separate
structures)

There are different types of microscopes:
Optical microscopes (sometimes known as light microscopes)

Electron microscopes

Laser scanning confocal microscopes

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Optical (light) microscopes
Optical microscopes use light to form an image

This limits the resolution of optical microscopes
Using light, it is impossible to resolve (distinguish between) two objects that are
closer than half the wavelength of light

The wavelength of visible light is between 500-650 nanometres (nm), so an optical
microscope cannot be used to distinguish between objects closer than half of this
value

Optical microscopes have a maximum resolution of around 0.2 micrometres (µm) or
200 nm
Therefore optical microscopes can be used to observe eukaryotic cells, their
nuclei and possibly mitochondria and chloroplasts

Optical microscopes cannot be used to observe smaller organelles such as
ribosomes, the endoplasmic reticulum or lysosomes

The maximum useful magnification of optical microscopes is about ×1500

Electron microscopes
Electron microscopes use electrons to form an image

This greatly increases the resolution of electron microscopes compared to optical
microscopes, giving a more detailed image
A beam of electrons has a much smaller wavelength than light, so an electron
microscope can resolve (distinguish between) two objects that are extremely close
together

Electron microscopes have a maximum resolution of around 0.0002 µm or 0.2 nm (i.e.
around 1000 times greater than that of optical microscopes)
This means electron microscopes can be used to observe small organelles such as
ribosomes, the endoplasmic reticulum or lysosomes

The maximum useful magnification of electron microscopes is about ×1,500,000

There are two types of electron microscopes:
Transmission electron microscopes (TEMs)

Scanning electron microscopes (SEMs)

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Transmission electron microscopes (TEMs)
TEMs use electromagnets to focus a beam of electrons

This beam of electrons is transmitted through the specimen

Denser parts of the specimen absorb more electrons
This makes these denser parts appear darker on the final image produced (produces
contrast between different parts of the object being observed)

Advantages of TEMs:
They give high-resolution images (more detail)

This allows the internal structures within cells (or even within organelles) to be
seen

Disadvantages of TEMs:
They can only be used with very thin specimens or thin sections of the object
being observed

They cannot be used to observe live specimens (as there is a vacuum inside a
TEM, all the water must be removed from the specimen and so living cells cannot be
observed, meaning that specimens must be dead, unlike optical microscopes that can
be used to observe live specimens)

The lengthy treatment required to prepare specimens means that artefacts
can be introduced (artefacts look like real structures but are actually the results of
preserving and staining)

They do not produce a colour image (unlike optical microscopes that produce a
colour image)

Scanning electron microscopes (SEMs)
SEMs scan a beam of electrons across the specimen

This beam bounces off the surface of the specimen and the electrons are detected,
forming an image
This means SEMs can produce three-dimensional images that show the surface of
specimens

Advantages of SEMs:
They can be used on thick or 3-D specimens

They allow the external, 3-D structure of specimens to be observed

Disadvantages of SEMs:
They give lower resolution images (less detail) than TEMs

They cannot be used to observe live specimens (unlike optical microscopes that
can be used to observe live specimens)

They do not produce a colour image (unlike optical microscopes that produce a
colour image)

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2.1 Cell Structure ⬇

Laser scanning confocal microscopes
These microscopes are relatively new technology

The cells being viewed must be stained with fluorescent dyes

A thick section of tissue or small living organisms are scanned with a laser beam
The laser beam is reflected by the fluorescent dyes

Multiple depths of the tissue section/organisms are scanned to produce an image
Think of it like the laser beam is building up the image layer by layer

Advantages:
They can be used on thick or 3-D specimens

They allow the external, 3-D structure of specimens to be observed

Very clear images are produced. The high resolution is due to the fact that the laser
beam can be focused at a very specific depth
You can even see the structure of the cytoskeleton in cells

Disadvantages:
It is a slow process and takes a long time to obtain an image

The laser has the potential to cause photodamage to the cells

Exam Tip

This is a lot of information to learn! First, make sure you know the basics of how each type
of microscope works. Then learn the advantages and disadvantages of each type of
microscope. In particular, make sure you can compare and contrast the different
microscopes in terms of their relative advantages and disadvantages. In an exam question,
you could be given a situation and then asked which type of electron microscope would be
most suitable to use and why. A good revision idea is to make a table of the advantages
and disadvantages of each type of microscope…then learn them!

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2.1.2 USING A MICROSCOPE
Preparation of Microscope Slides

Many biological structures are too small to be seen by the naked eye

Optical microscopes are an invaluable tool for scientists as they allow for tissues, cells and
organelles to be seen and studied

For example, the movement of chromosomes during mitosis can be observed using a
microscope

How optical microscopes work
Light is directed through the thin layer of biological material that is supported on a glass slide

This light is focused through several lenses so that an image is visible through the eyepiece
The magnifying power of the microscope can be increased by rotating the higher power
objective lens into place

Apparatus
The key components of an optical microscope are:
The eyepiece lens

The objective lenses

The stage

The light source

The coarse and fine focus

Other tools used:
Forceps

Scissors

Scalpel

Coverslip

Slides

Pipette

Staining solution

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2.1 Cell Structure ⬇

Image showing all the components of an optical microscope

Method
Preparing a slide using a liquid specimen:
Add a few drops of the sample to the slide using a pipette

Cover the liquid/smear with a coverslip and gently press down to remove air
bubbles

Wear gloves to ensure there is no cross-contamination of foreign cells

Methods of preparing a microscope slide using a solid specimen:
Take care when using sharp objects and wear gloves to prevent the stain from dying
your skin

Use scissors to cut a small sample of the tissue

Peel away or cut a very thin layer of cells from the tissue sample to be placed on
the slide (using a scalpel or forceps)

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The tissue needs to be thin so that the light from the microscope can pass
through

Apply a stain

Gently place a coverslip on top and press down to remove any air bubbles

Or

Some tissue samples need to be treated with chemicals to kill/make the tissue rigid

This involves fixing the specimen using formaldehyde (preservative), dehydrating it
using a series of ethanol solutions, impregnating it in paraffin/resin for support then
cutting thin slices from the specimen using a microtome

The paraffin is removed from the slices/specimen, a stain is applied and the specimen
is mounted using a resin and a coverslip is applied

Or

Freeze the specimen in carbon dioxide or liquid nitrogen

Cut the specimen into thin slices using a cryostat

Place the specimen on the slide and add a stain

Gently place a coverslip on top and press down to remove any air bubbles

When using an optical microscope always start with the low power objective lens:
It is easier to find what you are looking for in the field of view

This helps to prevent damage to the lens or coverslip in case the stage has been
raised too high

Preventing the dehydration of tissue:
The thin layers of material placed on slides can dry up rapidly

Adding a drop of water to the specimen (beneath the coverslip) can prevent the cells
from being damaged by dehydration

Unclear or blurry images:
Switch to the lower power objective lens and try using the coarse focus to get a
clearer image

Consider whether the specimen sample is thin enough for light to pass through to
see the structures clearly

There could be cross-contamination with foreign cells or bodies

Using a graticule to take measurements of cells:
A graticule is a small disc that has an engraved ruler

It can be placed into the eyepiece of a microscope to act as a ruler in the field of view

As a graticule has no fixed units it must be calibrated for the objective lens that is in
use. This is done by using a scale engraved on a microscope slide (a stage
micrometer)

By using the two scales together the number of micrometers each graticule unit is

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worth can be worked out

After this is known the graticule can be used as a ruler in the field of view

The stage micrometer scale is used to find out how many micrometers each graticule unit
represents

Limitations
The size of cells or structures of tissues may appear inconsistent in different specimen slides
Cell structures are 3D and the different tissue samples will have been cut at
different planes resulting in this inconsistencies when viewed on a 2D slide

Optical microscopes do not have the same magnification power as other types of
microscopes and so there are some structures that can not be seen

The treatment of specimens when preparing slides could alter the structure of cells

Exam Tip

Remember the importance of calibration when using a graticule. If it is not calibrated
then the measurements taken will be completely arbitrary!

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2.1 Cell Structure ⬇

Staining in Light Microscopy

Many tissues that are used in microscopy are naturally transparent, they let both light and
electrons pass through them

This makes it very difficult to see any detail in the tissue when using a microscope

Stains are often used to make the tissue coloured/visible

Staining for light microscopy
Coloured dyes are used when staining specimens

The dyes used absorb specific colours of light while reflecting others; this makes the
structures within the specimen that have absorbed the dye visible

Certain tissues absorb certain dyes, which dye they absorb depends on their chemical
nature

Specimens or sections are sometimes stained with multiple dyes to ensure the different
tissues within the specimen show up – this is known as differential staining

It is important to remember that most of the colours seen in photomicrographs (image taken
using a light microscope) are not natural
Chloroplasts don’t need stains as they show up green, which is their natural colour

Toluidine blue and phloroglucinol are common stains used
Toluidine blue turns cells blue

Phloroglucinol turns cells red/pink

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2.1 Cell Structure ⬇

Toluidine blue and phloroglucinol have been used to stain this tissue specimen taken
from a leaf

Staining for electron microscopy
When using Transmission electron microscopes (TEMs) the specimen must be stained in
order to absorb the electrons

Unlike light, electrons have no colour
The dyes used for staining cause the tissues to show up black or different shades
of grey

Heavy-metal compounds are commonly used as dyes because they absorb electrons well
Osmium tetroxide and ruthenium tetroxide are examples

Any of the colour present in electron micrographs is not natural and it is also not a result of
the staining

Colours are added to the image using an image-processing software

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2.1 Cell Structure ⬇

The internal structure of the mitochondrion can be seen using a TEM and staining

A spiracle found on the exoskeleton of an insect. No colours have been added to this
image using image-processing software.

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2.1.3 DRAWING CELLS
Drawing Cells

To record the observations seen under the microscope (or from photomicrographs taken) a
labelled biological drawing is often made

Biological drawings are line pictures which show specific features that have been observed
when the specimen was viewed

There are a number of rules/conventions that are followed when making a biological drawing

Guidelines for microscope drawings
The conventions are:
The drawing must have a title
The magnification under which the observations shown by the drawing are made
must be recorded

A sharp HB pencil should be used (and a good eraser!)

Drawings should be on plain white paper

Lines should be clear, single lines (no thick shading)

No shading

The drawing should take up as much of the space on the page as possible

Well-defined structures should be drawn

The drawing should be made with proper proportions

Label lines should not cross or have arrowheads and should connect directly to the
part of the drawing being labelled

Label lines should be kept to one side of the drawing (in parallel to the top of the
page) and drawn with a ruler

Drawings of cells are typically made when visualizing cells at a higher magnification power,
whereas plan drawings are typically made of tissues viewed under lower magnifications
(individual cells are never drawn in a plan diagram)

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An example of a tissue plan drawn from a low-power image of a transverse section of a
root. There is no cell detail present.

An example of a cellular drawing taken from a high-power image of phloem tissue.

Exam Tip

When producing a biological drawing, it is vital that you only ever draw what you see and not what you think you see.
To accurately reflect the size and proportions of structures you see under the microscope, you should get used to
using the eyepiece graticule.
You should be able to describe and interpret photomicrographs, electron micrographs and drawings of typical animal
cells.

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2.1 Cell Structure ⬇

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2.1 Cell Structure ⬇

2.1.4 MAGNIFICATION & RESOLUTION
Magnification Formula

Magnification is how many times bigger the image of a specimen observed is in
comparison to the actual (real-life) size of the specimen

The magnification (M) of an object can be calculated if both the size of the image (I), and
the actual size of the specimen (A), is known

An equation triangle for calculating magnification

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Worked Example

An image of an animal cell is 30 mm in size and it has been magnified by a factor of X
3000.
What is the actual size of the cell?

To find the actual size of the cell:

The size of cells is typically measured using the micrometre (μm) scale, with cellular
structures measured in either micrometers (μm) or nanometers (nm)

When doing calculations all measurements must be in the same units. It is best to use the
smallest unit of measurement shown in the question

To convert units, multiply or divide depending if the units are increasing or decreasing

Magnification does not have units

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2.1 Cell Structure ⬇

Converting units of measurement

There are 1000 nanometers (nm) in a micrometre (µm)

There are 1000 micrometres (µm) in a millimetre (mm)

There are 1000 millimetres (mm) in a metre (m)

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Worked Example

Step 1: Check that units in magnification questions are the same

Remember that 1mm = 1000µm

2000 / 1000 = 2, so the actual thickness of the leaf is 2 mm and the drawing thickness is 50 mm

Step 2: Calculate Magnification

Magnification = image size / actual size = 50 / 2 = 25

So the magnification is x 25

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2.1 Cell Structure ⬇

Magnification & Resolution
Magnification
Magnification is how many times bigger the image of a specimen observed is in compared to
the actual (real-life) size of the specimen

A light microscope has two types of lens:
An eyepiece lens, which often has a magnification of x10

A series of (usually 3) objective lenses, each with a different magnification

To calculate the total magnification the magnification of the eyepiece lens and the
objective lens are multiplied together:

eyepiece lens magnification x objective lens magnification
= total magnification

Resolution
Resolution is the ability to distinguish between two separate points

If two separate points cannot be resolved, they will be observed as one point

The resolution of a light microscope is limited by the wavelength of light

As light passes through the specimen, it will be diffracted

The longer the wavelength of light, the more it is diffracted and the more that this
diffraction will overlap as the points get closer together

Electron microscopes have a much higher resolution and magnification than a light
microscope as electrons have a much smaller wavelength than visible light
This means that they can be much closer before the diffracted beams overlap

The concept of resolution is why the phospholipid bilayer structure of the cell membrane
cannot be observed under a light microscope
The width of the phospholipid bilayer is about 10nm

The maximum resolution of a light microscope is 200nm (half the smallest wavelength
of visible light, 400nm)

Any points that are separated by a distance less than 200nm (such as the 10nm
phospholipid bilayer) cannot be resolved by a light microscope and therefore will not
be distinguishable as “separate”

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The resolving power of an electron microscope is much greater than that of the light
microscope, as structures much smaller than the wavelength of light will interfere with a
beam of electrons

Comparison of the electron microscope & light microscope
Light microscopes are used for specimens above 200 nm
Light microscopes shine light through the specimen, this light is then passed through
an objective lens (which can be changed) and an eyepiece lens (x10) which
magnify the specimen to give an image that can be seen by the naked eye

The specimens can be living (and therefore can be moving), or dead

Light microscopes are useful for looking at whole cells, small plant and animal
organisms, tissues within organs such as in leaves or skin

Electron microscopes, both scanning and transmission, are used for specimens above 0.5
nm
Electron microscopes fire a beam of electrons at the specimen either a broad static
beam (transmission) or a small beam that moves across the specimen (scanning)

The electrons are picked up by an electromagnetic lens which then shows the image

Due to the higher frequency of electron waves (a much shorter wavelength)
compared to visible light, the magnification and resolution of an electron microscope
is much better than a light microscope

Electron microscopes are useful for looking at organelles, viruses and DNA as well
as looking at whole cells in more detail

Electron microscopy requires the specimen to be dead however this can provide a
snapshot in time of what is occurring in a cell eg. DNA can be seen replicating and
chromosome position within the stages of mitosis are visible

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2.1 Cell Structure ⬇

Light v Electron Microscope Table

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2.1.5 EUKARYOTIC CELLS
Eukaryotic Cell Structure
Cell surface membrane

The structure of the cell surface membrane – although the structure looks static the
phospholipids and proteins forming the bilayer are constantly in motion

All cells are surrounded by a cell surface membrane which controls the exchange of
materials between the internal cell environment and the external environment
The membrane is described as being ‘partially permeable’

The cell membrane is formed from a phospholipid bilayer of phospholipids spanning a
diameter of around 10 nm

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2.1 Cell Structure ⬇

Cell wall

The cell wall is freely permeable to most substances (unlike the plasma membrane)

Found in plant cells but not in animal cells

Cell walls are formed outside of the cell membrane and offer structural support to cell

Structural support is provided by the polysaccharide cellulose in plants, and peptidoglycan in
most bacterial cells

Narrow threads of cytoplasm (surrounded by a cell membrane) called plasmodesmata
connect the cytoplasm of neighbouring plant cells

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2.1 Cell Structure ⬇

Nucleus

The nucleus of a cell contains chromatin (a complex of DNA and histone proteins) which
is the genetic material of the cell

Present in all eukaryotic cells (except red blood cells), the nucleus is relatively large and
separated from the cytoplasm by a double membrane (the nuclear envelope) which has
many pores

Nuclear pores are important channels for allowing mRNA and ribosomes to travel out of the
nucleus, as well as allowing enzymes (eg. DNA polymerases) and signalling molecules to
travel in

The nucleus contains chromatin (the material from which chromosomes are made)
Chromosomes are made of sections of linear DNA tightly wound around proteins
called histones

Usually, at least one or more darkly stained regions can be observed – these regions are
individually termed ‘nucleolus’ (plural: nucleoli) and are the sites of ribosome production

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2.1 Cell Structure ⬇

Mitochondria

A single mitochondrion is shown – the inner membrane has protein complexes vital for
the later stages of aerobic respiration embedded within it

The site of aerobic respiration within all eukaryotic cells, mitochondria are just visible with
a light microscope
Surrounded by double-membrane with the inner membrane folded to form cristae

The matrix formed by the cristae contains enzymes needed for aerobic respiration,
producing ATP

Small circular pieces of DNA (mitochondrial DNA) and ribosomes are also found in the matrix
(needed for replication)

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2.1 Cell Structure ⬇

Chloroplasts

Chloroplasts are found in the green parts of a plant – the green colour a result of the
photosynthetic pigment chlorophyll

Found in plant cells

Larger than mitochondria, also surrounded by a double-membrane

Membrane-bound compartments called thylakoids containing chlorophyll stack to form
structures called grana

Grana are joined together by lamellae (thin and flat thylakoid membranes)

Chloroplasts are the site of photosynthesis:
The light-dependent stage takes place in the thylakoids

The light-independent stage (Calvin Cycle) takes place in the stroma

Also contain small circular pieces of DNA and ribosomes used to synthesise proteins needed
in chloroplast replication and photosynthesis

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2.1 Cell Structure ⬇

Ribosomes

Ribosomes are formed in the nucleolus and are composed of almost equal amounts of
RNA and protein

Found in all cells

Found freely in the cytoplasm of all cells or as part of the rough endoplasmic reticulum in
eukaryotic cells

Each ribosome is a complex of ribosomal RNA (rRNA) and proteins

80S ribosomes (composed of 60S and 40S subunits) are found in eukaryotic cells

70S ribosomes (composed of 50S and 30S subunits) in prokaryotes, mitochondria and
chloroplasts

Site of translation (protein synthesis)

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2.1 Cell Structure ⬇

Endoplasmic reticulum

The RER and ER are visible under the electron microscope – the presence or absence of
ribosomes helps to distinguish between them

Rough Endoplasmic Reticulum (RER)
Found in plant and animal cells

Surface covered in ribosomes

Formed from continuous folds of membrane continuous with the nuclear envelope

Processes proteins made by the ribosomes

Smooth Endoplasmic Reticulum (ER)
Found in plant and animal cells

Does not have ribosomes on the surface, its function is distinct to the RER

Involved in the production, processing and storage of lipids, carbohydrates and steroids

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2.1 Cell Structure ⬇

Golgi apparatus (golgi complex)

The structure of the Golgi apparatus

Found in plant and animal cells

Flattened sacs of membrane similar to the smooth endoplasmic reticulum

Modifies proteins and lipids before packaging them into Golgi vesicles
The vesicles then transport the proteins and lipids to their required destination

Proteins that go through the Golgi apparatus are usually exported (e.g. hormones
such as insulin), put into lysosomes (such as hydrolytic enzymes) or delivered to
membrane-bound organelles

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2.1 Cell Structure ⬇

Large permanent vacuoles

The structure of the vacuole

A sac in plant cells surrounded by the tonoplast, selectively permeable membrane

Vacuoles in animal cells are not permanent and small

Vesicles

The structure of the vesicle

Found in plant and animal cells

A membrane-bound sac for transport and storage

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2.1 Cell Structure ⬇

Lysosomes

The structure of the lysosome

Specialist forms of vesicles which contain hydrolytic enzymes (enzymes that break
biological molecules down)

Break down waste materials such as worn-out organelles

Used extensively by cells of the immune system and in apoptosis (programmed cell
death)

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Centrioles

The structure of the centriole

Hollow fibres made of microtubules

Two centrioles at right angles to each other form a centrosome, which organises the
spindle fibres during cell division

Not found in flowering plants and fungi

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Microtubules

The structure of the microtubule

Found in all eukaryotic cells

Makes up the cytoskeleton of the cell about 25 nm in diameter

Made of α and β tubulin combined to form dimers, the dimers are then joined into
protofilaments
Thirteen protofilaments in a cylinder make a microtubule

The cytoskeleton is used to provide support and movement of the cell

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2.1 Cell Structure ⬇

Microvilli

The structure of the microvilli

Found in specialised animal cells

Cell membrane projections

Used to increase the surface area of the cell surface membrane in order to increase the
rate of exchange of substances

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2.1 Cell Structure ⬇

Cilia

The structure of the cilia

Hair-like projections made from microtubules

Allows the movement of substances over the cell surface

Flagella

The structure of the flagella

Found in specialised cells

Similar in structure to cilia, made of longer microtubules

Contract to provide cell movement for example in sperm cells

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2.1 Cell Structure ⬇

2.1.6 EUKARYOTIC CELLS UNDER THE MICROSCOPE
Photomicrographs of Eukaryotic Cells

There are some features or structures that can help to identify whether a cell shown in an
image is a plant cell or animal cell
Structures found only in animal cells: centrioles and microvilli

Structures found only in plant cells: the cellulose cell wall, large permanent
vacuoles and chloroplasts

The ultrastructure of an animal cell shows a densely packed cell – the ER and RER and
ribosomes form extensive networks throughout the cell in reality.

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2.1 Cell Structure ⬇

Plant cells have a larger, more regular structure in comparison to animal cells.

Describing and interpreting photomicrographs, electron micrographs and drawings of typical
animal/plant cells is an important skill
The organelles and structures within cells have a characteristic shape and size which can be
helpful when having to identify and label them in an exam

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2.1 Cell Structure ⬇

TEM electron micrograph of an animal cell showing key features. Notice the lack of a cell
wall.

TEM electron micrograph of a plant cell showing key features. Notice the presence of a
cell wall and vacuole.

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2.1 Cell Structure ⬇

More detailed structures can be seen and identified in electron micrographs compared to
photomicrographs

This is because electron microscopes have greater maximum magnification and resolution
than light (optical) microscopes

Mucus producing goblet cells (found in the lining of trachea, bronchi and larger
bronchioles) are shown in a photomicrograph

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2.1 Cell Structure ⬇

Details of the structures inside the goblet cell can be seen in an electron micrograph

Exam Tip

Make sure to learn the key identifying features of animal cells vs plant cells! It might also
help to familiarise yourself with the shapes and sizes of important structures and organelles
found in cells by finding some more photomicrographs and electron micrographs.

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2.1.7 ORGANELLES & THE PRODUCTION OF PROTEINS
Organelles & the Production of Proteins

In cells, many organelles are involved in the production and secretion of proteins

Organelles are specialised parts of a cell that carry out a particular function
Some organelles are membrane-bound

The organelles involved in protein synthesis include:
Nucleus

Ribosomes

Rough endoplasmic reticulum (RER)

Golgi apparatus

Cell surface membrane

The nucleus stores the DNA (that codes for the production of proteins) and also contains the
nucleolus, which manufactures ribosomes (required for protein synthesis)
The DNA from the nucleus is copied into a molecule of mRNA via a process known as
transcription

The mRNA strand leaves the nucleus through a nuclear pore and attaches to a ribosome
on the rough endoplasmic reticulum
The ribosome ‘reads’ the genetic instructions contained within the mRNA and uses
this code to synthesise a protein via a process known as translation

This protein then passes into the lumen (the inside space) of the rough endoplasmic
reticulum to be folded and processed

Cells that produce a large amount of proteins (e.g. enzyme or hormone-producing
cells) have an extensive rough endoplasmic reticulum

The processed proteins are then transported to the Golgi apparatus (also known as the
Golgi body or Golgi complex) in vesicles, which fuse with the Golgi apparatus, releasing the
proteins
The Golgi apparatus modifies the proteins, preparing them for secretion
Proteins that go through the Golgi apparatus are usually exported (e.g. hormones
such as insulin), put into lysosomes (such as hydrolytic enzymes) or delivered to other
membrane-bound organelles

The modified proteins then leave the Golgi apparatus in vesicles

Finally, these vesicles (containing the final proteins) fuse with the cell surface membrane,
releasing the proteins

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2.1 Cell Structure ⬇

Many organelles are involved in the production and secretion of proteins

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2.1.8 THE CYTOSKELETON
The Cytoskeleton

Within the cytoplasm of cells, there is an extensive network of protein fibres
This is known as the cytoskeleton

The cytoskeleton is made up of two main types of protein fibres: microfilaments and
microtubules
Microfilaments are solid strands that are mostly made of the protein actin. These
fibres can cause some cell movement and the movement of some organelles
within cells by moving against each other

Microtubules are tubular (hollow) strands that are mostly made of the protein
tubulin. Organelles and other cell contents are moved along these fibres using ATP
to drive this movement

Intermediate filaments (a third type of fibre) are also found within the cytoskeleton

The importance of the cytoskeleton
The cytoskeleton is important as it has several different functions, including:

Strengthening and support:
The cytoskeleton provides the cell with mechanical strength, forming a kind of
‘scaffolding‘ that helps to maintain the shape of the cell

It also supports the organelles, keeping them in position

Intracellular (within cell) movement:
The cytoskeleton aids transport within cells by forming ‘tracks’ along which
organelles can move

Examples of this include the movement of vesicles and the movement of
chromosomes to opposite ends of a cell during cell division

Cellular movement:
The cytoskeleton enables cell movement via cilia and flagella

These structures are both hair-like extensions that protrude from the cell surface and
contain microtubules that are responsible for moving them

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The cytoskeleton provides mechanical strength to cells, aids transport within cells and
enables cell movement

Exam Tip

For the exam, you only need to be aware of the two main types of protein fibres within the
cytoskeleton: microfilaments and microtubules. The third type (intermediate filaments) are
shown here to give extra detail on the composition of the cytoskeleton.

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2.1 Cell Structure ⬇

2.1.9 PROKARYOTIC & EUKARYOTIC CELLS
Comparison of Prokaryotic & Eukaryotic Cells

Animal and plant cells are types of eukaryotic cells, whereas bacteria are a type of
prokaryote

Prokaryotic cells are much smaller than eukaryotic cells (between 100 – 1000 times smaller)

Prokaryotic cells also differ from eukaryotic cells in having:
A cytoplasm that lacks membrane-bound organelles

Their ribosomes are structurally smaller (70 S) in comparison to those found in
eukaryotic cells (80 S)

No nucleus (instead they have a single circular DNA molecule that is free in the
cytoplasm and is not associated with proteins)

A cell wall that contains murein (a glycoprotein)

In addition, many prokaryotic cells have a few other structures that differentiate them from
others and act as a selective advantage, examples of these are:
Plasmids

Capsules

Flagellum

Plasmids are small loops of DNA that are separate from the main circular DNA molecule
Plasmids contain genes that can be passed between prokaryotes (e.g. genes for
antibiotic resistance)

Some prokaryotes (e.g. bacteria) are surrounded by a final outer layer known as a capsule.
This is sometimes called the slime capsule
It helps to protect bacteria from drying out and from attack by cells of the immune
system of the host organism

Flagellum (plural = flagella) are long, tail-like structure that rotate, enabling the
prokaryote to move (a bit like a propeller)
Some prokaryotes have more than one

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2.1 Cell Structure ⬇

Structures unique to prokaryotic cells

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2.1 Cell Structure ⬇

Prokaryotic cells are often described as being ‘simpler’ than eukaryotic cells, and they
are believed to have emerged as the first living organisms on Earth.

There are a number of important structural and physiological differences between
prokaryotic and eukaryotic cells
These differences affect their metabolic processes and how they reproduce

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2.1 Cell Structure ⬇

Prokaryotic & Eukaryotic Cells Comparison Table

Exam Tip

You will need to know all the differences between prokaryotic and eukaryotic cells.
Remember – the features in the table above are not present in all prokaryotes so keep this
in mind when answering exam questions.
Also, size is not a structural feature so if you are asked for a structural difference
between a prokaryotic and eukaryotic cell don’t include size in your answer.

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