Cambridge International AS & A Level Biology Coursebook PDF

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This is a coursebook, not a past paper, for Cambridge International AS & A Level Biology. The fifth edition covers key biological concepts like cell biology, biological molecules, and enzymes. The book includes practice questions and sample answers.

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Biology
for Cambridge International AS & A Level
COURSEBOOK

Mary Jones, Richard Fosbery, Dennis Taylor & Jennifer Gregory

Fifth edition Digital Access
 Biology
for Cambridge International AS & A Level
COURSEBOOK

Mary Jones, Richard Fosbery, Dennis Taylor & Jennifer Gregory
University Printing House, Cambridge CB2 8BS, United Kingdom
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no reproduction of any part may take place without the written
permission of Cambridge University Press.
First edition 2003
Second edition 2007
Third edition 2012
Fourth edition 2014
Fifth edition 2020
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Printed in Dubai by Oriental Press
A catalogue record for this publication is available from the British Library
ISBN 978-1-108-85902-8 Coursebook Paperback with Digital Access (2 Years)
ISBN 978-1-108-79651-4 Digital Coursebook (2 Years)
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NOTICE TO TEACHERS
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and remains the intellectual property of Cambridge Assessment International Education.
W
Cambridge Assessment International Education bears no responsibility for the example
answers to questions taken from its past question papers which are contained in this
publication.

Exam-style questions and sample answers have been written by the authors.
In examinations, the way marks are awarded may be different. References to
assessment and/or assessment preparation are the publisher’s interpretation of the
syllabus requirements and may not fully reflect the approach of Cambridge Assessment
International Education.

Cambridge International recommends that teachers consider using a range of teaching and
learning resources in preparing learners for assessment, based on their own professional
judgement of their students’ needs.
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 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

Contents
Introduction vii 4 Cell membranes and transport
4.1 The importance of membranes 98
How to use this series ix
4.2 Structure of membranes 98
How to use this book xi 4.3 Roles of the molecules found in
membranes 101
1 Cell structure 4.4 Cell signalling 102
1.1 Cells are the basic units of life 3 4.5 Movement of substances across
1.2 Cell biology and microscopy 4 membranes 104
1.3 Plant and animal cells as seen with
a light microscope 4 5 The mitotic cell cycle
1.4 Measuring size and calculating 5.1 Growth and reproduction 124
magnification 11 5.2 Chromosomes 125
1.5 Electron microscopy 14 5.3 The cell cycle 126
1.6 Plant and animal cells as seen with an 5.4 Mitosis 127
electron microscope 17 5.5 The role of telomeres 132
1.7 Bacteria 32 5.6 The role of stem cells 133
1.8 Comparing prokaryotic cells with 5.7 Cancers 134
eukaryotic cells 34
1.9 Viruses 34 6 Nucleic acids and protein synthesis
6.1 The molecule of life 144
2 Biological molecules
6.2 The structure of DNA and RNA 144
2.1 Biochemistry 45
6.3 DNA replication 149
2.2 The building blocks of life 45
6.4 The genetic code 150
2.3 Monomers, polymers and
macromolecules 45 6.5 Protein synthesis 151
2.4 Carbohydrates 46 6.6 Gene mutations 153
2.5 Lipids 53 7 Transport in plants
2.6 Proteins 57
7.1 The transport needs of plants 163
2.7 Water 66
7.2 Vascular system: xylem and phloem 163
3 Enzymes 7.3 Structure of stems, roots and leaves and
the distribution of xylem and phloem 164
3.1 What is an enzyme? 75
7.4 The transport of water 170
3.2 Mode of action of enzymes 76
7.5 Transport of assimilates 180
3.3 Investigating the progress of an
enzyme-catalysed reaction 79 8 Transport in mammals
3.4 Factors that affect enzyme action 81
8.1 Transport systems in animals 194
3.5 Comparing enzyme affinities 84
8.2 The mammalian circulatory system 194
3.6 Enzyme inhibitors 85
8.3 Blood vessels 195
3.7 Immobilising enzymes 87

iv
 Contents

8.4 Tissue fluid 200 13 Photosynthesis
8.5 Blood 202 13.1 An energy transfer process 332
8.6 The heart 209 13.2 Structure and function of chloroplasts 333
13.3 The light-dependent stage of
9 Gas exchange
photosynthesis 337
9.1 Gas exchange 224
13.4 The light-independent stage of
9.2 Lungs 225 photosynthesis 339
9.3 Trachea, bronchi and bronchioles 226 13.5 Limiting factors in photosynthesis 340
9.4 Warming and cleaning the air 226
9.5 Alveoli 228 14 Homeostasis
14.1 Homeostasis 349
10 Infectious disease 14.2 The structure of the kidney 352
10.1 Infectious diseases 238 14.3 Control of water content 360
10.2 Antibiotics 253 14.4 The control of blood glucose 364
14.5 Homeostasis in plants 371
11 Immunity
11.1 Defence against disease 267 15 Control and coordination
11.2 Cells of the immune system 268 15.1 Hormonal communication 388
11.3 Active and passive immunity 277 15.2 Nervous communication 389
15.3 Muscle contraction 406
P1 Practical skills for AS Level
15.4 Control and coordination in plants 413
P1.1 Practical skills 292
P1.2 Experiments 292 16 Inheritance
P1.3 Variables and making measurements 292 16.1 Gametes and reproduction 428
P1.4 Recording quantitative results 298 16.2 The production of genetic variation 433
P1.5 Displaying data 299 16.3 Genetics 435
P1.6 Making conclusions 301 16.4 Monohybrid inheritance and genetic
P1.7 Describing data 301 diagrams 437
P1.8 Making calculations from data 301 16.5 Dihybrid inheritance 441
P1.9 Identifying sources of error and 16.6 The chi-squared (χ2) test 449
suggesting improvements 303 16.7 Genes, proteins and phenotype 451
P1.10 Drawings 304 16.8 Control of gene expression 453

12 Energy and respiration 17 Selection and evolution
12.1 The need for energy in living organisms 312 17.1 Variation 465
12.2 Aerobic respiration 313 17.2 Natural selection 469
12.3 Mitochondrial structure and function 319 17.3 Genetic drift and the founder effect 474
12.4 Respiration without oxygen 320 17.4 The Hardy–Weinberg principle 476
12.5 Respiratory substrates 322 17.5 Artificial selection 478
17.6 Evolution 482
17.7 Identifying evolutionary relationships 486

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 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

18 Classification, biodiversity and P2 Practical skills for A Level
conservation P2.1 Practical skills 582
18.1 Classification 497 P2.2 Planning an investigation 582
18.2 Biodiversity 507 P2.3 Constructing a hypothesis 582
18.3 Maintaining biodiversity 521 P2.4 Identifying variables 583
18.4 Protecting endangered species 524 P2.5 Describing the sequence of steps 586
18.5 Controlling alien species 530 P2.6 Risk assessment 586
18.6 International conservation P2.7 Recording and displaying results 587
organisations 531 P2.8 Analysis, conclusions and evaluation 587
P2.9 Evaluating evidence 600
19 Genetic technology
P2.10 Conclusions and discussion 600
19.1 Genetic engineering 544
19.2 Tools for the gene technologist 545 Appendix 1: Amino acid R groups 608
19.3 Gene editing 552
19.4 Separating and amplifying DNA 555 Appendix 2: DNA and RNA triplet codes 609
19.5 Analysing and storing genetic
information 560 Glossary 611
19.6 Genetic technology and medicine 564 Index 631
19.7 Genetic technology and agriculture 570
Acknowledgements 643

vi
 Introduction

Introduction
This is the fifth edition of the Cambridge International AS & A Level Biology
Coursebook, and it provides everything that you need to support your course for
Cambridge AS & A Level Biology (9700). It provides full coverage of the syllabus for
examinations from 2022 onwards.
The chapters are arranged in the same sequence as the topics in the syllabus.
Chapters 1 to P1 cover the AS material, and Chapters 12 to P2 cover the material
needed for A Level. The various features that you will find in these chapters are
explained on the next two pages.
Many questions will test a deeper understanding of the facts and concepts that you
will learn during your course. It is therefore not enough just to learn words and
diagrams that you can repeat in your examinations; you need to ensure that you really
understand each concept fully. Trying to answer the questions that you will find within
each chapter, and at the end of each chapter, should help you to do this.
Although you will study your biology as a series of different topics, it is very important
to appreciate that all of these topics link up with each other. You need to make links
between different areas of the syllabus to answer some questions. For example, you
might be asked a question that involves bringing together knowledge about protein
synthesis, infectious disease and transport in mammals. In particular, you will find that
certain key concepts come up again and again. These include:
Cells as units of life
Biochemical processes
DNA, the molecule of heredity
Natural selection
Organisms in their environment
Observation and experiment.
As you work through your course, make sure that you keep reflecting on the work that
you did earlier and how it relates to the current topic that you are studying. Some of
the reflection questions at the ends of the chapters suggest particular links that you
could think about. They also ask you to think about how you learn, which may help
you to make the very best use of your time and abilities as your course progresses. You
can also use the self-evaluation checklists at the end of each chapter to decide how well
you have understood each topic in the syllabus, and whether or not you need to do
more work on each one.
Practical skills are an important part of your biology course. You will develop these skills
as you do experiments and other practical work related to the topics you are studying.
Chapters P1 (for AS Level) and P2 (for A Level) explain what these skills are and what
you need to be able to do.

vii
 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

You may like to look at two other books in this series – the Workbook and the
Practical Workbook. The Workbook provides clear guidance on many of the skills
that you need to develop as you work through the course – such as constructing
and analysing graphs, and planning experiments – with exercises for you to try.
The Practical Workbook is full of detailed explanations of how to carry out all the
practicals required in the syllabus, and many others too, that will help you to become
more confident in practical work.
This is an exciting time to be studying biology, with new discoveries and technologies
constantly finding their way into the news. We very much hope that you will enjoy
your biology course, and that this book will help you not only to prepare for your
examinations but also to develop a life-long interest in this subject.

viii
 How to use this series

How to use this series
This suite of resources supports students and teachers following the Cambridge
International AS & A Level Biology syllabus (9700). All of the books in the series
work together to help students develop the necessary knowledge and scientific
skills required for this subject. With clear language and style, they are designed for
international learners.

The coursebook provides comprehensive support
Biology for the full Cambridge International AS & A
for Cambridge International AS & A Level Level Biology syllabus (9700). It clearly explains
COURSEBOOK facts, concepts and practical techniques, and
Mary Jones, Richard Fosbery, Dennis Taylor & Jennifer Gregory uses real-world examples of scientific principles.
Two chapters provide full guidance to help
students develop investigative skills. Questions
within each chapter help them to develop their
understanding, while exam-style questions
provide essential practice.

Fifth edition Digital Access

The workbook contains over 100
exercises and exam-style questions, Biology
carefully constructed to help learners for Cambridge International AS & A Level
develop the skills that they need as they WORKBOOK

progress through their Biology course. Mary Jones & Matthew Parkin

The exercises also help students develop
understanding of the meaning of various
command words used in questions,
and provide practice in responding
appropriately to these.

Second edition Digital Access

ix
 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

Biology
for Cambridge International AS & A Level
This write-in book provides students with a wealth
PRACTICAL WORKBOOK
of hands-on practical work, giving them full guidance
Mary Jones & Matthew Parkin and support that will help them to develop all of
the essential investigative skills. These skills include
planning investigations, selecting and handling
apparatus, creating hypotheses, recording and
displaying results, and analysing and evaluating data.

Second edition

The teacher’s resource supports and enhances the questions and practical activities
in the coursebook. This resource includes detailed lesson ideas, as well as answers
and exemplar data for all questions and activities in the coursebook and workbook.
The practical teacher’s guide, included with this resource, provides support for the
practical activities and experiments in the practical workbook.
Teaching notes for each topic area include a suggested teaching plan, ideas for
active learning and formative assessment, links to resources, ideas for lesson starters
and plenaries, differentiation, lists of common misconceptions and suggestions
for homework activities. Answers are included for every
question and exercise in the coursebook, workbook
and practical workbook. Detailed support is provided
for preparing and carrying out for all the investigations
in the practical workbook, including tips for getting
things to work well, and a set of sample results that can
be used if students cannot do the experiment, or fail to Biology
collect results. for Cambridge International
AS & A Level

Biology
for Cambridge International AS & A Level
DIGITAL TEACHER’S RESOURCE ACCESS CARD

Digital Teacher’s Resource

DO NOT Code inside is required to activate your
DISCARD purchase of the Teacher’s Resource

x
 How to use this book

How to use this book
Throughout this book, you will notice lots of different features that will help your
learning. These are explained below.

LEARNING INTENTIONS KEY WORDS
These set the scene for each chapter, help with navigation through the Key vocabulary
coursebook and indicate the important concepts in each topic. is highlighted in
the text when it is
first introduced.
BEFORE YOU START Definitions are then
given in the margin,
This contains questions and activities on subject knowledge you will need which explain the
before starting this chapter. meanings of these
words and phrases.
You will also find
SCIENCE IN CONTEXT definitions of these
This feature presents real-world examples and applications of the content in words in the Glossary
a chapter, encouraging you to look further into topics. There are discussion at the back of this
questions at the end which look at some of the benefits and problems of these book.
applications.

COMMAND WORDS
PRACTICAL ACTIVITY Command words
This book does not contain detailed instructions for doing particular that appear in the
experiments, but you will find background information about the practical work syllabus and might
you need to do in these boxes. There are also two chapters, P1 and P2, which be used in exams are
provide detailed information about the practical skills you need to develop highlighted in the
during the course. exam-style questions
when they are first
introduced. In the
margin, you will
Questions find the Cambridge
Appearing throughout the text, questions give you a chance to check that you have International
understood the topic you have just read about. You can find the answers to these definition. You will
questions in the digital version of the Coursebook. also find these
definitions in the
Glossary at the
back of the book
with some further
explanation on the
meaning of these
words.*
*The information in this section is taken from the Cambridge International syllabus (9700) for examination
from 2022. You should always refer to the appropriate syllabus document for the year of your examination
to confirm the details and for more information. The syllabus document is available on the Cambridge
International website at www.cambridgeinternational.org.

xi
 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

WORKED EXAMPLE
Wherever you need to know how to use a formula to carry out a calculation,
there are worked examples boxes to show you how to do this.

REFLECTION IMPORTANT
These activities ask you to look back on the topics covered in the chapter and Important equations,
test how well you understand these topics and encourage you to reflect on facts and tips are
your learning. given in these boxes.

EXAM-STYLE QUESTIONS
Questions at the end of each chapter provide more demanding exam-style questions, some of which may require
use of knowledge from previous chapters. Some questions are taken from past papers. Where this is the case, they
include references to the relevant past paper. All other questions are written by the authors. Answers to these
questions can be found in the digital version of the Coursebook.

SUMMARY

There is a summary of key points at the end of each chapter.

SELF-EVALUATION
The summary checklists are followed by ‘I can’ statements which match the Learning intentions at the beginning
of the chapter. You might find it helpful to rate how confident you are for each of these statements when you are
revising. You should revisit any topics that you rated ‘Needs more work’ or ‘Almost there’.

See Needs Almost Ready to
I can
section more work there move on

These boxes tell you where information in the book is extension content,
and is not part of the syllabus.

xii
 Chapter 1

Cell structure

LEARNING INTENTIONS
In this chapter you will learn how to:
explain that cells are the basic units of life
use the units of measurement relevant to microscopy
recognise the common structures found in cells as seen with a light microscope and outline their
structures and functions
compare the key structural features of animal and plant cells
use a light microscope and make temporary preparations to observe cells
recognise, draw and measure cell structures from temporary preparations and micrographs
calculate magnifications of images and actual sizes of specimens using drawings or micrographs
explain the use of the electron microscope to study cells with reference to the increased resolution of
electron microscopes
recognise the common structures found in cells as seen with an electron microscope and outline their
structures and functions
outline briefly the role of ATP in cells
describe the structure of bacteria and compare the structure of prokaryotic cells with eukaryotic cells
describe the structure of viruses.
 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

BEFORE YOU START
Make a list of structures that could be found in a cell.
Try to write down the functions of the structures you have listed.
Which structures are found in plant cells and which are found in animal cells?
Are there any cells that are not animal or plant cells?

THINKING OUTSIDE THE BOX
Progress in science often depends on people
thinking ‘outside the box’ – original thinkers who
are often ignored or even ridiculed when they
first put forward their radical new ideas. One such
individual, who battled constantly throughout
her career to get her ideas accepted, was the
American biologist Lynn Margulis (1938–2011;
Figure 1.1). Her greatest achievement was to use
evidence from microbiology to help firmly establish
an idea that had been around since the mid-19th
century – that new organisms can be created from
combinations of existing organisms. Importantly,
the existing organisms are not necessarily closely
related. The organisms form a symbiotic partnership
(they live together in a partnership in which both
partners benefit). Margulis imagined that one
organism engulfed (‘ate’) another. Normally the
engulfed organism would be digested and killed, Figure 1.1: Lynn Margulis: ‘My work more than didn’t fit
but sometimes the organism engulfed may survive in. It crossed the boundaries that people had spent their
and even be of benefit to the organism in which lives building up. It hits some 30 sub-fields of biology,
it finds itself. This type of symbiosis is known as even geology.’
endosymbiosis (‘endo’ means inside). A completely
new type of organism is created, representing a traditional view, first put forward by Charles Darwin,
dramatic evolutionary change. that evolution occurs mainly as a result of
competition between species.
The best-known example of Margulis’ ideas is her
suggestion that mitochondria and chloroplasts Questions for discussion
were originally free-living bacteria (prokaryotes). Can you think of any ideas people have had
She suggested that these bacteria invaded the which were controversial at the time but
ancestors of modern eukaryotic cells, which are are now accepted? Try to think of scientific
much larger and more complex cells than bacteria, examples. You may also like to consider why
and entered into a symbiotic relationship with the ideas were controversial.
the cells. This idea has been confirmed as true by
later work. Margulis saw such symbiotic unions Can you think of any scientific ideas people
as a major driving cause of evolutionary change. have now which are controversial and not
Throughout her life, she continued to challenge the accepted by everybody?

2
 1 Cell structure

animals. It was soon also realised that all cells come from
1.1 Cells are the basic pre-existing cells by the process of cell division. This
raises the obvious question of where the original cell
units of life came from. There are many hypotheses, but we still have
no definite answers to this question.
Towards the middle of the 19th century, scientists made a
fundamental breakthrough in our understanding of how life
‘works’. They realised that the basic unit of life is the cell. Why cells?
The origins of this idea go back to the early days of A cell can be thought of as a bag in which the chemistry
microscopy when an English scientist, Robert Hooke, of life occurs. The activity going on inside the cell is
decided to examine thin slices of plant material. He therefore separated from the environment outside the cell.
chose cork as one of his examples. Looking down the The bag, or cell, is surrounded by a thin membrane. The
microscope, he made a drawing to show the regular membrane is an essential feature of all cells because it
appearance of the structure, as you can see in Figure 1.2. controls exchange between the cell and its environment.
In 1665 he published a book containing It can act as a barrier, but it can also control movement
this drawing. of materials across the membrane in both directions. The
membrane is therefore described as partially permeable.
If it were freely permeable, life could not exist, because
the chemicals of the cell would simply mix with the
surrounding chemicals by diffusion and the inside of the
cell would be the same as the outside.

Two types of cell
During the 20th century, scientists studying the cells
of bacteria and of more complex organisms such as
plants and animals began to realise that there were
two fundamentally different kinds of cells. Some cells
were very simple, but some were much larger and more
complex. The complex cells contained a nucleus (plural:
nuclei) surrounded by two membranes. The genetic
material, DNA, was in the nucleus. In the simple cells
the DNA was not surrounded by membranes, but
apparently free in the cytoplasm.

Figure 1.2: Drawing of cork cells published by Robert KEY WORDS
Hooke in 1665.
cell: the basic unit of all living organisms; it is
surrounded by a cell surface membrane and
If you examine the drawing you will see the regular
contains genetic material (DNA) and cytoplasm
structures that Hooke called ‘cells’. Each cell appeared
containing organelles
to be an empty box surrounded by a wall. Hooke had
discovered and described, without realising it, the organelle: a functionally and structurally distinct
fundamental unit of all living things. part of a cell, e.g. a ribosome or mitochondrion
Although we now know that the cells of cork are dead, nucleus (plural: nuclei): a relatively large
Hooke and other scientists made further observations of organelle found in eukaryotic cells, but absent
cells in living materials. However, it was not until almost from prokaryotic cells; the nucleus contains the
200 years later that a general cell theory emerged from cell’s DNA and therefore controls the activities
the work of two German scientists. In 1838 Schleiden, of the cell; it is surrounded by two membranes
a botanist, suggested that all plants are made of cells. A which together form the nuclear envelope
year later Schwann, a zoologist, suggested the same for

3
 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

Organisms made of cells with membrane-bound are unfamiliar to most people. Before studying light and
nuclei are now known as eukaryotes, while the simpler electron microscopy further, you need to become familiar
cells lacking membrane-bound nuclei are known as with these units.
prokaryotes (‘eu’ means true, ‘karyon’ means nucleus,
According to international agreement, the International
‘pro’ means before). Eukaryotes are thought to have
System of Units (SI units) should be used. In this system,
evolved from prokaryotes more than two billion years
the basic unit of length is the metre (symbol, m). More
ago. Prokaryotes include bacteria. Eukaryotes include
units are created by going a thousand times larger or
animals, plants, fungi and some other organisms.
smaller. Standard prefixes are used for the units. For
example, the prefix ‘kilo’ means 1000 times. Thus,
KEY WORDS 1 kilometre = 1000 metres. The units of length relevant
to cell studies are shown in Table 1.1.
eukaryote: an organism whose cells contain a
nucleus and other membrane-bound organelles The smallest structure visible with the human eye is
about 50–100 μm in diameter (roughly the diameter of
prokaryote: an organism whose cells do not the sharp end of a pin). The cells in your body vary in
contain a nucleus or any other membrane-bound size from about 5 μm to 40 μm. It is difficult to imagine
organelles how small these cells are, especially when they are clearly
visible using a microscope. An average bacterial cell is
about 1 µm across. One of the smallest structures you
will study in this book is the ribosome, which is only
1.2 Cell biology and about 25 nm in diameter! You could line up about
20 000 ribosomes across the full stop at the end of
microscopy this sentence.

The study of cells has given rise to an important branch
of biology known as cell biology. Cell biologists study
cells using many different methods, including the use of
various types of microscope.
1.3 Plant and animal
There are two fundamentally different types of cells as seen with a light
microscope: the light microscope and the electron
microscope. Both use a form of radiation in order to
see the specimen being examined. The light microscope
microscope
uses light as a source of radiation, while the electron Microscopes that use light as a source of radiation are
microscope uses electrons, for reasons which are called light microscopes. Figure 1.3 shows how the light
discussed later. microscope works.

Note: the structure of a light microscope is
Units of measurement extension content, and is not part of the syllabus.
In order to measure objects in the microscopic world,
we need to use very small units of measurement, which

Fraction of a metre Unit Symbol
–3
one thousandth = 0.001 = 1/1000 = 10 millimetre mm
–6
one millionth = 0.000 001 = 1/1000 000 = 10 micrometre μm
one thousand millionth = 0.000 000 001 = nanometre nm
1/1000 000 000 = 10–9

Table 1.1: Units of measurement relevant to cell studies: 1 micrometre is a thousandth of a millimetre; 1 nanometre is a
thousandth of a micrometre.

4
 1 Cell structure

Eyepiece lens magnifies and showing the structure of a generalised plant cell, both
eyepiece
focuses the image from the as seen with a light microscope. (A generalised cell
objective onto the eye. shows all the structures that may commonly be found
in a cell.) Figures 1.6 and 1.7 are photomicrographs.
light beam
A photomicrograph is a photograph of a specimen as
seen with a light microscope. Figure 1.6 shows some
human cells. Figure 1.7 shows a plant cell taken from a
leaf. Both figures show cells magnified 400 times, which
objective Objective lens collects light is equivalent to using the high-power objective lens on
coverslip passing through the specimen a light microscope. See also Figures 1.8a and 1.8b for
and produces a magnified image. labelled drawings of these figures.
glass slide
Many of the cell contents are colourless and transparent
Condenser lens focuses the so they need to be stained with coloured dyes to be seen.
condenser
light onto the specimen held The human cells in Figure 1.6 have been stained. The
between the coverslip and slide. chromatin in the nuclei is particularly heavily stained.
iris diaphragm
The plant cells in Figure 1.5 have not been stained
light source Condenser iris diaphragm is
because the chloroplasts contain the green pigment
closed slightly to produce a
pathway of light narrow beam of light.
chlorophyll and are easily visible without staining.

Figure 1.3: How the light microscope works. The coverslip is
a thin sheet of glass used to cover the specimen. It protects
specimens from drying out and also prevents the objective
Question
lens from touching the specimen. 1 Using Figures 1.4 and 1.5, name the structures that:
a animal and plant cells have in common
small structures that b are found only in plant cells
Golgi apparatus are difficult to identify c are found only in animal cells.
cytoplasm

mitochondria Features that animal and plant
cells have in common
Cell surface membrane
cell surface All cells, including those of both eukaryotes and
membrane prokaryotes, are surrounded by a very thin cell surface
membrane. This is also sometimes referred to as the
plasma membrane. As mentioned before, it is partially
permeable and controls the exchange of materials
between the cell and its environment.
nuclear envelope
chromatin – Nucleus
centriole – always deeply staining
nucleus All eukaryotic cells contain a nucleus. The nucleus
found near nucleus and thread-like
is a relatively large structure. It stains intensely and
nucleolus –
deeply staining
KEY WORD
Figure 1.4: Structure of a generalised animal cell (diameter
about 20 μm) as seen with a very high quality light cell surface membrane: a very thin membrane
microscope. (about 7 nm diameter) surrounding all cells; it is
partially permeable and controls the exchange of
Figure 1.4 is a drawing showing the structure of a materials between the cell and its environment
generalised animal cell and Figure 1.5 is a drawing

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 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

middle lamella – thin layer
tonoplast – membrane
holding cells together
surrounding vacuole

cell surface membrane plasmodesma –
(pressed against cell wall) connects cytoplasm
of neighbouring cells
vacuole – large cell wall of
with central position neighbouring
cell
cytoplasm

cell wall
mitochondria
chloroplast

nucleolus –
deeply staining grana just visible
nuclear envelope
nucleus
chromatin – small structures that
deeply staining are difficult to identify
and thread-like Golgi apparatus

Figure 1.5: Structure of a generalised plant cell (diameter about 40 μm) as seen with a very high quality light microscope.

Figure 1.6: Cells from the lining of the human cheek (×400). Figure 1.7: Cells in a moss leaf (×400). Many green chloroplasts
Each cell shows a centrally placed nucleus, which is typical are visible inside each cell. The grana are just visible as black
of animal cells. The cells are part of a tissue known as grains inside the chloroplasts (‘grana’ means grains). Cell walls
squamous (flattened) epithelium. are also clearly visible (animal cells lack cell walls).

6
 1 Cell structure

is therefore very easy to see when looking down the
microscope. The deeply staining material in the nucleus KEY WORDS
is called chromatin (‘chroma’ means colour). Chromatin chromatin: the material of which chromosomes
is a mass of coiled threads. The threads are seen to are made, consisting of DNA, proteins and small
collect together to form chromosomes during nuclear amounts of RNA; visible as patches or fibres
division (Chapter 5, Section 5.2, Chromosomes). within the nucleus when stained
Chromatin contains DNA (deoxyribonucleic acid), the
molecule which contains the instructions (genes) that chromosome: in the nucleus of the cells of
control the activities of the cell (Chapter 6). eukaryotes, a structure made of tightly coiled
chromatin (DNA, proteins and RNA) visible during
Inside the nucleus an even more deeply staining area cell division; the term ‘circular DNA’ is now also
is visible, the nucleolus. This is made of loops of DNA commonly used for the circular strand of DNA
from several chromosomes. The number of nucleoli is present in a prokaryotic cell
variable, one to five being common in mammals. One of
nucleolus: a small structure, one or more of
the main functions of nucleoli is to make ribosomes.
which is found inside the nucleus; the nucleolus
is usually visible as a densely stained body; its
Cytoplasm function is to manufacture ribosomes using the
All the living material inside the cell is called protoplasm. information in its own DNA
It is also useful to have a term for all the living material
protoplasm: all the living material inside a cell
outside the nucleus; it is called cytoplasm. Therefore,
(cytoplasm plus nucleus)
cytoplasm + nucleus = protoplasm.
cytoplasm: the contents of a cell, excluding
Cytoplasm is an aqueous (watery) material, varying the nucleus
from a fluid to a jelly-like consistency. Using a light
microscope, many small structures can be seen within mitochondrion (plural: mitochondria): the
it. These have been likened to small organs and are organelle in eukaryotes in which aerobic
therefore known as organelles (meaning ‘little organs’). respiration takes place
An organelle can be defined as a functionally and cell wall: a wall surrounding prokaryote, plant
structurally distinct part of a cell. Organelles are often, and fungal cells; the wall contains a strengthening
but not always, surrounded by one or two membranes material which protects the cell from mechanical
so that their activities can be separated from the damage, supports it and prevents it from bursting
surrounding cytoplasm. Organising cell activities in by osmosis if the cell is surrounded by a solution
separate compartments is essential for a structure as with a higher water potential
complex as an animal or plant cell to work efficiently.

Mitochondria (singular: mitochondrion) Differences between
The most numerous organelles seen with the light
microscope are usually mitochondria (singular: animal and plant cells
mitochondrion). Mitochondria are only just visible using One of the structures commonly found in animal cells
a light microscope. Videos of living cells, taken with the which is absent from plant cells is the centriole. Plant
aid of a light microscope, have shown that mitochondria cells also differ from animal cells in possessing cell walls,
can move about, change shape and divide. They are large permanent vacuoles and chloroplasts.
specialised to carry out aerobic respiration.
Centrioles
Golgi apparatus Under the light microscope the centriole appears as
The use of special stains containing silver resulted in the a small structure close to the nucleus (Figure 1.4).
Golgi apparatus being discovered in 1898 by Camillo Centrioles are discussed later in this chapter.
Golgi. The Golgi apparatus collects and processes
molecules within the cell, particularly proteins.
Cell walls and plasmodesmata
With a light microscope, individual plant cells are more
easily seen than animal cells. This is because they are
Note: you do not need to learn this structure. It is
usually larger and, unlike animal cells, are surrounded
sometimes called the Golgi body or Golgi complex.
by a cell wall. Note that the cell wall is an extra

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 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

structure which is outside the cell surface membrane. of the plant, mainly in the leaves. They are relatively
The wall is relatively rigid because it contains fibres large organelles and so are easily seen with a light
of cellulose, a polysaccharide which strengthens the microscope. It is even possible to see tiny ‘grains’ or
wall. The cell wall gives the cell a definite shape. It grana (singular: granum) inside the chloroplasts using
prevents the cell from bursting when water enters by a light microscope (Figure 1.7). These are the parts
osmosis, allowing large pressures to develop inside the of the chloroplast that contain chlorophyll, the green
cell (Chapter 4, Section 4.5, Movement of substances pigment which absorbs light during the process of
across membranes). Cell walls may be reinforced with photosynthesis. Chloroplasts are discussed further in
extra cellulose or with a hard material called lignin Chapter 13 (Section 13.2, Structure and function of
for extra strength (Chapter 7). Cell walls are freely chloroplasts).
permeable, allowing free movement of molecules and
ions through to the cell surface membrane.
KEY WORDS
Plant cells are linked to neighbouring cells by means
of pores containing fine strands of cytoplasm. plasmodesma (plural: plasmodesmata): a
These structures are called plasmodesmata (singular: pore-like structure found in plant cell walls;
plasmodesma). They are lined with the cell surface plasmodesmata of neighbouring plant cells line
membrane. Movement through the pores is thought to up to form tube-like pores through the cell walls,
be controlled by the structure of the pores. allowing the controlled passage of materials from
one cell to the other; the pores contain ER and
are lined with the cell surface membrane
Vacuoles
Vacuoles are sac-like structures which are surrounded vacuole: an organelle found in eukaryotic cells;
by a single membrane. Although animal cells may a large, permanent central vacuole is a typical
possess small vacuoles such as phagocytic vacuoles feature of plant cells, where it has a variety of
(Chapter 4, Section 4.5, Movement of substances functions, including storage of biochemicals such
across membranes), which are temporary structures, as salts, sugars and waste products; temporary
mature plant cells often possess a large, permanent, vacuoles, such as phagocytic vacuoles (also
central vacuole. The plant vacuole is surrounded by known as phagocytic vesicles), may form in
a membrane, the tonoplast, which controls exchange animal cells
between the vacuole and the cytoplasm. The fluid
tonoplast: the partially permeable membrane
in the vacuole is a solution of pigments, enzymes,
that surrounds plant vacuoles
sugars and other organic compounds (including some
waste products), mineral salts, oxygen and carbon chloroplast: an organelle, bounded by an
dioxide. envelope (i.e. two membranes), in which
In plants, vacuoles help to regulate the osmotic photosynthesis takes place in eukaryotes
properties of cells (the flow of water inwards and photosynthesis: the production of organic
outwards) as well as having a wide range of other substances from inorganic ones, using energy
functions. For example, the pigments which colour from light
the petals of certain flowers and the parts of some
vegetables, such as the red pigment of beetroots, may grana (singular: granum): stacks of membranes
be found in vacuoles. inside a chloroplast

Chloroplasts
Chloroplasts are organelles specialised for the process
of photosynthesis. They are found in the green parts

8
 1 Cell structure

IMPORTANT
You can think of a plant cell as being very similar to an animal cell but with extra structures.
Plant cells are often larger than animal cells, although cell size varies enormously.
Do not confuse the cell wall with the cell surface membrane. Cell walls are relatively thick and physically
strong, whereas cell surface membranes are very thin. Cell walls are freely permeable, whereas cell
surface membranes are partially permeable. All cells have a cell surface membrane, but animal cells do
not have a cell wall.
Vacuoles are not confined to plant cells; animal cells may have small vacuoles, such as phagocytic
vacuoles, although these are not usually permanent structures.

PRACTICAL ACTIVITY 1.1

Making temporary slides black and will also colour nuclei and cell walls a pale
yellow. A dilute solution of methylene blue can be
A common method of examining material with a light
used to stain animal cells such as cheek cells.
microscope is to cut thin slices of the material called
‘sections’. The advantage of cutting sections is that Viewing specimens yourself with a microscope will
they are thin enough to allow light to pass through help you to understand and remember structures.
the section. The section is laid (‘mounted’) on a glass Your understanding can be reinforced by making
slide and covered with a coverslip to protect it. Light a pencil drawing on good quality plain paper.
passing through the section produces an image Remember always to draw what you see, and not
which can then be magnified using the objective and what you think you should see.
eyepiece lenses of the microscope.
Procedure
Biological material may be examined live or in a
preserved state. Prepared slides contain material that Place the biological specimen on a clean glass slide
has been killed and preserved in a life-like condition. and add one or two drops of stain. Carefully lower a
cover over the specimen to protect the microscope
Temporary slides are quicker and easier to prepare lens and to help prevent the specimen from drying
and are often used to examine fresh material out. Adding a drop of glycerine and mixing it with
containing living cells. In both cases the sections the stain can also help prevent drying out.
are typically stained before being mounted on the
glass slide. Suitable animal material: human cheek cells
obtained by gently scraping the lining of the
Temporary preparations of fresh material are useful cheek with a finger nail
for quick preliminary investigations. Sometimes
Suitable plant material: onion epidermal cells,
macerated (chopped up) material can be used,
lettuce epidermal cells, Chlorella cells, moss
as when examining the structure of wood (xylem).
slip leaves
A number of temporary stains are commonly used.
For example, iodine in potassium iodide solution (See Practical Investigation 1.1 in the Practical
is useful for plant specimens. It stains starch blue- Workbook for additional information.)

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 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

PRACTICAL ACTIVITY 1.2

Biological drawing sections of Practical Activity 7.1 before answering
the question below, which is relevant to this chapter.
To reinforce your learning, you will find it useful to
Figures 1.8a and b show examples of good drawing
make labelled drawings of some of your temporary
and labelling technique based on Figures 1.6
and permanent slides, as well as labelled drawings
and 1.7. Note that it is acceptable to draw only
of photomicrographs.
a representative portion of the cell contents of
Practical Activity 7.1 in Chapter 7 provides general Figure 1.7, but add a label explaining this.
guidance on biological drawing. Read the relevant
a
cytoplasm

nucleus

chromatin

small structures (organelles?)
visible (not all drawn)

Question
2 A student was asked to make a high-power drawing
of three neighbouring cells from Figure 1.6.
Figure 1.9 shows the drawing made by the student.
Using Practical Activity 7.1 to help you, suggest how
b
the drawing in Figure 1.9 could be improved.

eus
cytoplasm nucl
representative
portion of chloroplast
cytoplasm cytoplasm
drawn grana visible?

cell wall

Figure 1.8: Examples of good drawing technique: a high-power
drawing of three neighbouring animal cells from Figure 1.6;
b high-power drawing of two neighbouring plant cells from Figure 1.9: A student’s high-power drawing of
Figure 1.7. three neighbouring cells from Figure 1.6.

(See Practical Investigation 1.1 in the Practical Workbook for additional information.)

10
 1 Cell structure

1.4 Measuring size and Measuring cell size
Cells and organelles can be measured with a microscope
calculating magnification by means of an eyepiece graticule. This is a transparent
scale. It usually has 100 divisions (see Figure 1.10a).
Magnification is the number of times larger an image of The eyepiece graticule is placed in the microscope
an object is than the real size of the object. eyepiece so that it can be seen at the same time as
observed size of the image the object to be measured, as shown in Figure 1.10b.
magnification =
actual size Figure 1.10b shows the scale over one of a group of
or six human cheek epithelial cells (like those shown in
I Figure 1.6). The cell selected lies between 40 and 60 on
M = the scale. We therefore say it measures 20 eyepiece units
A
M = magnification in diameter (the difference between 60 and 40). We will
not know the actual size of the eyepiece units until the
I = observed size of the image (what you can measure
eyepiece graticule is calibrated.
with a ruler)
A = actual size (the real size – for example, the size of a KEY WORDS
cell before it is magnified).
If you know two of the values M, I and A, you can work magnification: the number of times larger an
out the third one. For example, if the observed size of image of an object is than the real size of the
the image and the magnification are known, you can object; magnification = image size ÷ actual (real)
I size of the object
work out the actual size A =. If you write the formula
M eyepiece graticule: small scale that is placed in a
in a triangle as shown below and cover up the value you
want to find, it should be obvious how to do the right microscope eyepiece
calculation.

I

M × A

a cheek cells on a slide b eyepiece graticule c
on the stage of the scale (arbitrary
microscope units)

0 10 20 30 40 50 60 70 80 90 100 0 10 20 30 40 50 60 70 80 90 100
0 10 20 30 40 50 60 70 80 90 100

0 0.1 0.2

eyepiece
graticule in
the eyepiece
stage micrometer
of the
scale (marked in
microscope
0.01 mm and 0.1 mm
divisions)

Figure 1.10: Microscopical measurement. Three fields of view seen using a high-power (×40) objective lens: a an eyepiece
graticule scale; b superimposed images of human cheek epithelial cells and the eyepiece graticule scale; c superimposed
images of the eyepiece graticule scale and the stage micrometer scale.

11
 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

To calibrate the eyepiece graticule, a miniature a
transparent ruler called a stage micrometer is placed on
the microscope stage and is brought into focus. This
scale may be etched onto a glass slide or printed on a
transparent film. It commonly has subdivisions of 0.1
and 0.01 mm. The images of the stage micrometer and
the eyepiece graticule can then be superimposed (placed
on top of one another) as shown in Figure 1.10c.

Calculating magnification
Figure 1.11 shows micrographs of two sections through
the same plant cell. The difference in appearance of the
two micrographs is explained in the next section.
If we know the actual (real) length of a cell in such a
micrograph, we can calculate its magnification, M, using b
the formula:
I
M =
A
epidermal cell
cell wall
KEY WORDS
chloroplast
stage micrometer: very small, accurately drawn
P starch grain
scale of known dimensions, engraved on a
microscope slide vacuole
nucleus
micrograph: a picture taken with the aid of a
microscope; a photomicrograph (or light mitochondrion
micrograph) is taken using a light microscope; cytoplasm
an electron micrograph is taken using an
electron microscope
Figure 1.11: Micrographs of two sections of the same
plant cells, as seen a with a light microscope, and b with
an electron microscope. Both are shown at the same
magnification (about ×750).

WORKED EXAMPLE

1 In the eyepiece graticule shown in Figure 1.10, The diameter of the cell shown superimposed
100 units measure 0.25 mm. Hence, the value of on the scale in Figure 1.8b measures 20 eyepiece
each eyepiece unit is: units and so its actual diameter is:
0.25
= 0.0025 mm 20 × 2.5 μm = 50 μm
100
This diameter is greater than that of many human
Or, converting mm to μm: cells because the cell is a flattened epithelial cell.
0. 25 1000
2. 5 µm
100

12
 1 Cell structure

WORKED EXAMPLE
2 Suppose we want to know the magnification of the Step 3 Use the equation to calculate the
plant cell labelled P in Figure 1.11b. The real length magnification.
of the cell is 80 μm.
image size, l
Step 1 Measure the length in mm of the cell in the magnification, M =
actual size, A
micrograph using a ruler. You should find
50 000 µm
that it is about 50 mm. =
80 µm
Step 2 Convert mm to μm. (It is easier if we first = × 625
convert all measurements to the same
units – in this case micrometres, μm.) The multiplication sign (×) in front of the number
625 means ‘times’. We say that the magnification
So: 1 mm = 1000 µm is ‘times 625’.
50 mm = 50 × 1000 µm
= 50 000 µm

Question
3 a Calculate the magnification of the drawing of b Calculate the actual (real) length of the
the animal cell in Figure 1.4. chloroplast labelled X in Figure 1.34.

WORKED EXAMPLE
3 Figure 1.12 shows a lymphocyte with a scale Step 1 Measure the scale bar. Here, it is 36 mm.
bar. We can use this scale bar to calculate the Step 2 Convert mm to μm:
magnification.
36 mm = 36 × 1000 μm = 36 000 μm
Step 3 The scale bar represents 6 µm. This is the
actual size, A. Use the equation to calculate the
magnification:
image size, l
magnification, M =
actualsize, A
36 000µm
=
6µm
= × 6000
6 µm

Figure 1.12: A lymphocyte.

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 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

Calculating the real size of an separate points. If the two points cannot be resolved,
they will be seen as one point. In practice, resolution is
object from its magnification the amount of detail that can be seen – the greater the
resolution, the greater the detail.
To calculate the real or actual size of an object, we can
use the same magnification equation. The maximum resolution of a light microscope is 200 nm.
The reason for this is explained in the next section, ‘The
electromagnetic spectrum’. A resolution of 200 nm means
WORKED EXAMPLE that, if two points or objects are closer together than
200 nm, they cannot be distinguished as separate.
4 Figure 1.20 shows parts of three plant cells You might imagine that you could see more detail in
magnified ×5600. Suppose we want to know the Figure 1.11a by magnifying it (simply making it larger).
actual length of the labelled chloroplast in this In practice you would be able to see what is already
electron micrograph. there more easily, but you would not see any more
detail. The image would just get more and more blurred
Step 1 Measure the observed length of the
as magnification increased. The resolution would not
image of the chloroplast (I), in mm,
be greater.
using a ruler. The maximum length is
25 mm.

Step 2 Convert mm to μm:
The electromagnetic spectrum
25 mm = 25 × 1000 μm = 25 000 μm How is resolution linked with the nature of light? One
of the properties of light is that it travels in waves. The
Step 3 Use the equation to calculate the lengths of the waves of visible light vary, ranging from
actual length: about 400 nm to about 700 nm. The human eye can
distinguish between these different wavelengths, and
image size, l
actual size, A = in the brain the differences are converted to colour
magnification, M differences. Waves that are 400 nm in length are seen as
25 000 µm violet. Waves that are 700 nm in length are seen
=
5600 as red.
= 4.5 µm (to one Visible light is a form of electromagnetic radiation.
decimal place) The range of different wavelengths of electromagnetic
radiation is called the electromagnetic spectrum. Visible
light is only one part of this spectrum. Figure 1.13
shows some of the parts of the electromagnetic
1.5 Electron microscopy spectrum. The longer the waves, the lower their
frequency. (All the waves travel at the same speed, so
Before studying what cells look like with an electron imagine them passing a post: shorter waves pass at
microscope, you need to understand the difference higher frequency.) In theory, there is no limit to how
between magnification and resolution. short or how long the waves can be. Wavelength changes
with energy: the greater the energy, the shorter the
wavelength.
Magnification and resolution
Look again at Figure 1.11. Figure 1.11a is a light KEY WORD
micrograph. Figure 1.11b is an electron micrograph.
Both micrographs are of the same cells and both have resolution: the ability to distinguish between
the same magnification. However, you can see that two objects very close together; the higher the
Figure 1.11b, the electron micrograph, is much clearer. resolution of an image, the greater the detail that
This is because it has greater resolution. Resolution can be seen
can be defined as the ability to distinguish between two

14
 1 Cell structure

X-rays infrared
microwaves
gamma rays UV radio and TV waves

5 7 9 11 13
0.1 nm 10 nm 1000 nm 10 nm 10 nm 10 nm 10 nm 10 nm

visible light

400 nm 500 nm 600 nm 700 nm
violet green orange red

Figure 1.13: Diagram of the electromagnetic spectrum. The numbers indicate the wavelengths of the different types of
electromagnetic radiation. Note the waves vary from very short to very long. Visible light is part of the spectrum. The double-
headed arrow labelled UV is ultraviolet light.

wavelength stained mitochondrion The general rule when viewing specimens is that the
400 nm of diameter 1000 nm limit of resolution is about one half the wavelength
interferes with light waves of the radiation used to view the specimen. In other
words, if an object is any smaller than half the
wavelength of the radiation used to view it, it cannot
be seen separately from nearby objects. This means
that the best resolution that can be obtained using a
microscope that uses visible light (a light microscope)
is 200 nm, since the shortest wavelength of visible light
is 400 nm (violet light). Ribosomes are approximately
25 nm in diameter and can therefore never be seen
using a light microscope.
If an object is transparent, it will allow light waves to
pass through it and therefore will still not be visible. This
is why many biological structures have to be stained
before they can be seen.

Question
stained ribosomes of diameter 25 nm 4 Explain why ribosomes are not visible using a light
do not interfere with light waves microscope.

Figure 1.14: A mitochondrion and some ribosomes in the
path of light waves of 400 nm length. The electron microscope
So how can we look at things smaller than 200 nm?
Now look at Figure 1.14. It shows a mitochondrion The only solution to this problem is to use radiation
and some very small cell organelles called ribosomes. of a shorter wavelength than visible light. If you study
It also shows some wavy blue lines that represent light Figure 1.13, you will see that ultraviolet light or X-rays
of 400 nm wavelength. This is the shortest visible look like possible candidates. A much better solution,
wavelength. The mitochondrion is large enough to though, is to use electrons. Electrons are negatively
interfere with the light waves. However, the ribosomes charged particles which orbit the nucleus of an atom.
are far too small to have any effect on the light waves. When a metal becomes very hot, some of its electrons

15
 CAMBRIDGE INTERNATIONAL AS & A LEVEL BIOLOGY: COURSEBOOK

gain so much energy that they escape from their orbits,
similar to a rocket escaping from Earth’s gravity. Free
Viewing specimens with the
electrons behave like electromagnetic radiation. They
have a very short wavelength: the greater the energy,
electron microscope
the shorter the wavelength. Electrons are a very suitable Figure 1.16 shows how a TEM works and Figure 1.17
form of radiation for microscopy for two major reasons. shows one in use.
First, their wavelength is extremely short (at least as
short as that of X-rays). Second, unlike X-rays, they are electron gun and anode –
negatively charged, so they can be focused easily using produce a beam of electrons
electromagnets (a magnet can be made to alter the path of
the beam, the equivalent of a glass lens bending light). electron beam
Using an electron microscope, a resolution of 0.5 nm can
vacuum
be obtained, 400 times better than a light microscope.

pathway of electrons
Transmission and scanning
condenser electromagnetic
electron microscopes lens – directs the electron beam
Two types of electron microscope are now in common onto the specimen
use. The transmission electron microscope (TEM) was
the type originally developed. The beam of electrons is
passed through the specimen before being viewed. Only specimen is placed on a
those electrons that are transmitted (pass through the grid
specimen) are seen. This allows us to see thin sections of
specimens, and thus to see inside cells. In the scanning
electron microscope (SEM), the electron beam is used
objective electromagnetic
to scan the surfaces of structures and only the reflected lens – produces an image
beam is observed.
An example of a scanning electron micrograph is shown
in Figure 1.15. The advantage of this microscope is that
surface structures can be seen. Because much of the projector electromagnetic
specimen is in focus at the same time, a three-dimensional lenses – focus the magnified
appearance is achieved. A disadvantage of the SEM is image onto the screen
that it cannot achieve the same resolution as a TEM.
Using an SEM, resolution is between 3 nm and 20 nm.

screen or photographic film
or sensor – shows the image
of the specimen

Figure 1.16: How a TEM works.

Note: the structure of an electron microscope is
extension content, and is not part of the syllabus.
Figure 1.15: Scanning electron micrograph (SEM) of a
tardigrade. Tardigrades or water bears, are about 0.5 mm It is not possible to see an electron beam, so to make
long, with four pairs of legs. They are common in soil and the image visible the electron beam has to be projected
can survive extreme environmental conditions (×86). onto a fluorescent screen. The areas hit by electrons

16
 1 Cell structure

The electron beam, and therefore the specimen and
the fluorescent screen, must be in a vacuum. If the
electrons collided with air molecules, they would scatter,
making it impossible to achieve a sharp picture. Also,
water boils at room temperature in a vacuum, so all
specimens must be dehydrated before being placed in
the microscope. This means that only dead material or