This lesson describes how respiration produces ATP by substrate-level and oxidative phosphorylation. The PowerPoint and accompanying resources are part of the 1st lesson in a series of 7 lessons which have been designed to cover the detailed content of point 5.2 (RESPIRATION) of the AQA A-level Biology specification. As the first lesson in this sub-topic, it has been specifically planned to act as an introduction to this cellular reaction and provides important details about glycolysis, the Krebs cycle and oxidative phosphorylation that will support the students to make significant progress when these stages are covered during individual lessons. Students met phosphorylation in topic 5.1 when considering the light-dependent reactions of photosynthesis and their knowledge of the production of ATP in this plant cell reaction is called on a lot in this lesson to show the similarities. The students are also tested on their recall of the structure and function of ATP, as covered in topic 1.6, through a spot the errors task. By the end of the lesson, the students will be able to name and describe the different types of phosphorylation and will know that ATP is produced by substrate-level phosphorylation in glycolysis and the Krebs cycle and by oxidative phosphorylation in the final stage of aerobic respiration with the same name.

This clear and concise lesson looks at the role of the Link reaction in the conversion of pyruvate to acetyl coenzyme A which will then enter the Krebs cycle. The PowerPoint has been designed to cover the fourth part of point 5.2 of the AQA A-level Biology specification which states that students should know about this conversion and the production of reduced NAD The lesson begins with a challenge, where the students have to recall the details of glycolysis in order to form the word matrix. This introduces the key point that this stage occurs in this part of the mitochondria and time is taken to explain why the reactions occur in the matrix as opposed to the cytoplasm like glycolysis. Moving forwards, the Link reaction is covered in 5 detailed bullet points and students have to add the key information to these points using their prior knowledge as well as knowledge provided in terms of NAD. The students will recognise that this reaction occurs twice per molecule of glucose and a quick quiz competition is used to test their understanding of the numbers of the different products of this stage. This is just one of the range of methods that are used to check understanding and all answers are explained to allow students to assess their progress. This lesson has been written to tie in with the other uploaded lessons on glycolysis and the Krebs cycle and oxidative phosphorylation.

This fully-resourced lesson explores how other respiratory substrates, such as lipids and proteins, can be used to produce molecules of ATP. The PowerPoint and accompanying resources have been designed to cover the 7th and final part of point 5.2 of the AQA A-level Biology specification which states that students should know how these substrates enter the Krebs cycle. This lesson has been written to challenge the knowledge of the earlier parts of the topic of respiration and so contains constant prior knowledge checks which come in a range of forms. Students will learn that lipids and proteins can be used as respiratory substrates and will recognise the different ways that they enter the respiratory pathway. Time is taken to look at the beta oxidation pathway and again students are challenged to compare the products of this pathway against that of the Link reaction.

This fully-resourced lesson looks at the series of oxidation-reduction reactions that form the Krebs cycle and focuses on the products in terms of reduced NAD, FAD and ATP. The engaging PowerPoint and accompanying resource have both been designed to cover the fifth part of point 5.2 of the AQA A-level Biology specification. The lesson begins with a version of the Impossible game where students have to spot the connection between 8 of the 9 terms and will ultimately learn that this next stage is called the Krebs cycle. The main part of the lesson challenges the students to use descriptions of the main steps of the cycle to continue their diagram of the reactions. Students are continually exposed to key terminology such as decarboxylation and dehydrogenation and they will learn where carbon dioxide is lost and reduced NAD and FAD are generated. They will also recognise that ATP is synthesised by substrate level phosphorylation. The final task challenges them to apply their knowledge of the cycle to work out the numbers of the different products and to calculate the number of ATP that must be produced in the next stage This lesson has been designed to tie in with the other uploaded lessons on glycolysis, anaerobic respiration, the Link reaction and oxidative phosphorylation.

A fun and engaging lesson presentation (90 slides) and associated worksheets that uses exam questions, quick tasks and quiz competitions to allow students to assess their understanding of the topic of transport in plants, which is module 3.1.3 on the OCR A-Level Biology A specification. Competition rounds include “Keyword BINGO”, “Crack the Code” and “Make the Link” and students will enjoy being able to identify areas that require further attention. All exam questions have mark schemes. This lesson is designed for A-level students

This revision resource includes exam questions, understanding checks and quiz competitions, all of which have been designed with the aim of motivating and engaging the students whilst they assess their understanding of the content found in topic 10 (Diseases and immunity) of the CIE IGCSE Biology specification for examination in June and November 2020 and 2021. This revision resource contains an engaging PowerPoint (37 slides) and associated worksheets, some of which have been differentiated to help and challenge differing abilities. The range of activities have been designed to cover as much of the Core and Supplement content as possible but the following sub-topics have been given particular attention: Pathogens as disease causing microorganisms that cause transmissible diseases when they are spread Pathogens can be spread through direct or indirect contact Vaccinations as a form of active immunity that leads to the production of memory cells Examples of passive immunity The human body’s defence systems to include the white blood cells Diabetes type I as an example of an autoimmune disease

This lesson describes how the hydrolysis of ATP supplies energy for biological processes and how the phosphorylation of ADP requires energy. The PowerPoint has been designed to cover point 5.6 of the Pearson Edexcel A-level Biology A specification and also describes how ATP is made in the light-dependent stage of photosynthesis and is needed in the light-independent stage. The start of the lesson focuses on the structure of this energy currency and challenges the students to use their knowledge of nucleotides and specifically RNA nucleotides to recognise the components of ATP. As a result, they will learn that this molecule consists of adenine, ribose and three phosphate groups. In order to release the stored energy, ATP must be broken down and students will be given time to discuss which reaction will be involved as well as the products of this reaction. Time is taken to describe how the hydrolysis of ATP can be coupled to energy-requiring reactions within cells and the examples of skeletal muscle contraction are used as this is covered in greater detail in topic 7. The final part of the lesson considers how ATP is formed when ADP is phosphorylated and students will learn that this occurs in the mitochondria and chloroplast during aerobic respiration and photosynthesis respectively, so that it ties in with the upcoming lessons in topic 5 and 7.

This lesson describes and explains how increasing the concentration of inhibitors affects the rate of an enzyme-controlled reaction. The PowerPoint and accompanying resource are the last in a series of 5 lessons which cover the content detailed in point 1.4.2 of the AQA A-level Biology specification and describes the effect of both competitive and non-competitive inhibitors. The lesson begins with a made up round of the quiz show POINTLESS called “Biology opposites” and this will get the students to recognise that inhibition is the opposite of stimulation. This introduces inhibitors as substances that reduce the rate of a reaction and students are challenged to use their general knowledge of enzymes to identify that inhibitors prevent the formation of the enzyme-substrate complex. Moving forwards, a quick quiz competition generates the abbreviation EIC (representing enzyme-inhibitor complex) and this introduces competitive inhibitors as substances that occupy the active site. The students are asked to apply their knowledge to a new situation to work out that these inhibitors have a similar shape to the enzyme’s substrate molecule. A series of exam-style questions are used throughout the lesson and at this point, the students are challenged to work out that an increase in the substrate concentration would reduce the effect of a fixed concentration of a reversible competitive inhibitor. The rest of the lesson focuses on non-competitive inhibitors and time is taken to ensure that key details such as the disruption of the tertiary structure is understood and biological examples are used to increase the relevance. Again, students will learn that increasing the concentration of the inhibitor results in a greater inhibition and a reduced rate of reaction but that increasing the substrate concentration cannot reduce the effect as was observed with competitive inhibitors.

This lesson explains the effects of temperature on the rate of enzyme activity and includes examples in plants, animals and microorganisms. The PowerPoint and the accompanying resource have been designed to cover point 5.16 of the Pearson Edexcel A-level Biology A (Salters Nuffield) specification and this lesson has been specifically planned to tie in with a lesson in topic 2 where the roles and mechanism of action of enzymes were introduced. The lesson begins by challenging the students to recognise optimum as a key term from its 6 synonyms that are shown on the board. Time is taken to ensure that the students understand that the optimum temperature is the temperature at which the most enzyme-product complexes are produced per second and therefore the temperature at which the rate of an enzyme-controlled reaction works at its maximum. The optimum temperatures of DNA polymerase in humans and in a thermophilic bacteria and RUBISCO in a tomato plant are used to demonstrate how different enzymes have different optimum temperatures and the roles of the former in the PCR is briefly described to prepare students for this lesson in topic 6. Moving forwards, the next part of the lesson focuses on enzyme activity at temperatures below the optimum and at temperatures above the optimum. Students will understand that increasing the temperature increases the kinetic energy of the enzyme and substrate molecules, and this increases the likelihood of successful collisions and the production of enzyme-substrate and enzyme-product complexes. When considering the effect of increasing the temperature above the optimum, continual references are made to the previous lesson and the control of the shape of the active site by the tertiary structure. Students will be able to describe how the hydrogen and ionic bonds in the tertiary structure are broken by the vibrations associated with higher temperatures and are challenged to complete the graph to show how the rate of reaction decreases to 0 when the enzyme has denatured.

This engaging lesson explores the roles of the SAN, AVN, Bundle of His and Purkyne fibres in the transmission of the wave of excitation through the heart. The PowerPoint and accompanying resources have been designed to cover the first part of point 6.1.3 of the AQA A-level Biology specification which states that students should be able to describe the myogenic stimulation of the heart and the subsequent wave of electrical activity. The lesson begins with the introduction of the SAN as the natural pacemaker and then time is given to study each step of the conduction of the impulse as it spreads away from the myogenic tissue in a wave of excitation. The lesson has been written to make clear links to the cardiac cycle and the structure of the heart and students are challenged on their knowledge of this system from topic 3. Moving forwards, students are encouraged to consider why a delay would occur at the AVN and then they will learn that the impulse is conducted along the Bundle of His to the apex so that the contraction of the ventricles can happen from the bottom upwards. The structure of the cardiac muscle cells is discussed and the final task of the lesson challenges the students to describe the conducting tissue, with an emphasis on the use of key terminology

This lesson looks at the two stages of protein synthesis, transcription and translation, and focuses on the key details that students need to understand this potentially difficult topic. The lesson presentation has been deliberately written in a concise way to encourage the students to summarise the two stages and pick out the key points which will enable them to form longer answers when necessary. The lesson begins by introducing the students to RNA, and a quick check is done to see how much they can recall about the other nucleic acid, DNA. Moving forwards, students are challenged to study the structure of DNA and RNA in SPOT THE DIFFERENCE before being challenged to explain why RNA is necessary in this process. Time is taken to look at important sections such as complimentary base pairing and the identification of amino acids from the codon. A number of quick competitions have been written into the lesson to maintain engagement and the progress checks are regular so that students assess their understanding and any misconceptions can be quickly identified and addressed. This lesson has been written for GCSE students but should a teacher want to teach an introduction lesson on protein synthesis before going into more detail at a later date, then this would be suitable.

This lesson describes the relationship between gross and net primary productivity and plant respiration and explains how to calculate NPP. The PowerPoint and accompanying resources have been designed to cover points 5.10 (i) and (ii) of the Pearson Edexcel A-level Biology A (Salters Nuffield) specification. Due to the fact that the productivity of plants is dependent on photosynthesis, a series of exam-style questions have been written into the lesson which challenge the students to explain how the structure of the leaf as well as the light-dependent and light-independent reactions are linked to GPP. All of the exam questions have displayed mark schemes which are included in the PowerPoint to allow students to immediately assess their understanding. A number of quick quiz competitions as well as guided discussion points are used to introduce the formulae to calculate NPP and N and to recognise the meaning of the components. Once again, this is immediately followed by the opportunity to apply their understanding to selected questions. As well as linking to photosynthesis from earlier in topic 5, this lesson has been specifically planned to challenge students on their understanding of ecosystem terminology from the start of the topic as well as preparing them for the next lesson on the efficiency of biomass and energy transfer

An informative lesson presentation (20 slides) and associated worksheet that looks at how negative feedback loops act as a final control in homeostatic mechanisms. This is a topic which is poorly understood by students at both GCSE and even A-level, so whilst designing this lesson, the focus was on a few key points and applying it to a range of actual examples. Students will see how a negative feedback loop is used in the control of adrenaline release and temperature regulation and they will also be shown what would happen if this loop didn’t exist. Students are then challenged to apply their knowledge by putting the order of the regulation of metabolic rate into the correct order. The final part of the lesson briefly looks at how positive feedback loops also exist by using the example of the release of oxytocin during birth. This lesson has primarily been designed for GCSE students but is suitable for A-level Biology students too.

A fast-paced lesson that explores the meaning of “health” and introduces the idea of communicable and non-communicable diseases. The lesson begins by showing the students an example of a health survey so they can complete a definition of the meaning of this term. Despite being widely used in the English language, the actual Scientific definition is not always well known by students so this 1st task is an important one. Moving forwards, students are given 5 minutes to see if they can fill an A-Z with the names of different diseases. Students will learn that diseases can be grouped as communicable or non-communicable and will be encouraged to discuss what the determining factor is on this classification. A quiz competition called “TO COM or NOT TO COM” is a play on words of Shakespeare’s famous saying but acts to test whether the students can distinguish a number of diseases as being spread by pathogens or not. After each disease is revealed, time is taken to look at the details of some of them like cystic fibrosis and the zika virus. The lesson concludes with the example of the human-papilloma virus and the connection between this and cervical cancer so that students can recognise that sometimes both types of disease are involved. This lesson has been written for GCSE students (14 - 16 year olds in the UK) but could be used with younger students who are looking at the healthy living topic.

Adenosine triphosphate is the universal energy currency and this lesson focuses on the structure of this nucleotide derivative. The PowerPoint has been designed to cover point 1.6 of the AQA A-level Biology specification and also explains how ATP must be hydrolysed to release energy and then re-synthesised during respiration and photosynthesis. As the previous sub-topic concerned the structure of DNA and RNA, the start of this lesson challenges the students on their knowledge of these polynucleotides so that they can recognise that this molecule consists of adenine, ribose and three phosphate groups. In order to release the stored energy, ATP must be broken down and students will be given time to discuss which reaction will be involved as well as the products of this reaction. Time is taken to describe how the hydrolysis of ATP can be coupled to energy-requiring reactions within cells and the examples of active transport and skeletal muscle contraction are used as these are covered in greater detail in topic 2 and 6. The final part of the lesson considers how ATP must be re-synthesised and students will learn that this occurs in the mitochondria and chloroplast during aerobic respiration and photosynthesis respectively.

This engaging and fully-resourced lesson covers the content of specification points 5.1.4 (e and f) of the OCR A-level Biology A specification which states that students should be able to demonstrate and apply an understanding of the differences between diabetes mellitus type I and II and the potential treatments of this disease. The lesson has been designed to take place in a diabetes clinic where students will be challenged to perform a number of roles such as diagnosing a patient with either type I or II and to write a letter to this patient explaining how the disease was caused and any treatments that will be recommended to control the disease. It has been planned to build on the knowledge that they will have of these diseases from GCSE and links are made to other A-level topics such as the beta cells of the pancreas which they considered during the lesson on the control of blood glucose concentration. The final part of the lesson looks at the potential treatments which include the genetic modification of bacteria. This topic is covered in greater detail in module 6.1.3 so this section of the lesson focuses on the enzymes involved as well as the plasmid DNA from a bacterial cell. This lesson has been designed for students studying the OCR A-level Biology A course and runs alongside the uploaded lesson on the control of blood glucose concentration as well as the other lessons that have been added for module 5.1.4

This engaging lesson describes how the structure of the phloem enables this vascular tissue to transport organic substances in plants. Both the detailed PowerPoint and accompanying resource have been designed to cover the 3rd part of point 3.4.2 (Mass transport in plants) of the AQA A-level Biology specification. Comparative questions between the xylem and phloem are very common so the lesson begins by challenging the students to use their prior knowledge to complete the xylem column of a table with details including the presence of lignin and bordered pits and specific substances which are transported in this tissue. This has been written into the lesson to encourage the students to start to think about how the structure and function of the phloem may compare. 3 quiz rounds have been included in the lesson to maintain motivation and to introduce key terms. The first of these rounds will challenge the students to be the first to recognise descriptions of sucrose and amino acids as they learn that these are the two most common assimilate, which are the substances transported by the phloem. The focus of this lesson is the relationship between structure and function and all descriptions have these two parts highlighted to support the students to recognise the link. Moving forwards, students will be introduced to the sieve tube elements and the companion cells and time is taken to consider why the structure of these cells are so different. Current understanding checks are interspersed throughout the lesson to ensure that any misconceptions can be quickly addressed. The plasmodesmata is described to allow students to understand how assimilates move from the companion cells to the sieve tube elements as this will be particularly important for the next lesson on translocation. The final task of the lesson challenges the students to write a detailed passage about the structure and function of the phloem, incorporating all of the information that they have absorbed throughout the course of the lesson.

A thought-provoking lesson presentation (34 slides) that looks at each of the stages in the development of drugs and considers the potential issues that arise at each of the stages. The lesson begins by ensuring that the students know the scientific definition of a drug and then they will be told how much is spent by the NHS alone each year on medicinal drugs so they can recognise the importance of this topic. Moving forwards, each stage in the development is considered in the appropriate detail. Students are challenged to consider some stages from both a scientific angle and a business angle so they can understand why certain animals are chosen for the testing. Key terms such as placebo and double blind trial are introduced and discussion time is written into the lesson so that insightful questions can be posed by all. There are regular progress checks throughout the lesson to allow the students to check on their understanding. This lesson has been written for GCSE students but could be used with KS3 students who might be carrying out research or a project on the topic of drugs.

This lesson describes and explains how increasing the temperature affects the rate of an enzyme-controlled reaction. The PowerPoint and the accompanying resource have been designed to cover the second part of point 1.4.2 of the AQA A-level Biology specification and ties in directly with the previous lesson on the properties of enzymes and their mechanism of action. The lesson begins by challenging the students to recognise optimum as a key term from its 6 synonyms that are shown on the board. Time is taken to ensure that the students understand that the optimum temperature is the temperature at which the most enzyme-product complexes are produced per second and therefore the temperature at which the rate of an enzyme-controlled reaction works at its maximum. The optimum temperatures of DNA polymerase in humans and in a thermophilic bacteria and RUBISCO in a tomato plant are used to demonstrate how different enzymes have different optimum temperatures and the roles of the latter two in the PCR and photosynthesis are briefly described to prepare students for these future lessons. Moving forwards, the rest of the lesson focuses on enzyme activity at temperatures below the optimum and at temperatures above the optimum. Students will understand that increasing the temperature increases the kinetic energy of the enzyme and substrate molecules, and this increases the likelihood of successful collisions and the production of enzyme-substrate and enzyme-product complexes. When considering the effect of increasing the temperature above the optimum, continual references are made to the previous lesson and the control of the shape of the active site by the tertiary structure. Students will be able to describe how the hydrogen and ionic bonds in the tertiary structure are broken by the vibrations associated with higher temperatures and result in an active site that is no longer complementary to the substrate. Key terminology such as denaturation is used throughout. Please note that this lesson has been designed specifically to explain the relationship between the change in temperature and the rate of reaction and not the practical skills that would be covered in a core practical lesson

This lesson describes the key structural features of viruses and challenges the students to compare them against those of a bacteria as covered in topic 3. The PowerPoint and accompanying resource have primarily been designed to cover point 6.5 of the Pearson Edexcel A-level Biology A (Salters Nuffield) specification but can be used a revision tool for point 3.4 as students need to recall the structures of a prokaryotic cell. Details of the COVID-19 epidemic are included in the lesson to increase relevance and to help students to understand this biological topic in greater depth. They will understand that a virus’ lack of cell structures results in an non-cellular classification and the fact that it is unable to reproduce without a host is one of the additional reasons that renders it as non-living. The main focus of the lesson is the nucleic acid, the capsid and the attachment proteins that are present in these microorganisms and time is taken to explain how these structures are involved in the infection of a host cell. The lipid membrane is also introduced and links are made to the previous lessons on eukaryotic cells. The final section of the lesson challenges the students to recognise the following prokaryotic cell structures from their descriptions: plasmid pili capsule cell wall flagellum circular DNA ribosomes mesosomes This lesson has been specifically planned to link to the next lesson which covers point 6.6 on the infection of human cells by Mycobacterium tuberculosis and human immunodeficiency virus