This fully-resourced lesson is clear and concise and has been written to explain how the inheritance of two or more genes that have loci on the same chromosome demonstrates linkage. The engaging PowerPoint and associated resource have been designed to cover point 3.8 (i and ii) of the Pearson Edexcel A-level Biology (Salters Nuffield) specification which states that students should know the meaning of a gene locus and understand the linkage of genes on a chromosome. This is a topic which can cause confusion for students so time was taken in the design to split the concept into small chunks. There is a clear focus on how the number of original phenotypes and recombinants can be used to determine linkage and suggest how the loci of the two genes compare. Important links to other topics such as crossing over in meiosis are made to enable students to understand how the random formation of the chiasma determines whether new phenotypes will be seen in the offspring or not. Linkage is an important cause of variation and the difference between observed and expected results and this is emphasised on a number of occasions. The main task of the lesson acts as an understanding check where students are challenged to analyse a set of results involving the inheritance of the ABO blood group gene and the nail-patella syndrome gene to determine whether they have loci on the same chromosome and if so, how close their loci would appear to be.

This fully-resourced lesson describes the key steps in the process of DNA replication, including the role of DNA polymerase. Both the detailed PowerPoint and accompanying resources have been designed to cover point 2.11 (i) of the Pearson Edexcel A-level Biology A specification and this lesson also explains why this replication is known as semi-conservative in order to prepare the students for the following lesson on Meselson and Stahl’s experiment. The main focus of this lesson is the role of DNA polymerase in the formation of the growing nucleotide strands but the students will also learn that the hydrogen bonds between nucleotide bases are broken by DNA helicase and that DNA ligase joins the nucleic acid fragments. Time is taken to explain key details, such as the assembly of strands in the 5’-to-3’ direction, so that the continuous manner in which the leading strand is synthesised can be compared against that of the lagging strand. The students are constantly challenged to make links to previous topics such as DNA structure and hydrolysis reactions through a range of exam questions and answers are displayed so that any misconceptions are quickly addressed. The main task of the lesson asks the students to use the information provided in the lesson to order the sequence of events in DNA replication before discussing how the presence of a conserved strand and a newly built strand in each new DNA molecule shows that it is semi-conservative.

This detailed and fully-resourced lesson describes the relationship between the structure, properties and functions of glycogen, starch and cellulose. The engaging PowerPoint and accompanying resources have been designed to cover specification points 2.1.2 (f) & (g) of the OCR A-level Biology A course and continual links are also made to the previous lessons in this topic where the monosaccharides and disaccharides were introduced. The lesson begins with the CARBOHYDRATE WALL where students have to use their prior knowledge to collect the 9 carbohydrates on show into 3 groups. This results in glycogen, starch and cellulose being grouped together as polysaccharides and the structure, properties and functions of these large carbohydrates are covered over the course of the lesson. Students will learn how key structural features like the 1 - 4 and 1 - 6 glycosidic bonds and the hydrogen bonds dictate whether the polysaccharide chain is branched or unbranched and also dictate whether the chain spirals or not. Following the description of the structure of glycogen, students are challenged to design an exam question in the form of a comparison table so that it can be completed as the lesson progresses and they learn more about starch and cellulose. This includes a split in the starch section of the table so that the differing structures and properties of amylose and amylopectin can be considered. The importance of the compact structure for storage is discussed as well as the branched chains of amylopectin acting as quick source of energy when it is needed. In the final part of the lesson, time is taken to focus on the hydrogen bonds between rotated glucose molecules on the same chain and between different chains and to explain how the formation of cellulose microfibrils and macrofibrils provides plant cells with the additional strength needed to support the whole plant. Due to the detail included in this lesson, it is estimated that it will take in excess of 2 hours of allocated teaching time to complete

This lesson describes how the relationship between the different properties of water and its roles in living organisms. The engaging PowerPoint has been designed to cover specification point 2.3 (d) of the CIE International A-level Biology course. Hydrolysis reactions have been a recurring theme throughout topic 2, so the start of this lesson challenges the students to recognise the definition when only a single word is shown: water. Students will also recall the meaning of a condensation reaction. Moving forwards, the rest of the lesson focuses on the relationship between the structure and properties of water, beginning with its role as an important solvent. The lesson has been specifically written to make links to future topics and this is exemplified by the transport of water along the xylem in plants which is covered in topic 7. The next section focuses on the high latent heat of vaporisation and heat capacity of water and these properties are put into biological context using thermoregulation and the maintenance of a stable environment for aquatic animals. The lesson finishes with an explanation of the polar nature of water, a particularly important property that needs to be well understood for a number of upcoming topics, such as cell membranes.

This lesson describes the relationship between the structure and function of the vacuole, chloroplast and cell wall, as found in plant cells. Additional structures, such as the nucleus and mitochondria, were covered in the previous lesson on the structure of eukaryotic animal cells and the detailed content of these two lessons has been designed in parallel to cover the main content of point 2.1.1 of the AQA A-level Biology specification. The lesson begins with a task called REVERSE GUESS WHO which will challenge the students to recognise a cell structure from a description of its function. This will remind students that plant cells are eukaryotic and therefore contain a cell-surface membrane, a nucleus (+ nucleolus), a mitochondria, a Golgi apparatus, ribosomes and rough and smooth endoplasmic reticulum like the animal cells. Moving forwards, the rest of the lesson focuses on the relationship between the structure and function of the vacuole, chloroplast and cellulose cell wall. When considering the vacuole, key structures such as the tonoplast are described as well as critical functions including the maintenance of turgor pressure. A detailed knowledge of the structure of the chloroplast at this early stage of their A-level studies will increase the likelihood of a clear understanding of photosynthesis when covered in topic 5. For this reason, time is taken to consider the light-dependent and light-independent reactions and to explain how these stages are linked. The final part of the lesson challenges the students on their knowledge of cellulose as a polysaccharide as previously covered in topic 1. In addition to the focus on plant cells, the presence of chloroplasts and a cell wall in algae and the latter in fungi is also described. The previous lesson which contains the content that ties in closely with this one has been uploaded under the title “Structure of eukaryotic (animal) cells”

This detailed lesson describes the structure and properties of the cell membrane, focusing on the phospholipid bilayer and membrane proteins. Fully resourced, the PowerPoint and accompanying worksheets have been designed to cover the first part of point 2.3 of the AQA A-level Biology specification and clear links are made to Singer and Nicholson’s fluid mosaic model The fluid mosaic model is introduced at the start of the lesson so that it can be referenced at appropriate points throughout the lesson. Students were introduced to phospholipids in topic 1 and so an initial task challenges them to spot the errors in a passage describing the structure and properties of this molecule. This reminds them of the bilayer arrangement, with the hydrophilic phosphate heads protruding outwards into the aqueous solutions on the inside and the outside of the cell. In a link to some upcoming lessons on the transport mechanisms, the students will learn that only small, non-polar molecules can move by simple diffusion and that this is through the tails of the bilayer. This introduces the need for transmembrane proteins to allow large or polar molecules to move into the cell by facilitated diffusion and active transport. Proteins that act as receptors as also introduced and an opportunity is taken to make a link to an upcoming topic so that students can understand how hormones or drugs will bind to target cells in this way. Moving forwards, the structure of cholesterol is covered and students will learn that this hydrophobic molecule sits in the middle of the tails and therefore acts to regulate membrane fluidity. The final part of the lesson challenges the students to apply their newly-acquired knowledge to a series of questions where they have to explain why proteins may have moved when two cells are used and to suggest why there is a larger proportion of these proteins in the inner mitochondrial membrane than the outer membrane.

This lesson describes the movement across cell membranes by simple and facilitated diffusion and describes how the rate is increased. The PowerPoint and accompanying resources have been designed to cover the second part of specification point 2.3 of the AQA A-level Biology course and the limitations imposed by the phospholipid bilayer and the role of channel and carrier proteins are described in detail. The structure and properties of cell membranes was covered in the previous lesson so this one has been written to include continual references to the content of these lessons. This enables links to be made between the movement across a cell membrane with the concentration gradient, the parts of the membrane that are involved and any features that may increase the rate at which the molecules move. A series of questions about the alveoli are used to demonstrate how a large surface area, a short diffusion distance and the maintenance of a steep concentration gradient will increase the rate of simple diffusion. One of two quick quiz rounds is then used to introduce temperature and size of molecule as two further factors that can affect simple diffusion. The remainder of the lesson focuses on facilitated diffusion and describes how transmembrane proteins are needed to move small, polar or large molecules from a high concentration to a lower concentration across a partially permeable membrane.

This is a fast-paced lesson which uses a range of tasks and quick competitions to compare the diagnosis, symptoms and treatment of Diabetes mellitus Type I and II. Students are continually challenged throughout the lesson to build and deepen their knowledge of these conditions and consider how they can be controlled through hormone injections or lifestyle changes. Clear links are made to related topics such as auto-immune diseases and the endocrine system and progress checks have been written into the lesson to allow students to assess their understanding of all of these topics. The final part of the lesson involves the students writing a letter to an individual who has type II, explaining how this diagnosis was done, giving details of the condition and recommending lifestyle changes. This task is differentiated so that students who are finding it difficult can still access the learning. This lesson has been written for A-level students. If you are looking for a lesson for younger students on this topic, then my other upload “Diabetes Type I and II” will be more suitable.

This is an engaging and informative lesson that looks at the meaning of excretion in detail and explores the functions of the organs involved with the excretion of carbon dioxide and urea. This lesson has been designed for students studying A-level Biology. The lesson begins by introducing the definition of excretion to the students so that they are able to recognise that the substances being removed have to have come from a metabolic process in order to be excreted. This important difference to egestion (elimination) is a key detail which they need to understand at this level. Moving forwards, a quick competition is used to meet some of the organs that are involved in excretion. The remainder of the lesson focuses on the excretion of carbon dioxide. Links are made to the transport of carbon dioxide as hydrogen carbonate ions and how the affinity of haemoglobin for oxygen is affected when the carbon dioxide concentration is high. Students will meet the idea of deamination and the ornithine cycle and the key details of these two processes are covered. Progress checks have been written into this lesson at regular intervals, which challenge the students on knowledge from this lesson and prior knowledge, to enable them to constantly assess their understanding.

This is a concise, fast-paced lesson that has been designed to enable students to discover the key structural features of a synapse and be able to write accurate descriptions of the sequence of events that occur at these structures. The neurotransmitter involved is acetyl choline and therefore this is specifically a lesson about cholinergic synapses. The lesson begins by going through the terminology associated with synapses which includes pre-synaptic terminal or knob, synaptic cleft and post-synaptic neurone. Then time is taken to look at each of the two neurones and the structures found inside the terminal or on the membranes. The main task of the lesson involves a step by step guide through the sequence of events at the synapse. This guide has been written in a bullet point format and students are challenged to use the features they have met and their own Biological knowledge to complete each point. The final part of the lesson looks at how the enzyme acetylcholinesterase is involved in the breakdown and then how the neurotransmitter is re-formed using the ATP generated in the mitochondria This lesson is written for A-level students

This is a fully-resourced REVISION lesson that consists of an engaging PowerPoint (87 slides) and associated worksheets that challenge the students on their knowledge of the content of Topic 1 (Lifestyle, Health and Risk) of the Edexcel A-Level Biology A (Salters-Nuffield) specification. A wide range of activities have been written into the lesson to maintain motivation and these tasks include exam questions (with answers), understanding checks, differentiated tasks and quiz competitions. The lesson has been designed to include as much which of the content from topic 1, but the following specification points have been given particular attention: The differences between monosaccharides, disaccharides and polysaccharides, including glycogen and starch (amylose and amylopectin). Be able to relate the structures of monosaccharides, disaccharides and polysaccharides to their roles in providing and storing energy Know how monosaccharides join to form disaccharides (sucrose, lactose and maltose) and polysaccharides (glycogen and amylose) through condensation reactions forming glycosidic bonds, and how these can be split through hydrolysis reactions. Know how a triglyceride is synthesised by the formation of ester bonds during condensation reactions between glycerol and three fatty acids. Understand the course of events that leads to atherosclerosis Know how factors such as genetics, diet, age, gender, high blood pressure, smoking and inactivity increase the risk of cardiovascular disease Know the benefits and risks of treatments for CVD Understand the blood-clotting process and its role in CVD Understand how the structures of arteries and veins) relate to their functions. Understand the importance of water as a solvent in transport, including its dipole nature. This lesson can be used at numerous points over the duration of the course, as an end of topic revision aid, in the lead up to the mocks or in the lead up to the actual A-level exams.

This engaging and detailed REVISION resource has been written to encourage students to evaluate their understanding of the content found in MODULE 4.1.1 (Communicable diseases, disease prevention and the immune system) of the OCR A-Level Biology specification. The resource contains a motivating PowerPoint (86 slides) and associated worksheets which have been differentiated to support students of differing abilities in their access of the work. The lesson includes a wide range of activities such as exam questions, quick tasks and quiz competitions to motivate the students whilst they recognise those areas of the specification which require even more attention. The lesson has been designed to cover as much of the content in module 4.1.1 as possible but the following sub-topics have been given particular attention: Communicable diseases caused by bacteria, viruses and fungi Bacteria as pathogens Antigen-presenting cells The specific immune response Antibiotics and the existence of resistant strains Preventing the spread of pathogens Vaccinations Primary defences of the human body In addition to content from this module, links are made to earlier modules and challenges posed so that students can see how connections between the modules have to be made to be successful. This resource is suitable for use at the end of the module, in the lead up to AS or A2 mocks or in the lead up to the actual A-level exams.

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 has been designed to cover the content set out in specification point 2.5 (g) of the WJEC GCSE Biology specification which states that students should understand that hormones are chemical messengers which control many body functions. A wide range of activities have been written into the lesson with the aim of engaging and motivating the students whilst ensuring that the content is covered in detail. These activities include a number of quiz competitions which will challenge the students to identify an endocrine organ when presented with three organs as well as introducing them to the names of some of the hormones released by the pituitary gland. The following content is covered in this lesson: The location of the pituitary, adrenal and thyroid glands in the human body The location of the pancreas, ovaries and testes in the human body The hormones which are secreted by the endocrine glands The effects of the hormones on their target organs This lesson has been written for GCSE-aged students who are studying on the WJEC Biology course but it is suitable for younger students who are looking at this as one of the different organ systems

This engaging lesson covers the final details of specification point 6.4.2 of the AQA A-level Biology specification which states that students should be able to describe the causes and control of diabetes mellitus type I and II. 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. This lesson has been designed for students taking the AQA A-level Biology course and runs alongside the uploaded lesson on the control of blood glucose concentration as well as the other lessons that have been added on topic 6

This is a fully-resourced lesson that covers the content of specification point 15.1 (k) of the CIE International A-level Biology specification which states that students should be able to explain the sliding filament model of muscular contraction. The wide range of activities included in the lesson will engage and motivate the students whilst the understanding and previous knowledge checks will not only allow them to assess their progress but also challenge them to make links to other Biology topics. The start of the lesson is designed to encourage the students to consider how a sarcomere can narrow but the lengths of the myofilaments can remain the same. In doing so, they will be introduced to the idea of the sliding filament model and the main task of the lesson involves the formation of a bullet point description of this model where one event is the trigger for the next. Time is taken during this section to focus on the involvement of the calcium ions but also ATP and the idea of the sources of this molecule, including creatine phosphate, are discussed in more detail later in the lesson. The final part of the lesson involves students having to apply their knowledge by describing the effect on muscle contraction when a part of a structure is unable to function correctly. This lesson has been designed for students studying the CIE International A-level Biology course and ties in well with the other uploaded lessons on this topic, particularly the lesson which covers the ultrastructure of striated muscle

This fully-resourced lesson looks at how heart rate is controlled by the cardiovascular control centre in the medulla oblongata. The engaging and detailed PowerPoint and accompanying resources have been designed to cover the first part of point 7.9 (ii) of the Pearson Edexcel A-level Biology A (Salters Nuffield) specification but also ties in well with previously covered topics and provides a good introduction to control systems which are covered later in topic 7 and 8. This lesson begins with a prior knowledge check where students have to identify and correct any errors in a passage about the conduction system of the heart. This allows the SAN to be recalled as this structure play an important role as the effector in this control system. Moving forwards, the three key parts of a control system are recalled as the next part of the lesson will specifically look at the range of sensory receptors, the coordination centre and the effector. Students are introduced to chemoreceptors and baroreceptors and time is taken to ensure that the understanding of the stimuli detected by these receptors is complete and that they recognise the result is the conduction of an impulse along a neurone to the brain. A quick quiz is used to introduce the medulla oblongata as the location of the cardiovascular centre. The communication between this centre and the SAN through the autonomic nervous system can be poorly understood so detailed explanations are provided and the sympathetic and parasympathetic divisions compared. The final task challenges the students to demonstrate and apply their understanding by writing a detailed description of the control and this task has been differentiated three ways to allow differing abilities to access the work