This lesson describes how large molecules are hydrolysed to smaller molecules by the enzymes produced by the digestive system in mammals. The detailed PowerPoint and accompanying worksheets are part of the 1st lesson in a series of 2 which have been designed to cover the content of point 3.3 of the AQA A-level Biology specification and this lesson includes descriptions of the action of amylase, disaccharidases, lipase, endopeptidases, exopeptidases and dipeptidases. The lesson has been designed to walk the students through the functions of the digestive system at each point of the digestive tract up until the duodenum and focuses on the action of the enzymes produced in the mouth, stomach and small intestine and by the accessory organs of the system. Time is taken to describe and explain key details, such as the fact that endopeptidases cleave peptide bonds within the molecules, meaning that they cannot break down proteins into monomers. The lesson is filled with exam-style questions which will develop their understanding of the current topic as well as checking on their knowledge of related topics which have been previously-covered such as the structure of the biological molecules and qualitative tests. In addition to the detailed content and regular questioning, the lesson PowerPoint contains guided discussion periods and two quick quiz competitions which introduce a key term and a key value in a fun and memorable way This lesson has been specifically planned to prepare the students for the very next lesson where the mechanisms for the absorption of the products of digestion are described.

This lesson describes the action of bactericidal and bacteriostatic antibiotics, as illustrated by penicillin and tetracycline. The engaging PowerPoint and accompanying resources have been designed to cover point 6.3 (i) of the Edexcel A-level Biology B specification but it has been specifically planned to make continual links to earlier lessons in topic 6 and to protein synthesis as covered in topic 1 The lesson begins by challenging the students to use their general biological knowledge and any available sources to identify the suffixes cidal and static. Students will learn that when the prefix is added, these form the full names of two types of antibiotics. Their understanding of terminology is tested further as they have to recognise that Polymyxin B is an example of a bactericidal antibiotic as its actions would result in the death of the bacterial cell. Time is then taken to describe the action of penicillin and students will learn how inhibitors and modified versions of this antibiotic are used to overcome those bacteria who have resistance. Tetracycline is used as the example of a bacteriostatic antibiotic and students will discover that its prevention of the binding of tRNA that inhibits protein synthesis and this reduction and stopping of growth and reproduction is synonymous with these drugs. Students are challenged on their knowledge of translation and will also be given time for a class discussion to understand that these antibiotics encourage the body’s immune system to overcome the pathogen in natural, active immunity. The final part of the lesson uses a quick quiz competition and a series of exam-style questions to ensure that students can recognise these different types of antibiotics from descriptions.

This lesson describes the structure of DNA as a double-stranded polymer coiled into a double helix and focuses on nucleotides as the monomers. The PowerPoint and accompanying resources have been designed to cover the detail of point 3.4 of the Edexcel GCSE Biology & Combined Science specifications. The lesson begins with a reveal of the acronym DNA and students will learn that this stands for deoxyribonucleic acid. There is a focus on the use and understanding of key terminology throughout the lesson so time is taken to look at the meanings of the prefixes poly and mono as well as the suffix -mer. This leads into the description of DNA as a polymer which is made up of many monomers known as nucleotides. Students will be introduced to the three components of a DNA nucleotide and will learn that four different bases can be attached to the sugar. An observational task is used to get them to recognise that DNA consists of two strands and that complementary bases are joined by hydrogen bonds. Understanding checks are interspersed throughout the lesson along with mark schemes so that students can assess their progress

This lesson describes the biological meaning of species, populations, gene pool and allele frequency and explains how these terms are linked. The PowerPoint and accompanying resources are part of the 1st lesson in a series of 2 lessons that cover the detail of specification point 7.2 (Populations) of the AQA A-level biology. The two living species of the African elephant, the forest and bush elephant, are used as examples to demonstrate the meaning of species and to show how they exist as one or more populations. A quick quiz introduces the term gene pool in an engaging way and then the allele frequency of three versions of the GBA gene demonstrates how these frequencies can change in small populations. In doing so, students are briefly introduced to genetic drift which they will encounter in an upcoming topic. The students are challenged throughout the lesson with understanding checks and prior knowledge checks as well as exam-based questions where they have to comment on the validity of a scientist’s conclusion. The other lesson in topic 7.2 is the Hardy-Weinberg principle.

This engaging and fully-resourced lesson looks at examples of stabilising, directional and disruptive selection as the three main types of selection. The PowerPoint and accompanying resources have been designed to cover the 1st part of point 6.1.2 (e) of the OCR A-level Biology specification which states that students should be able to demonstrate and apply an understanding of the factors that affect the evolution of a species. The lesson begins by making a link to a topic from module 4 as the students are challenged to use the mark, release, recapture method to calculate numbers of rabbits with different coloured fur in a particular habitat. Sketch graphs are then constructed to show the changes in the population size in this example. A quick quiz competition is used to engage the students whilst introducing the names of the three main types of selection before a class discussion point encourages the students to recognise which specific type of selection is represented by the rabbits. Key terminology including intermediate and extreme phenotypes and selection pressure are used to emphasise their importance during explanations. A change in the environment of the habitat and a change in the numbers of the rabbits introduces directional selection before students will be given time to discuss and to predict the shape of the sketch graph for disruptive selection. Students are challenged to apply their knowledge in the final task of the lesson by choosing the correct type of selection when presented with details of a population and answer related questions. This lesson has been designed to tie in with another uploaded lesson on genetic drift which covers the second part of this specification point.

This fully-resourced lesson explores how projects to sequence the genomes of both simple and complex organisms can be used. Both the detailed PowerPoint and accompanying resources have been designed to cover the content of point 8.3 of the AQA A-level Biology specification. The start of the lesson describes each step of Sanger’s chain termination method and demonstrates how this method has paved the way for other projects. The use of the modified nucleotides are explained and links are made to the topic 4 and 2 where protein synthesis and DNA replication were first introduced. Students will learn how the radioactively-labelled nucleotide at the end of each fragment allows the next base to be determined. Key processes like gel electrophoresis are introduced and details provided to support the students when this is encountered in greater detail in 8.4.3. Moving forwards, the applications of sequencing in simple organisms like viruses and bacteria are explored and the students are challenged on their prior knowledge of bacterial pathogenesis and current understanding of sequencing through a series of exam-style questions. The final part of the lesson looks at the difficulties of translating genome knowledge into proteome knowledge and considers the development of automated methods. Due to the detail and extensiveness of this lesson, it is estimated that it will take in excess of 2 hours of allocated A-level teaching time to cover all of the points which have been written into the various tasks

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.

This detailed lesson describes the specific stages of the aerobic energy system and has been designed for the OCR A-level PE course. In line with the specification content in “Energy systems and ATP resynthesis”, the lesson describes the type of reaction, the sites of the specific stages within the system, the fuel used, the controlling enzymes, the ATP yield and the bi-products. The lesson begins by introducing the aerobic system as the system that becomes the dominant energy provider after the ATP-PC and glycolytic system. Students are challenged to recognise that this system supports lower intensity exercise but that it will support exercise for a much longer duration than the others, suggesting that it produces a high yield of ATP. The main part of the lesson looks at how this high yield of ATP is produced during glycolysis, the Krebs cycle and the electron transport chain and students will learn the location of each of these stages in the cell. Questions, discussion points and quiz competitions are included throughout the lesson and act as understanding checks to ensure that any misconceptions are addressed immediately. The final tasks of the lesson are a series of multiple choice questions and a quiz round called “UNLOCK THE AEROBIC SYSTEM SAFE” where the teams of students compete to recall the quantitative values associated with this topic.

This engaging lesson describes the relationship between the structure, properties and functions of a phopholipid and cholesterol. The PowerPoint has been written as the second lesson in a series of two that cover specification points 2.1.2 (h), (i) & (j) of the OCR A-level Biology A course and there is a particular focus on their roles in membranes to link to module 2.1.5. In the previous lesson, the students met triglycerides and a quick quiz round called FAMILY AFFAIR is used at the start of the lesson to challenge the students on their knowledge of the structure of this macromolecule to identify the shared features in a phospholipid. This then allows the differences to be introduced, such as the presence of a phosphate group in place of the third fatty acid. Moving forwards, the students will learn that the two fatty acid tails are hydrophobic whilst the phosphate head is hydrophilic which leads into a key discussion point where the class has to consider how it is possible for the phospholipids to be arranged when both the inside and outside of a cell is an aqueous solution. The outcome of the discussion is the introduction of the bilayer which is critical for the lesson in module 2.1.5 on the fluid mosaic model. Students are briefly introduced to facilitated diffusion and reminded of active transport so they can recognise that proteins will be found in the membrane to allow for movement of large or polar molecules. The remainder of the lesson focuses on cholesterol, beginning with the structure. The hydrophobic nature of this molecule is then considered and discussed so that they can understand its role in the regulation of membrane fluidity. That just leaves one final quiz round which identifies vitamin D, testosterone and oestrogen as three substances that are formed from cholesterol

This fully-resourced lesson describes the regulatory mechanisms that control gene expression at a transcriptional level. The detailed PowerPoint and accompanying resources have been designed to cover the first part of point 6.1.1 (b) as detailed in the OCR A-level Biology A specification which states that the students knowledge should include the lac operon and examples of transcription factors in eukaryotes. . This is one of the more difficult concepts in this A-level course and therefore key points are reiterated throughout this lesson to increase the likelihood of student understanding and to support them when trying to make links to actual biological examples in living organisms. There is a clear connection to transcription and translation as covered in module 2.1.3, so the lesson begins by reminding students that in addition to the structural gene in a transcription unit, there is the promotor region where RNA polymerase binds. Students are introduced to the idea of transcription factors and will understand how these molecules can activate or repress transcription by enabling or preventing the binding of the enzyme. At this point, students are challenged on their current understanding with a series of questions about DELLA proteins so they can see how these molecules prevent the binding of RNA polymerase. Their understanding is then tested again with another example with oestrogen and the ER receptor. The final and main section of the lesson focuses on the lac operon and immediately an opportunity is taken to challenge their knowledge of biological molecules with a task where they have to spot the errors in a passage describing the formation and breakdown of this disaccharide. Students will be able to visualise the different structures that are found in this operon and time is taken to go through the individual functions. A step by step guide is used to walk students through the sequence of events that occur when lactose is absent and when it is present before they are challenged to apply their understanding to an exam question.

This lesson describes how communication occurs between cells by cell signalling. The PowerPoint and accompanying resource have been designed to cover point 5.1.1 (b) of the OCR A-level Biology A specification and focuses on the use of the nervous system for communication between the CNS and effectors and the release of hormones to bring about responses. As this is one of the first lessons to be delivered in module 5, this lesson has been specifically planned to prepare students for the upcoming topics of neuronal and hormonal communication. Students begin by learning that cell signalling governs the basic activities of cells and coordinates multiple cell actions. Moving forwards, the next part of the lesson focuses on the nervous system and students will learn that an electrical impulse will be conducted on a somatic or an autonomic motor neurone depending upon the type of muscle to be stimulated. This provides some introductory information for modules 5.1.3 and 5.1.5. The remainder of the lesson describes how the hormones that are secreted by the cells of endocrine glands allow communication with target cells and the different actions of peptide and steroid hormones is considered.

This fully-resourced lesson describes how to calculate the concentration of solution in grams per decimetres cubed and mol per decimetre cubed. The lesson PowerPoint and accompanying questions which are differentiated have been designed to cover points 1.49 & 5.8 of the Edexcel GCSE Chemistry specification. The lesson begins by introducing students to volumes in decimetres cubed and time is taken to ensure that students are able to convert to this measurement from volumes in centimetres cubed. Moving forwards, students are shown how to calculate the concentration in both units through the use of worked examples and then they are challenged to apply this to a series of exam-style questions which have been differentiated so students of differing abilities can access the work

This lesson describes the gross structure of the human gas exchange system and the functions of the structural components like goblet cells. The PowerPoint and accompanying resources have been designed to cover points 9.1 (a & c) of the CIE A-level Biology specification and has been specifically planned to prepare students for an upcoming lesson where the gas exchange between the alveoli and the blood is described. The lesson is filled with a range of activities such as guided discussion periods, exam-style questions (with markschemes) and quiz competitions and these run alongside the slides containing the detailed A-level Biology content to cover the following features: The incomplete rings of cartilage, ciliated pseudostratified columnar epithelium and goblet cells in the trachea The narrowing airways of the primary, secondary and tertiary bronchi The elastic fibres and smooth muscle in the terminal and respiratory bronchioles The pleural cavity and fluid of the lungs When describing the production of mucus by the goblet cells in the trachea, time is taken to consider cystic fibrosis and the inheritance of this autosomal recessive disorder. Students will be supported in working out genotypes from a pedigree tree to prepare them for topic 16 (Inherited change)

This lesson describes the in situ and ex situ methods of maintaining biodiversity, and discusses the advantages and disadvantages associated with both. The engaging PowerPoint and accompanying worksheets have been primarily designed to cover point 4.2.1 (h) of the OCR A-level Biology A specification but the lesson has been carefully planned to enable links to be made to some related topics which are found later in the course such as classification, evolution through natural selection and the Founder effect. Hours of research has gone into the planning of this lesson to source interesting examples that increase the relevance of the biological content concerning in situ conservation, and these include the Lizard National Nature Reserve in Cornwall, the Lake Télé Community reserve in the Republic of Congo and the marine conservation zone in the waters surrounding Tristan da Cunha. Students will learn how this form of active management conserves habitats and species in their natural environment, with the aim of minimising human impact whilst maintaining biodiversity. The main issues surrounding this method are discussed, including the fact that the impact of this conservation may not be significant if the population has lost much of its genetic diversity and that despite the management, the conditions that caused the species to become endangered may still be present. A number of quick quiz competitions are interspersed throughout the lesson to introduce key terms and values in a fun and memorable way and one of these challenges them to use their knowledge of famous scientists to reveal the surname, Fossey. Dian Fossey was an American conservationist and her years of study of the mountain gorillas is briefly discussed along with the issue that wildlife reserves can draw poachers and tourists to the area, potentially disturbing the natural habitat. To enrich their understanding of ex situ conservation, the better known examples of ZSL London zoo, Kew Gardens and the Millennium Seed Bank Project in Wakehurst are used. Students will understand how conserving animal species outside of their natural habitat enables human intervention that ensures the animals are fed and given medical assistance when needed as well as reproductive assistance to increase the likelihood of the successful breeding of endangered species. As with the in situ method, the disadvantages are also discussed and there is a focus on the susceptibility of captive populations to diseases as a result of their limited genetic diversity. The final part of the lesson considers how seed banks can be used to ensure that plant species avoid extinction and how the plants can be bred asexually to increase plant populations quickly. Due to the extensiveness of this lesson, it is estimated that it will take in excess of 2/3 hours of allocated A-level teaching time to cover the tasks and content that is included in the lesson.

An informative lesson presentation (26 slides) that shows students how to convert between numbers and standard form (and the other way) so they are able to understand when these are used in Science questions. The lesson begins by guiding them through how to change numbers to standard form and explains when a power of 10 that is positive will be achieved and when it will be negative. Students are given the opportunity to see these used in a Science question and there is a cross-subject link as they are also required to convert between units. A number of competitions are used near the end of the lesson to maintain motivation and to allow the students to check their progress in a fun way This lesson has been designed for GCSE students but is suitable for KS3