How plants use glucose lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability class, although content can be adjusted to suit any ability. Includes powerpoint timers, slide animations, embedded video’s, practice questions, peer assessment worksheet and mini review. *Top paper friendly tip: the information in the ‘How to use glucose’ worksheet can also be found in the textbook therefore isn’t required to be printed.* NB: If you are unable to play embedded videos please view slide notes for link. AQA spec link: 4.4.1.3 Relevant chapter: B8 Photosynthesis. AQA Biology third edition textbook-Page 128-129 Students are required to know the following; The glucose produced in photosynthesis may be: •• used for respiration •• converted into insoluble starch for storage •• used to produce fat or oil for storage •• used to produce cellulose, which strengthens the cell wall •• used to produce amino acids for protein synthesis. To produce proteins, plants also use nitrate ions that are absorbed from the soil. AT 8-Tests to identify starch, glucose and proteins using simple qualitative reagents

Aims In this activity students will use an aseptic (sterile) technique and a small part of a cauliflower ‘flower’ to clone and create an entirely new plant. Learning outcomes After completing this practical, students should be able to: • state why plant clones are genetically identical to each other • explain how using tissue culture creates a clone of a plant • explain why it is easier to clone a plant than an animal • explain and carry out a practical accurately and safely in order to successfully clone a plant. Specification references: B1.1.4 Cell differentiation B1.2.3 Stem cells

Stem cells dilemmas lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability separates class, although content can be adjusted to suit any ability. Includes: slide animations, embedded video, practice questions with answers on slides. AQA spec link: 4.1.2.3 Relevant chapter: B2 Cell division. AQA Biology third edition textbook-Page 32-33 Specification requires students to know the following; In therapeutic cloning an embryo is produced with the same genes as the patient. Stem cells from the embryo are not rejected by the patient’s body so they may be used for medical treatment. The use of stem cells has potential risks such as transfer of viral infection, and some people have ethical or religious objections. Stem cells from meristems in plants can be used to produce clones of plants quickly and economically. •• Rare species can be cloned to protect from extinction. •• Crop plants with special features such as disease resistance can be cloned to produce large numbers of identical plants for farmers.

Stem cells (introduction) lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability separates class, although content can be adjusted to suit any ability. Includes: slide animations, embedded video, practice questions with answers on slides. AQA spec link: 4.1.2.3 Relevant chapter: B2 Cell division. AQA Biology third edition textbook-Page 30-31 Specification requires students to know the following; A stem cell is an undifferentiated cell of an organism which is capable of giving rise to many more cells of the same type, and from which certain other cells can arise from differentiation. Students should be able to describe the function of stem cells in embryos, in adult animals and in the meristems in plants. Stem cells from human embryos can be cloned and made to differentiate into most different types of human cells. Stem cells from adult bone marrow can form many types of cells including blood cells. Meristem tissue in plants can differentiate into any type of plant cell, throughout the life of the plant. Knowledge and understanding of stem cell techniques are not required. Treatment with stem cells may be able to help conditions such as diabetes and paralysis

Rate of photosynthesis lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability class, although content can be adjusted to suit any ability. Includes powerpoint timers, slide animations, embedded video's and mini review. NB: If you are unable to play embedded videos please view slide notes for link. AQA spec link: 4.4.1.1 Relevant chapter: B8 Photosynthesis. AQA Biology third edition textbook-Page 126-127 Students are required to know the following; Students should be able to explain the effects of temperature, light intensity, carbon dioxide concentration, and the amount of chlorophyll on the rate of photosynthesis. Students should be able to: • measure and calculate rates of photosynthesis • extract and interpret graphs of photosynthesis rate involving one limiting factor •plot and draw appropriate graphs selecting appropriate scale for axes •translate information between graphical and numeric form. Solve simple algebraic equations. MS 1a, 1c, 2c, 4a, 4c (HT only) These factors interact and any one of them may be the factor that limits photosynthesis. (HT only) Students should be able to explain graphs of photosynthesis rate involving two or three factors and decide which is the limiting factor. (HT only) Students should understand and use inverse proportion – the inverse square law and light intensity in the context of photosynthesis. (HT only) Limiting factors are important in the economics of enhancing the conditions in greenhouses to gain the maximum rate of photosynthesis while still maintaining profit. (HT only) WS 1.4 Use data to relate limiting factors to the cost effectiveness of adding heat, light or carbon dioxide to greenhouses.

This lesson has been improved, it contains two lessons worth of content and now includes an optional practical activity Photosynthesis lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability class, although content can be adjusted to suit any ability. Includes powerpoint timers, slide animations, embedded video’s, optional practical and mini review. NB: If you are unable to play embedded videos please view slide notes for link. AQA spec link: 4.4.1.1 Relevant chapter: B8 Photosynthesis. AQA Biology third edition textbook-Page 124-125 Students are required to know the following; Photosynthesis is represented by the equation: carbon dioxide + water (light) glucose + oxygen Students should recognise the chemical symbols: CO2, H2O, O2 and C6H12O6. Students should be able to describe photosynthesis as an endothermic reaction in which energy is transferred from the environment to the chloroplasts by light.

Growth and differentiation lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability separates class, although content can be adjusted to suit any ability. Includes: slide animations, embedded video, practice questions with answers on slides. AQA spec link: 4.1.1.4 Relevant chapter: B2 Cell division. AQA Biology third edition textbook-Page 28-29 Specification requires students to know the following; Students should be able to explain the importance of cell differentiation. As an organism develops, cells differentiate to form different types of cells. • Most types of animal cell differentiate at an early stage. ••Many types of plant cells retain the ability to differentiate throughout life. In mature animals, cell division is mainly restricted to repair and replacement. As a cell differentiates it acquires different sub-cellular structures to enable it to carry out a certain function. It has become a specialised cell.

Cell division (mitosis) lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability separates class, although content can be adjusted to suit any ability. Includes: slide animations, practice questions with answers on slides and worksheet. AQA spec link: 4.1.2.1 & 4.1.2.2 Relevant chapter: B2 Cell division. AQA Biology third edition textbook-Page 26-27 Specification requires students to know the following; The nucleus of a cell contains chromosomes made of DNA molecules. Each chromosome carries a large number of genes. In body cells the chromosomes are normally found in pairs. Cells divide in a series of stages called the cell cycle. Students should be able to describe the stages of the cell cycle, including mitosis. During the cell cycle the genetic material is doubled and then divided into two identical cells. Before a cell can divide it needs to grow and increase the number of sub-cellular structures such as ribosomes and mitochondria. The DNA replicates to form two copies of each chromosome. In mitosis one set of chromosomes is pulled to each end of the cell and the nucleus divides. Finally the cytoplasm and cell membranes divide to form two identical cells. Students need to understand the three overall stages of the cell cycle but do not need to know the different phases of the mitosis stage. Cell division by mitosis is important in the growth and development of multi-cellular organisms. Students should be able to recognise and describe situations in given contexts where mitosis is occurring.

Diet, exercise and disease lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability class, although content can be adjusted to suit any ability. Includes powerpoint timers, slide animations, embedded video's, worksheet and mini review. NB: If you are unable to play embedded videos please view slide notes for link. AQA spec link: 4.2.2.6 Relevant chapter: B7 Non-communicable diseases. AQA Biology combined textbook-Page 104-105 Students are required to know the following; • discuss the human and financial cost of these non-communicable diseases to an individual, a local community, a nation, or globally • explain the effect of lifestyle factors including diet, alcohol, and smoking on the incidence of non-communicable diseases at local, national, and global levels. Risk factors are linked to an increased rate of a disease. They can be: • aspects of a person’s lifestyle • substances in the person’s body or environment. A causal mechanism has been proven for some risk factors, but not in others. • The effects of diet and exercise on cardiovascular disease. • Obesity as a risk factor for Type 2 diabetes. Many diseases are caused by the interaction of a number of factors. Students should be able to understand the principles of sampling as applied to scientific data in terms of risk factors. Students should be able to translate information between graphical and numerical forms; and extract and interpret information from charts, graphs and tables in terms of risk factors. Students should be able to use a scatter diagram to identify a correlation between two variables in terms of risk factors.

Alcohol and other carcinogens lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability class, although content can be adjusted to suit any ability. Includes powerpoint timers, slide animations, embedded video's, worksheet and mini review. NB: If you are unable to play embedded videos please view slide notes for link. AQA spec link: 4.2.2.6 Relevant chapter: B7 Non-communicable diseases. AQA Biology combined textbook-Page 106-107 Students are required to know the following; A causal mechanism has been proven for some risk factors, but not in others. • The effect of alcohol on the liver and brain function. • The effects of alcohol on unborn babies. • Carcinogens, including ionising radiation, as risk factors in cancer. Many diseases are caused by the interaction of a number of factors. Students should be able to understand the principles of sampling as applied to scientific data in terms of risk factors. Students should be able to translate information between graphical and numerical forms; and extract and interpret information from charts, graphs and tables in terms of risk factors. Students should be able to use a scatter diagram to identify a correlation between two variables in terms of risk factors.

Exchanging materials lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability separates class, although content can be adjusted to suit any ability. Includes: slide animations, practice questions with answers on slides, worksheet, and homework (with MS) AQA spec link: 4.1.3.1 Relevant chapter: B1 Cell structure and transport. AQA Biology third edition textbook-Page 22-23 Specification requires students to know the following; A single-celled organism has a relatively large surface area to volume ratio. This allows sufficient transport of molecules into and out of the cell to meet the needs of the organism. Students should be able to calculate and compare surface area to volume ratios. Students should be able to explain the need for exchange surfaces and a transport system in multicellular organisms in terms of surface area to volume ratio. Students should be able to explain how the small intestine and lungs in mammals, gills in fish, and the roots and leaves in plants, are adapted for exchanging materials. In multicellular organisms, surfaces and organ systems are specialised for exchanging materials. This is to allow sufficient molecules to be transported into and out of cells for the organism’s needs. The effectiveness of an exchange surface is increased by: •• having a large surface area •• a membrane that is thin, to provide a short diffusion path •• (in animals) having an efficient blood supply •• (in animals, for gaseous exchange) being ventilated.

Active transport lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability separates class, although content can be adjusted to suit any ability. Includes: slide animations, practice questions with answers on slides, worksheet. AQA spec link: 4.1.3.3 Relevant chapter: B1 Cell structure and transport. AQA Biology third edition textbook-Page 20-21 Specification requires students to know the following; Active transport moves substances from a more dilute solution to a more concentrated solution (against a concentration gradient). This requires energy from respiration. Active transport allows mineral ions to be absorbed into plant root hairs from very dilute solutions in the soil. Plants require ions for healthy growth. It also allows sugar molecules to be absorbed from lower concentrations in the gut into the blood which has a higher sugar concentration. Sugar molecules are used for cell respiration. Students should be able to: •• describe how substances are transported into and out of cells by diffusion, osmosis and active transport •• explain the differences between the three processes.

I've attached an applied science-revision checklist. It's essentially a copy of the Pearson applied science specification-I've just broken it down and chunked relevant topics. I have handed this to students so they can use it as a revision tool. Hope it helps. I've also made a checklist for the physics and chemistry unit.

**Please note this lesson has been updated ** Smoking and the risk of disease lesson created in accordance to the NEW AQA Specification (9-1). Designed for a higher ability class, although content can be adjusted to suit any ability. Includes powerpoint timers, slide animations, embedded video’s, worksheet and mini review. NB: If you are unable to play embedded videos please view slide notes for link, i have also included practical instructions in the notes. AQA spec link: 4.2.2.6 Relevant chapter: B7 Non-communicable diseases. AQA Biology combined textbook-Page 104-105 Specification requires students to know the following; Risk factors are linked to an increased rate of a disease. They can be: •• aspects of a person’s lifestyle •• substances in the person’s body or environment. A causal mechanism has been proven for some risk factors, but not in others. •• The effect of alcohol on the liver and brain function. •• The effect of smoking on lung disease and lung cancer. •• The effects of smoking and alcohol on unborn babies. •• Carcinogens, including ionising radiation, as risk factors in cancer. Many diseases are caused by the interaction of a number of factors.

Gene expression and mutation lesson created in accordance to the NEW AQA Specification (9-1). NB: BIOLOGY ONLY-HT. Designed for higher ability class, although content can be adjusted to suit any ability. Includes: embedded videos and timers, slide animations, practice questions with answers on slides. AQA spec link: 6.1.5 Relevant chapter: B13 Genetics and reproduction. AQA Biology third edition textbook-Page 206-207. Specification requires students to know the following; (HT only) Mutations occur continuously. Most do not alter the protein, or only alter it slightly so that its appearance or function is not changed. (HT only) A few mutations code for an altered protein with a different shape. An enzyme may no longer fit the substrate binding site or a structural protein may lose its strength. (HT only) Not all parts of DNA code for proteins. Non-coding parts of DNA can switch genes on and off, so variations in these areas of DNA may affect how genes are expressed.

DNA structure and protein synthesis lessons created in accordance to the NEW AQA Specification (9-1). NB: BIOLOGY ONLY. I taught this topic in two lessons as it's a topic that's a difficult concept and can be taught effectively as opposed to being rushed. This resource is designed for higher ability class, although content can be adjusted to suit any ability. Includes: embedded videos and timers, slide animations, practice questions with answers on slides, worksheets and an interactive quiz. AQA spec link: 6.1.5 Relevant chapter: B13 Genetics and reproduction. AQA Biology third edition textbook-Page 204-205. Students should be able to describe DNA as a polymer made from four different nucleotides. Each nucleotide consists of a common sugar and phosphate group with one of four different bases attached to the sugar. DNA contains four bases, A, C, G and T. A sequence of three bases is the code for a particular amino acid. The order of bases controls the order in which amino acids are assembled to produce a particular protein. The long strands of DNA consist of alternating sugar and phosphate sections. Attached to each sugar is one of the four bases. The DNA polymer is made up of repeating nucleotide units. (HT only) Students should be able to: •• recall a simple description of protein synthesis •• explain simply how the structure of DNA affects the protein made •• describe how genetic variants may influence phenotype: a) in coding DNA by altering the activity of a protein: and b) in non-coding DNA by altering how genes are expressed. (HT only) In the complementary strands a C is always linked to a G on the opposite strand and a T to an A. (HT only) Students are not expected to know or understand the structure of mRNA, tRNA, or the detailed structure of amino acids or proteins. (HT only) Students should be able to explain how a change in DNA structure may result in a change in the protein synthesised by a gene. (HT only) Proteins are synthesised on ribosomes, according to atemplate. Carrier molecules bring specific amino acids to add to the growing protein chain in the correct order. (HT only) When the protein chain is complete it folds up to form a unique shape. This unique shape enables the proteins to do their job as enzymes, hormones or forming structures in the body such as collagen.