Cell Biology and Biodiversity

Chemicals of Life - Composition, properties and functions of proteins
Chemicals of Life - Composition, properties and functions of lipids
Chemicals of Life - Composition, properties and functions of vitamins

By the end of the lesson, the learner should be able to:

- Describe the composition, properties and functions of proteins
- Investigate the presence of proteins in food substances using the Biuret test
- Relate knowledge of proteins to real life examples such as why eggs and beans are recommended for body building and why high fever can be dangerous as it denatures body proteins

- Describe the properties, sources, functions and deficiency symptoms of vitamins A, B complex, C, D, E and K
- Investigate the presence of vitamin C in food substances using DCPIP solution
- Relate vitamin knowledge to real life examples such as why eating fresh fruits prevents scurvy, why carrots improve night vision and why sunlight exposure helps strengthen bones

- Discuss the composition of proteins including carbon, hydrogen, oxygen, nitrogen and sulphur
- Discuss properties of proteins including amphoteric nature, denaturation and hydrolysis
- Carry out a practical activity to test for the presence of proteins using the Biuret test

- Use reference materials to search for information on the properties, sources and functions of vitamins
- Discuss the classification of vitamins into water-soluble and fat-soluble vitamins
- Carry out a practical activity to test for the presence of vitamin C using DCPIP solution

How are proteins important in living organisms?
What is the role of vitamins in the body?

- Distinction Biology Learner's Book Grade 10 pg. 81
- Egg white, sodium hydroxide, copper (II) sulphate
- Test tubes, measuring cylinder
- Distinction Biology Learner's Book Grade 10 pg. 85
- Cooking oil, ethanol, distilled water, filter paper

- Distinction Biology Learner's Book Grade 10 pg. 91
- DCPIP solution, lemon juice, test tubes
- Measuring cylinder, dropper

- Oral questions - Observation - Practical assessment

Cell Biology and Biodiversity

Chemicals of Life - Enzymes: Meaning and properties of enzymes
Chemicals of Life - Investigating the presence of catalase enzymes in living tissues

By the end of the lesson, the learner should be able to:

- Define enzymes and explain their role as biological catalysts
- Describe the properties of enzymes including specificity, reusability and protein nature
- Relate enzyme function to real life examples such as how saliva breaks down starch in the mouth during digestion and how enzyme-based detergents remove stains from clothes

- Use print and non-print media to search for the meaning of enzymes
- Discuss the naming of enzymes based on their substrates
- Discuss the properties of enzymes including their protein nature, specificity, reusability and sensitivity to temperature and pH

What are enzymes and how do they function?

- Distinction Biology Learner's Book Grade 10 pg. 94
- Digital resources
- Internet access
- Distinction Biology Learner's Book Grade 10 pg. 96
- Fresh and boiled potato or liver, hydrogen peroxide
- Test tubes, wooden splint, scalpel

- Oral questions - Observation - Written assignments

Cell Biology and Biodiversity

Chemicals of Life - Factors affecting enzyme activity: Temperature and pH

By the end of the lesson, the learner should be able to:

- Determine the effect of temperature on enzyme activity through experiments
- Determine the effect of pH on enzyme activity through experiments
- Relate factors affecting enzymes to real life examples such as why food is stored in refrigerators to slow spoilage and why the stomach produces acid for digestion by pepsin

- Carry out a practical activity to investigate the effect of temperature on enzyme activity using amylase and starch solution at different temperatures
- Carry out a practical activity to investigate the effect of pH on enzyme activity using pepsin and egg albumen
- Draw graphs showing the effect of temperature and pH on enzyme activity

How do temperature and pH affect enzyme activity?

- Distinction Biology Learner's Book Grade 10 pg. 98
- Amylase, starch solution, iodine solution, pepsin
- Water baths, HCl, NaOH, test tubes, thermometer

- Oral questions - Observation - Practical assessment

Cell Biology and Biodiversity

Chemicals of Life - Factors affecting enzyme activity: Substrate and enzyme concentration

By the end of the lesson, the learner should be able to:

- Determine the effect of substrate concentration on enzyme activity through experiments
- Determine the effect of enzyme concentration on enzyme activity through experiments
- Relate substrate and enzyme concentration to real life examples such as why adding more yeast speeds up dough rising in baking and how enzyme inhibitors in pesticides control pests

- Carry out a practical activity to investigate the effect of substrate concentration on enzyme activity using hydrogen peroxide at different concentrations
- Carry out a practical activity to investigate the effect of enzyme concentration using pepsin at different concentrations
- Discuss enzyme inhibitors, cofactors and co-enzymes

How do substrate and enzyme concentration affect enzyme activity?

- Distinction Biology Learner's Book Grade 10 pg. 102
- Hydrogen peroxide at different concentrations, potato or liver
- Pepsin, egg white, HCl, test tubes, water bath

- Oral questions - Observation - Practical assessment

Cell Biology and Biodiversity

Chemicals of Life - Functions of water and mineral salts
Chemicals of Life - Importance of chemical components in cells

By the end of the lesson, the learner should be able to:

- Describe the functions of water in living organisms
- Describe the sources and functions of mineral salts in living organisms
- Relate functions of water and mineral salts to real life examples such as why drinking water is essential for body temperature regulation, why iron-rich foods prevent anaemia and why calcium is important for strong bones and teeth

- Examine packaging labels of common food products to identify chemical components, preservatives, colourings and expiry dates
- Explain the importance of chemical components in cells for growth, energy production and life processes
- Relate food labelling to real life consumer decisions such as checking expiry dates before buying food and reading nutritional information to make healthy dietary choices

- Use print and non-print media to search for information on the functions of water in living organisms
- Discuss the functions of water including medium for chemical reactions, transport, temperature regulation, excretion and solvent
- Discuss sources and functions of mineral salts including calcium, iron, iodine, phosphorus and sodium

- Examine packaging labels of common food products such as mineral water, salt, flour and cooking oil
- Identify the quality marks, preservatives, colourings, date of manufacture and expiry on the labels
- Discuss the importance of knowing the chemical components in food substances for health and safety

Why are water and mineral salts important in living organisms?
Why is it important to know the chemical components in food products?

- Distinction Biology Learner's Book Grade 10 pg. 104
- Charts showing sources of mineral salts
- Digital resources

- Distinction Biology Learner's Book Grade 10 pg. 106
- Packaging labels of common food products
- Digital resources

- Oral questions - Observation - Written assignments

Anatomy and Physiology of Plants

Nutrition - Types of nutrition in plants (Autotrophism and Heterotrophism)

By the end of the lesson, the learner should be able to:

- Describe the meaning of autotrophism and heterotrophism in plants
- Classify plants according to their mode of nutrition
- Recognise that plants in the local environment use different strategies to obtain nutrients

- Search for information from print and non-print media on the types of nutrition in plants and share with peers
- Study pictures showing autotrophic and heterotrophic plants and identify their modes of nutrition
- Discuss the meaning of autotrophism and heterotrophism with classmates

How do plants obtain nutrients from their environment?

- Distinction Biology Learner's Book Grade 10 pg. 107
- Digital resources
- Charts showing autotrophic and heterotrophic plants

- Oral questions - Observation - Written assignments

Anatomy and Physiology of Plants

Nutrition - Parasitism as a mode of nutrition in plants

By the end of the lesson, the learner should be able to:

- Explain parasitism as a mode of heterotrophic nutrition in plants
- Distinguish between full and partial parasitic plants
- Identify parasitic plants in the local environment and explain their impact on host plants

- Brainstorm on the meaning of parasitism as a mode of nutrition in heterotrophic plants
- Study pictures of parasitic plants and describe how they depend on host plants for survival
- Discuss examples of parasitic plants in the local environment

How do parasitic plants obtain nutrients from their host?

- Distinction Biology Learner's Book Grade 10 pg. 109
- Digital resources
- Pictures of parasitic plants

- Oral questions - Observation - Written assignments

Anatomy and Physiology of Plants

Nutrition - Saprophytic, symbiotic and insectivorous modes of nutrition
Nutrition - Structure of the chloroplast

By the end of the lesson, the learner should be able to:

- Describe saprophytic, symbiotic and insectivorous modes of nutrition in plants
- Compare and contrast the different heterotrophic modes of nutrition
- Relate the survival strategies of insectivorous plants to nutrient-deficient habitats such as swamps

- Search for information on saprophytic, symbiotic and insectivorous modes of nutrition using print and non-print media
- Study pictures of venus flytrap and pitcher plants and discuss how they trap insects
- Discuss the nutrients obtained by insectivorous plants from insects

Why do some plants trap and digest insects?

- Distinction Biology Learner's Book Grade 10 pg. 110
- Digital resources
- Pictures/charts of insectivorous plants
- Distinction Biology Learner's Book Grade 10 pg. 112
- Charts/diagrams of chloroplast structure

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Nutrition - Function of the chloroplast in plants

By the end of the lesson, the learner should be able to:

- Relate the structure of the chloroplast to its function in plant cells
- Explain the role of chlorophyll, grana and stroma in photosynthesis
- Link the abundance of chloroplasts in palisade cells to why the upper leaf surface is the main site for food manufacture

- Discuss the structure of the chloroplast in relation to its function (chlorophyll traps light, grana provide large surface area, stroma has enzymes)
- Use reference materials to search for information on the function of chloroplast in plants

How does the structure of the chloroplast enable it to carry out its function?

- Distinction Biology Learner's Book Grade 10 pg. 113
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Nutrition - The process of photosynthesis
Nutrition - The light stage of photosynthesis
Nutrition - The dark stage of photosynthesis
Nutrition - Comparing the light and dark stages of photosynthesis

By the end of the lesson, the learner should be able to:

- Define photosynthesis and state the word equation for the process
- Identify the raw materials, conditions and products of photosynthesis
- Relate photosynthesis to everyday food production such as farming and kitchen gardening

- Describe the dark (light independent) stage of photosynthesis
- Illustrate the dark stage of photosynthesis using a word equation
- Explain how glucose from the dark stage is eventually stored as starch in foods like potatoes and cereals

- Watch animations/video clips on the process of photosynthesis and discuss observations
- Identify the raw materials (water and carbon (IV) oxide), conditions (light and chlorophyll) and products (glucose and oxygen) of photosynthesis
- Write the word equation for photosynthesis
- Discuss the dark stage of photosynthesis (carbon (IV) oxide fixation)
- Illustrate the dark stage using word equations showing combination of carbon (IV) oxide and hydrogen atoms to form glucose and water
- Identify the site of dark stage in the chloroplast (stroma)

What are the raw materials and products of photosynthesis?
How is carbon (IV) oxide fixed during the dark stage of photosynthesis?

- Distinction Biology Learner's Book Grade 10 pg. 114
- Digital resources
- Internet access
- Distinction Biology Learner's Book Grade 10 pg. 115
- Charts/flow charts
- Distinction Biology Learner's Book Grade 10 pg. 116
- Digital resources
- Charts/flow charts
- Distinction Biology Learner's Book Grade 10 pg. 115
- Charts comparing stages

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Nutrition - Significance of photosynthesis in nature

By the end of the lesson, the learner should be able to:

- Explain the importance of photosynthesis to plants, animals and the environment
- Discuss how photosynthesis ensures food security in the community
- Connect photosynthesis to combating global warming through tree planting and forest conservation

- Discuss the importance of photosynthesis to plants (food production, energy), animals (oxygen, food chains) and the environment (carbon (IV) oxide removal)
- Explain how photosynthesis helps solve global warming by removing carbon (IV) oxide from the atmosphere
- Discuss how photosynthesis ensures food security

How does photosynthesis benefit both plants and animals?

- Distinction Biology Learner's Book Grade 10 pg. 118
- Digital resources
- Charts on importance of photosynthesis

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Nutrition - Other products of photosynthesis

By the end of the lesson, the learner should be able to:

- Identify other products of photosynthesis apart from glucose (fatty acids, amino acids)
- Explain the conversion of glucose to starch, fats and proteins in plants
- Relate how plants convert photosynthesis products into nutrients found in everyday foods like beans, avocados and maize

- Discuss how glucose formed during photosynthesis is converted to starch for storage
- Explain the formation of fatty acids (combined to form fats and oils) and amino acids (converted to proteins)
- Search for information on other products of photosynthesis using reference materials

What other substances do plants produce during photosynthesis besides glucose?

- Distinction Biology Learner's Book Grade 10 pg. 117
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Nutrition - Other products of photosynthesis

By the end of the lesson, the learner should be able to:

- Identify other products of photosynthesis apart from glucose (fatty acids, amino acids)
- Explain the conversion of glucose to starch, fats and proteins in plants
- Relate how plants convert photosynthesis products into nutrients found in everyday foods like beans, avocados and maize

- Discuss how glucose formed during photosynthesis is converted to starch for storage
- Explain the formation of fatty acids (combined to form fats and oils) and amino acids (converted to proteins)
- Search for information on other products of photosynthesis using reference materials

What other substances do plants produce during photosynthesis besides glucose?

- Distinction Biology Learner's Book Grade 10 pg. 117
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Nutrition - Assessment and review on nutrition in plants
Transport - External structures of the plant transport system

By the end of the lesson, the learner should be able to:

- Answer questions on types of nutrition, chloroplast structure and photosynthesis
- Illustrate the stages of photosynthesis correctly
- Value the role of photosynthesis in sustaining life on earth by discussing real-life examples like oxygen production and food chains

- State the external parts of a plant that form the transport system (roots, stems, leaves)
- Identify the substances transported by each external part
- Relate the transport system in plants to how water reaches the topmost leaves of tall trees in the local environment

- Answer assessment exercise questions on nutrition in plants
- Draw and label the chloroplast and identify parts where light and dark stages occur
- Discuss the mode of nutrition shown in given pictures (e.g., mould growing on bread)
- Discuss the structures of external parts of a plant in relation to their transport functions
- Identify substances transported within the plant (water, mineral salts, food substances and waste products)
- Search for information on the external structures of plants that transport substances

How do the different types of nutrition and photosynthesis sustain plant life?
What external structures make up the transport system in plants?

- Distinction Biology Learner's Book Grade 10 pg. 119
- Digital resources
- Past assessment questions
- Distinction Biology Learner's Book Grade 10 pg. 120
- Digital resources
- Fresh plant specimens

- Written tests - Oral questions - Observation
- Oral questions - Observation - Written assignments

Anatomy and Physiology of Plants

Transport - Structure and function of roots in transport
Transport - Internal structure of the root (transverse section)

By the end of the lesson, the learner should be able to:

- Describe the regions of the root (cell division, elongation and differentiation)
- Relate the structure of the root to its function in absorption and transport
- Explain why seedlings with damaged root hairs wilt faster than those with intact roots

- Study the longitudinal section of a dicotyledonous root and identify regions of cell division, elongation and differentiation
- Discuss how root hairs increase the surface area for absorption of water and mineral salts
- Draw and label the longitudinal section of a root

How is the root adapted to absorb water and mineral salts?

- Distinction Biology Learner's Book Grade 10 pg. 121
- Digital resources
- Charts of root structure
- Distinction Biology Learner's Book Grade 10 pg. 123
- Charts/photomicrographs of root cross-sections

- Oral questions - Observation - Written assignments

Anatomy and Physiology of Plants

Transport - Structure and function of stems in transport
Transport - Structure and function of leaves in transport

By the end of the lesson, the learner should be able to:

- Describe the internal structure of the stem (epidermis, cortex, pith, vascular tissues)
- Relate the structure of the stem to its transport function
- Connect the waxy cuticle on stems to why some plant stems feel smooth and resist water loss

- Study cross-sectional drawings of monocotyledonous and dicotyledonous stems
- Identify the epidermis, cortex (parenchyma, collenchyma, sclerenchyma), pith and vascular tissues
- Discuss the functions of the stem as part of the transport system

How does the structure of the stem support its transport function?

- Distinction Biology Learner's Book Grade 10 pg. 125
- Digital resources
- Fresh plant stems
- Charts of stem cross-sections
- Distinction Biology Learner's Book Grade 10 pg. 127
- Fresh plant leaves

- Oral questions - Observation - Written assignments

Anatomy and Physiology of Plants

Transport - Structure, functions and adaptations of xylem vessels

By the end of the lesson, the learner should be able to:

- Describe the structure and adaptations of xylem vessels and tracheids
- Explain how xylem vessels are adapted to transport water and mineral salts
- Relate the lignin deposits in xylem walls to why woody stems are rigid and do not collapse easily

- Study diagrams of xylem vessels and tracheids and discuss their structure
- Discuss the adaptations of xylem to its function (continuous tube, lignified walls, pits, dead cells)
- Search for information on the structure and adaptations of xylem vessels

How are xylem vessels adapted to transport water in plants?

- Distinction Biology Learner's Book Grade 10 pg. 129
- Digital resources
- Charts/diagrams of xylem vessels

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Transport - Structure, functions and adaptations of phloem tissue
Transport - Arrangement of vascular tissues in roots of monocots and dicots (Practical)
Transport - Arrangement of vascular tissues in stems of monocots and dicots (Practical)

By the end of the lesson, the learner should be able to:

- Describe the structure and adaptations of phloem tissue (sieve tubes, companion cells, sieve pores)
- Explain how phloem is adapted to transport manufactured food
- Explain why ringing the bark of a fruit tree causes fruits above the ring to become sweeter due to sugar accumulation

- Observe and draw cross-sections of monocotyledonous and dicotyledonous stems under a microscope
- Compare the arrangement of vascular tissues in stems of monocots and dicots
- Collect plant specimens responsibly without destroying other plants in the environment

- Study diagrams of the phloem tissue and identify sieve tubes, companion cells, sieve pores and plasmodesmata
- Discuss the adaptations of phloem to its function (living cells, mitochondria in companion cells, sieve pores)
- Compare the structure of xylem and phloem tissues
- Cut thin cross-sections of monocotyledonous and dicotyledonous stems, stain and observe under a microscope
- Draw well-labelled cross-sectional drawings of monocot and dicot stems
- Outline the similarities and differences of vascular tissues in stems of monocots and dicots

How is the phloem adapted to transport manufactured food in plants?
How does the arrangement of vascular tissues differ in stems of monocots and dicots?

- Distinction Biology Learner's Book Grade 10 pg. 131
- Digital resources
- Charts/diagrams of phloem tissue
- Distinction Biology Learner's Book Grade 10 pg. 133
- Light microscope
- Fresh plant roots
- Iodine solution, scalpel, glass slides, cover slips
- Distinction Biology Learner's Book Grade 10 pg. 135
- Light microscope
- Fresh plant stems
- Iodine solution, scalpel, glass slides, cover slips

- Oral questions - Written assignments - Observation
- Observation - Practical assessment - Written assignments

Anatomy and Physiology of Plants

Transport - Mechanisms of water uptake in plants (osmosis and active transport)

By the end of the lesson, the learner should be able to:

- Describe the mechanisms of water uptake in plants (osmosis, active transport)
- Explain how water moves from soil particles to the xylem vessels in the root
- Relate osmosis in root hair cells to why plants wilt when placed in very salty soil

- Search for information on mechanisms of water and mineral salt uptake in plants
- Study diagrams showing the absorption of water by plant roots
- Discuss how water moves from the soil particles through the root hair cells to the xylem vessels by osmosis

How does water move from the soil into the root of a plant?

- Distinction Biology Learner's Book Grade 10 pg. 137
- Digital resources
- Charts showing water absorption in plants

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Transport - Movement of water up the plant (transpiration pull, cohesion, adhesion, capillarity, root pressure)

By the end of the lesson, the learner should be able to:

- Explain the forces that move water up the plant (transpiration pull, cohesion, adhesion, capillarity and root pressure)
- Describe how each force contributes to the upward movement of water
- Relate capillary action in xylem vessels to how water moves up a piece of cloth dipped in water

- Discuss transpiration pull, cohesion forces, adhesion forces, capillarity and root pressure
- Watch animations on the uptake of water and mineral salts in plants
- Explain how exudation and guttation occur in plants

What forces enable water to move from the roots to the leaves against gravity?

- Distinction Biology Learner's Book Grade 10 pg. 139
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Transport - Movement of water up the plant (transpiration pull, cohesion, adhesion, capillarity, root pressure)

By the end of the lesson, the learner should be able to:

- Explain the forces that move water up the plant (transpiration pull, cohesion, adhesion, capillarity and root pressure)
- Describe how each force contributes to the upward movement of water
- Relate capillary action in xylem vessels to how water moves up a piece of cloth dipped in water

- Discuss transpiration pull, cohesion forces, adhesion forces, capillarity and root pressure
- Watch animations on the uptake of water and mineral salts in plants
- Explain how exudation and guttation occur in plants

What forces enable water to move from the roots to the leaves against gravity?

- Distinction Biology Learner's Book Grade 10 pg. 139
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Transport - Absorption of mineral salts and demonstrating water uptake (Practical)
Transport - The process of transpiration

By the end of the lesson, the learner should be able to:

- Explain the mechanism of mineral salt absorption (active transport and diffusion)
- Carry out an experiment to demonstrate uptake of water in plants using dye/ink
- Handle chemicals like food colouring safely and dispose of waste materials responsibly after the experiment

- Define transpiration and describe how it occurs through the stomata
- Relate the internal structure of the leaf to the process of transpiration
- Explain why clothes dry faster on a sunny windy day, linking it to how transpiration increases under similar conditions

- Discuss how mineral salts are absorbed by active transport and diffusion
- Carry out a dye/ink experiment to demonstrate uptake of water in plants
- Observe exudation and guttation in the experimental set-up and draw conclusions
- Discuss the process of transpiration and how water vapour diffuses out through the stomata
- Study the internal structure of the leaf and relate it to transpiration (spongy mesophyll, sub-stomatal air spaces, guard cells)
- Discuss the role of guard cells in controlling the opening and closing of stomata

How are mineral salts absorbed by plant roots?
How does transpiration occur in plant leaves?

- Distinction Biology Learner's Book Grade 10 pg. 141
- Fresh young plants
- Food colouring/ink
- Glass beaker, scalpel, distilled water
- Distinction Biology Learner's Book Grade 10 pg. 143
- Digital resources
- Charts of leaf internal structure

- Practical assessment - Observation - Written assignments
- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Transport - Structural factors affecting the rate of transpiration

By the end of the lesson, the learner should be able to:

- Describe the structural factors that affect the rate of transpiration (leaf size, leaf surface, number and position of stomata, leaf hairs)
- Explain how each structural factor affects transpiration rate
- Explain why cactus plants survive in arid areas by relating their leaf structure to reduced water loss

- Discuss structural factors affecting the rate of transpiration (broad lamina, glossy surface, number of stomata, sunken stomata, leaf hairs)
- Explain midday closure and reversed stomatal rhythm
- Search for information on structural factors using available reference materials

How do leaf structures influence the rate of water loss in plants?

- Distinction Biology Learner's Book Grade 10 pg. 145
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Transport - Environmental factors affecting the rate of transpiration (Temperature and light intensity practicals)

By the end of the lesson, the learner should be able to:

- Carry out experiments to demonstrate the effect of temperature and light intensity on transpiration
- Explain how temperature and light intensity affect the rate of transpiration
- Set up a control experiment and explain its purpose in ensuring valid results

- Carry out an experiment using a heat bulb to demonstrate the effect of temperature on transpiration
- Carry out an experiment using a light bulb to demonstrate the effect of light intensity on transpiration
- Compare condensation on plastic bottles/carrier bags in both experiments and draw conclusions

How do temperature and light intensity affect the rate of transpiration?

- Distinction Biology Learner's Book Grade 10 pg. 147
- Potted plants
- Heat bulb, light bulb
- Transparent carrier bags, elastic bands

- Practical assessment - Observation - Written assignments

Anatomy and Physiology of Plants

Transport - Environmental factors affecting the rate of transpiration (Temperature and light intensity practicals)
Transport - Environmental factors affecting the rate of transpiration (Wind practical and other factors)

By the end of the lesson, the learner should be able to:

- Carry out experiments to demonstrate the effect of temperature and light intensity on transpiration
- Explain how temperature and light intensity affect the rate of transpiration
- Set up a control experiment and explain its purpose in ensuring valid results

- Carry out an experiment to demonstrate the effect of wind on transpiration
- Describe how humidity, atmospheric pressure and water availability affect transpiration
- Improvise a fan from locally available materials, demonstrating creativity and resourcefulness

- Carry out an experiment using a heat bulb to demonstrate the effect of temperature on transpiration
- Carry out an experiment using a light bulb to demonstrate the effect of light intensity on transpiration
- Compare condensation on plastic bottles/carrier bags in both experiments and draw conclusions
- Carry out an experiment using an improvised fan to demonstrate the effect of wind on transpiration
- Discuss how humidity, atmospheric pressure and water availability in the soil affect the rate of transpiration
- Compare water droplets on carrier bags of potted plants near and far from the fan

How do temperature and light intensity affect the rate of transpiration?
How do wind, humidity and water availability affect the rate of transpiration?

- Distinction Biology Learner's Book Grade 10 pg. 147
- Potted plants
- Heat bulb, light bulb
- Transparent carrier bags, elastic bands
- Distinction Biology Learner's Book Grade 10 pg. 149
- Potted plants
- Improvised fan materials
- Transparent carrier bags, elastic bands

- Practical assessment - Observation - Written assignments

Anatomy and Physiology of Plants

Transport - Translocation of manufactured food in plants

By the end of the lesson, the learner should be able to:

- Define translocation and describe the process in plants
- Identify the materials transported during translocation (sucrose, amino acids, vitamins)
- Relate translocation to why fruits, roots and seeds store food, as seen in everyday crops like sugarcane and sweet potatoes

- Discuss the process of translocation of manufactured food from the leaves to other parts of the plant
- Watch animations on translocation and share with peers
- Identify the vascular tissues (phloem) involved in translocation

How is manufactured food transported from the leaves to other parts of the plant?

- Distinction Biology Learner's Book Grade 10 pg. 151
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Transport - Demonstrating translocation by bark ringing and significance of transport in plants

By the end of the lesson, the learner should be able to:

- Carry out a bark ringing (girdling) experiment to demonstrate translocation
- Explain the importance of transport in plants
- Carry out bark ringing responsibly without destroying the entire plant, showing care for the environment

- Carry out a bark ringing/girdling experiment on a young tree to demonstrate translocation
- Observe the swelling above the ring and wilting below and draw conclusions
- Discuss the importance of transport in plants (distribution of nutrients, removal of waste products)

What evidence confirms translocation of food in plants?

- Distinction Biology Learner's Book Grade 10 pg. 153
- Young tree/woody plant
- Knife, permanent marker pen
- Digital device for recording

- Practical assessment - Observation - Written assignments

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Meaning and significance of gaseous exchange in plants

By the end of the lesson, the learner should be able to:

- Define gaseous exchange in plants
- Explain the significance of gaseous exchange to plants and the environment
- Relate gaseous exchange to why indoor plants help improve air quality in homes and classrooms

- Search for information on the meaning of gaseous exchange and discuss with peers
- Identify the respiratory gases (oxygen and carbon (IV) oxide) and their movement during the day and at night
- Discuss the significance of gaseous exchange to plants (photosynthesis, respiration, transpiration) and the environment (balance of atmospheric gases, air purification)

Why is gaseous exchange important to plants and the environment?

- Distinction Biology Learner's Book Grade 10 pg. 151
- Digital resources
- Internet access

- Oral questions - Observation - Written assignments

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Stomata as a site for gaseous exchange (Practical)
Gaseous Exchange and Respiration - Distribution of stomata in different plant habitats
Gaseous Exchange and Respiration - Lenticels as gaseous exchange sites in stems

By the end of the lesson, the learner should be able to:

- Observe stomata in leaves using a microscope
- Describe the structure of stomata and guard cells
- Handle microscope slides and nail polish carefully, disposing of waste materials appropriately after the practical

- Describe the structure and adaptations of lenticels for gaseous exchange
- Explain the mechanism of gaseous exchange through lenticels
- Relate lenticels to the small raised spots visible on the bark of woody plants like hibiscus or guava trees

- Apply clear nail polish on the lower surface of a leaf, peel off after drying and observe under a microscope
- Identify stomata and guard cells under the microscope
- Discuss the structure of guard cells (thin elastic outer walls, thick inner walls) and how they control the opening and closing of stomata
- Study photomicrographs of lenticels and discuss their structure (loosely packed cork cells, thin film of moisture)
- Discuss how lenticels carry out gaseous exchange continuously
- Explain the mechanism of gaseous exchange through lenticels (diffusion of oxygen in and carbon (IV) oxide out)

What is the structure of stomata and how are they adapted for gaseous exchange?
How do lenticels facilitate gaseous exchange in woody stems?

- Distinction Biology Learner's Book Grade 10 pg. 155
- Fresh plant leaves
- Clear nail polish
- Light microscope, glass slides, cover slips
- Distinction Biology Learner's Book Grade 10 pg. 157
- Fresh leaf samples from different habitats
- Light microscope, nail polish
- Glass slides, cover slips
- Distinction Biology Learner's Book Grade 10 pg. 161
- Photomicrographs of lenticels
- Digital resources

- Practical assessment - Observation - Written assignments
- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Pneumatophores as gaseous exchange sites in roots
Gaseous Exchange and Respiration - Photosynthetic theory of stomatal opening and closing

By the end of the lesson, the learner should be able to:

- Describe the structure and adaptations of pneumatophores for gaseous exchange
- Explain the mechanism of gaseous exchange through pneumatophores
- Relate pneumatophores to the visible breathing roots of mangrove trees growing in swampy areas along the Kenyan coast

- Study photographs/diagrams of pneumatophores and discuss their structure (lenticels, aerenchyma tissues)
- Discuss how pneumatophores grow above the water level to obtain oxygen from the atmosphere
- Explain the role of aerenchyma tissues in storing air for gaseous exchange

How do plants in waterlogged areas carry out gaseous exchange?

- Distinction Biology Learner's Book Grade 10 pg. 163
- Photomicrographs/pictures of pneumatophores
- Digital resources
- Distinction Biology Learner's Book Grade 10 pg. 165
- Digital resources
- Charts showing open and closed stomata

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Starch-sugar inter-conversion theory

By the end of the lesson, the learner should be able to:

- Describe the mechanism of opening and closing of stomata using the starch-sugar inter-conversion theory
- Explain the role of pH in the conversion of starch to glucose and vice versa
- Connect how changes in carbon (IV) oxide levels during day and night trigger a chain reaction that opens or closes stomata

- Discuss how during the day, carbon (IV) oxide is used for photosynthesis causing pH to rise favouring conversion of starch to glucose
- Explain how glucose increases osmotic pressure of guard cells causing water uptake and stomata to open
- Discuss the reverse process at night when carbon (IV) oxide accumulates lowering pH

How does the conversion between starch and sugar control stomatal opening?

- Distinction Biology Learner's Book Grade 10 pg. 167
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Potassium ion theory of stomatal opening and closing
Gaseous Exchange and Respiration - The process of respiration and aerobic respiration

By the end of the lesson, the learner should be able to:

- Describe the mechanism of opening and closing of stomata using the potassium ion theory
- Compare the three theories of stomatal opening and closing
- Explain how understanding stomatal mechanisms helps farmers manage irrigation and crop water needs more effectively

- Discuss the potassium ion theory explaining the mechanism of opening and closing of stomata
- Watch animations showing the mechanism of opening and closing of stomata and discuss with peers
- Compare the photosynthetic theory, starch-sugar inter-conversion theory and potassium ion theory

How do potassium ions influence the opening and closing of stomata?

- Distinction Biology Learner's Book Grade 10 pg. 168
- Digital resources
- Internet access
- Charts comparing the three theories
- Distinction Biology Learner's Book Grade 10 pg. 169
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Anaerobic respiration in plants

By the end of the lesson, the learner should be able to:

- Define anaerobic respiration and state its word equation
- Distinguish between aerobic and anaerobic respiration
- Relate anaerobic respiration to the production of alcohol in local brewing and the rising of bread dough during baking

- Discuss anaerobic respiration as the breakdown of glucose in the absence of oxygen producing ethanol, carbon (IV) oxide and less energy
- Compare aerobic and anaerobic respiration in terms of oxygen requirement, energy released and products
- Discuss where anaerobic respiration occurs in plants (waterlogged areas, germinating seeds)

How does anaerobic respiration differ from aerobic respiration?

- Distinction Biology Learner's Book Grade 10 pg. 171
- Digital resources
- Internet access

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Investigating aerobic and anaerobic respiration (Practical)

By the end of the lesson, the learner should be able to:

- Carry out experiments to distinguish between aerobic and anaerobic respiration
- Explain the role of calcium hydroxide solution and paraffin in the experiments
- Observe safety precautions when handling chemicals and dispose of waste materials appropriately after the experiment

- Set up experiments using germinating bean seeds to demonstrate aerobic respiration (test tube A) and boiled bean seeds to demonstrate anaerobic respiration (test tube B)
- Observe the colour change of calcium hydroxide solution and record temperature readings
- Discuss the role of paraffin in blocking oxygen entry

How can aerobic and anaerobic respiration be demonstrated experimentally?

- Distinction Biology Learner's Book Grade 10 pg. 172
- Germinating and boiled bean seeds
- Test tubes, delivery tubes, rubber stoppers
- Calcium hydroxide solution, paraffin, glucose solution

- Practical assessment - Observation - Written assignments

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Economic importance of anaerobic respiration

By the end of the lesson, the learner should be able to:

- Explain the economic importance of anaerobic respiration in various industries
- Describe how anaerobic respiration is applied in brewing, baking, dairy and biogas production
- Relate anaerobic respiration to locally made products like yoghurt, cheese, bread and traditional fermented drinks

- Discuss the economic importance of anaerobic respiration in brewing, baking, biogas production, dairy industry, sewage treatment, silage formation, pharmaceutical industry and compost manure production
- Explain how yeast breaks down sugars anaerobically in brewing and baking
- Discuss how bacteria produce lactic acid in dairy products

How is anaerobic respiration applied in everyday industries and products?

- Distinction Biology Learner's Book Grade 10 pg. 174
- Digital resources
- Charts showing applications of anaerobic respiration

- Oral questions - Written assignments - Observation

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Biogas production project

By the end of the lesson, the learner should be able to:

- Demonstrate anaerobic respiration through a biogas production project
- Describe the procedure and observations in biogas production
- Relate biogas production to waste management and renewable energy solutions in rural Kenyan communities

- Set up a simple biogas digester using organic waste and water in a sealed container
- Observe balloon inflation over 5-7 days as biogas is produced
- Test the collected gas by bringing it near a flame and observing the blue flame

How can anaerobic respiration be harnessed for biogas production?

- Distinction Biology Learner's Book Grade 10 pg. 175
- Large plastic bottle/container
- Organic waste, water
- Rubber tubing, balloon, tape

- Project assessment - Observation - Written report

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Significance of gaseous exchange and respiration to plants and the environment

By the end of the lesson, the learner should be able to:

- Outline the significance of gaseous exchange and respiration to plants and the environment
- Design a portfolio illustrating the significance of gaseous exchange and respiration
- Relate the significance of gaseous exchange to why deforestation contributes to climate change and why reforestation is encouraged

- Discuss the significance of gaseous exchange and respiration to plants (energy production, growth, photosynthesis) and the environment (oxygen supply, carbon cycling, temperature regulation)
- Design a portfolio illustrating the significance of gaseous exchange and respiration
- Show portfolios to peers for assessment

How do gaseous exchange and respiration contribute to the survival of plants and the environment?

- Distinction Biology Learner's Book Grade 10 pg. 177
- Digital resources
- Portfolio materials

- Portfolio assessment - Oral questions - Observation

Anatomy and Physiology of Plants

Gaseous Exchange and Respiration - Assessment and review on gaseous exchange and respiration

By the end of the lesson, the learner should be able to:

- Answer assessment questions on gaseous exchange sites, stomatal mechanisms, types of respiration and economic importance of anaerobic respiration
- Distinguish between gaseous exchange and respiration in plants
- Connect the concepts learned to real-life applications such as food preservation, energy production and environmental conservation

- Answer assessment exercise questions on gaseous exchange and respiration
- Distinguish between gaseous exchange and respiration
- Identify and explain adaptations of gaseous exchange structures (stomata, lenticels, pneumatophores, aerenchyma)
- Describe mechanisms of opening and closing of stomata using the three theories

How are gaseous exchange and respiration essential to the survival of plants?

- Distinction Biology Learner's Book Grade 10 pg. 178
- Digital resources
- Past assessment questions

- Written tests - Oral questions - Observation