Unit B Scofield Reset

Question 1

B1,1

3 Properties of carbon allowing chemical diversity

Answer 1

• Carbon forms covalent bonds
• Carbon forms up to 4 single bonds, or combination of bonds
• Forms straight/branched chains or single/multiple rings

Question 2

B1.1

4 Properties of monosaccharides

Answer 2

• Solubility
• Transportability
• Chemical stability
• Oxidation yields energy

Question 3

B1.1

4 Properties of glucose

Answer 3

• Solubility – dissolves in water as it is polar
• Transportability – dissolves in blood plasma
• Chemical stability – cyclic molecule with -OH in axial region
• Oxidation yields energy – respiration releases energy

Question 4

B1.1

4 Forms of storage of glucose

Answer 4

• Amylose (eg. potatoes) – linear starch chain linked by a-1,4-glycosidic bonds
• Amylopectin (main component) (eg. corn) – starch chain linked by a-1,4-glycosidic bonds, with branches joined by a-1,6-glycosidic bonds every 24-30 units
• Cellulose – linear chain linked by b-1,4-glycosidic bonds, cross-linked by H-bonds and bundled into microfibrils
• Glycogen – chain linked by a-1,4-glycosidic bonds, with branches joined by a-1,6-glycosidic bonds every 8-12 units

Question 5

B1.1

4 Functions of glycoproteins

Answer 5

• Cell-cell recognition
• Receptors
• Ligands
• Structural support

eg. ABO blood antigens

Question 6

B1.1

3 differences in properties of saturated/unsaturated lipids

Answer 6

• Solid/liquid at RTP
• High/low viscosity
• High/low melting point

Question 7

B1.1

Storage of fats in plants and endotherms

Answer 7

• Plants – unsaturated fats and oils in seeds for germination
• Endotherms – liquid droplets in adipocytes for respiration

Question 8

B1.2

7 Functions of proteins with examples

Answer 8

• structure (macro/micro) –- collagen/histone
• transport (extra/inter/intracellular) –- haemoglobin/ channel protein
• enzyme –- lysozyme
• movement –- actin / tubulin
• hormones –- insulin
• antibodies –- immunoglobulin
• storage –- albumin

Question 9

B1.2

4 examples of types of R-group

Answer 9

• Acidic – aspartic acid
• Basic – lysine
• Polar – serine
• Non-polar – alanine

Question 10

B1.2

Origins of H-bonds, S-bonds and ionic bonds in proteins

Answer 10

• H-bonds – between polar hydrophilic R-groups
• S-bonds – between cysteine residues
• ionic bonds – between NH2 or C=O charged by binding/dissociation of H+, and charged R-groups

Question 11

B1.2

Levels of Polypeptide Structure

Answer 11

Primary Structure - sequence of amino acids, linked by peptide bonds
Secondary Structure – local folding of peptides into a-helices or b-pleated sheets
Tertiary Structure - folding of polypeptide via H-/S-/ionic bonds
Quaternary Structure - arrangement and interaction of two or more polypeptide chains to form a functional protein

Question 12

B1.2

Conjugation in Haemoglobin, Insulin and Collagen

Answer 12

• Haemoglobin – tetramer with haem groups and iron
• Insulin – non-conjugated dimer
• Collagen – non-conjugated trimer

Question 13

B1.2

4 Properties of Globular Proteins

Answer 13

• Tertiary structure, often spherical in shape
• Water-soluble
• High pH/temperature sensitivity
• Function as enzymes, transporters, regulators

eg. Insulin has a hydrophilic exterior to be transported in blood plasma, but a hydrophobic core to be chemically stable

Question 14

B1.2

4 Properties of Fibrous Proteins

Answer 14

• Secondary structure, often linear or long in shape
• Water-insoluble
• Low pH/temperature senstivity
• Function as structural support and stabilisation

eg. Collagen is made of 3 twisted H-bonded polypeptides containing glycine, proline, and hydroxyproline

Question 15

B2.1

7 Point Explanation of Cholesterol Effect on Membrane Fluidity

Answer 15

1. Polar group faces aqueous external environment
2. Non-polar regions face interior of bilayer
3. Rigid steroid structure strongly interacts with phospholipids
4. Increases fluidity at low temperature by interfering with packing of fatty acid chain
5. Decreases fluidity at high temperature by reducing mobility of phospholipis
6. Broadens phase transition of freezing
7. Prevents abrupt membrane fluidity changes

Question 16

B2.1

7 Point Explanation of Effect of Temperature on Fatty Acid Saturation

Answer 16

1. Unsaturated tails are kinked so are less dense and have lower melting point
2. At low temperature, less saturation to prevent membrane solidification
3. Membrane fluidity needed for protein function
4. Saturated tails are straight, so can be more tightly packed leading to higher melting point
5. At high temperature, more saturation to strengthen membrane
6. To maintain appropriate membrane fluidity
7. Eg. cold-blooded organisms and hibernating animals

Question 17

B2.1

Example of ligand-gated channel in a neuron (3)

Answer 17

Nicotinic acetylcholine receptors

1. Postsynaptic receptors have acetylcholine/nicotine binding site
2. Binding causes a reversible conformational change allowing inward facilitated diffusion of 5 sodium ions
3. Influx of sodium depolarises membrane, helping to generate the action potential

Question 18

B2.1

Example of voltage-gated channel in a neuron (3)

Answer 18

Sodium/Potassium channels

1. Ball-and-chain mechanism controls opening of the membrane
2. Voltage change causes a conformational change in the pore, causing the ball to detach allowing sodium influx/potassium efflux
3. Influx of sodium depolarises membrane, potassium efflux repolarises membrane

Question 19

B2.1

Example of direct active transport (5)

Answer 19

Sodium-Potassium Pump

1. Pump is open to inside of cell. Sodium ions bind to 3 binding sites
2. Binding triggers ATP hydrolysis. Pi binds to pump, causing a conformational change.
3. Pump is open to outside of cell. Potassium ions bind to 2 binding sites.
4. Bindings triggers release of Pi from pump, causing a conformational change.
5. Bidirectional active transport builds a high Na+ concentration outside and high K+ concentration inside the cell to reestablish membrane potential after hyperpolarisation.

Question 20

B2.1

4 Point Explanation of Role of Phospholipids in Plasma Membrane

Answer 20

• hydrophilic phosphate faces aqueous external environment
• hydrophobic fatty acids face each other forming core
• low permeability to large or charged species
• effective patrtial permeability

Question 21

B2.1

5 Functions of Proteins in Membranes

Answer 21

• Facilitated diffusion and Active transport
• Cell recognition
• Cell adhesion
• Chemical reception
• Enzymes

Question 22

B2.1

3 Functions of glycocalyx

Answer 22

• Cell recognition
• Cell adhesion
• Cell signalling

Question 23

B2.1

Role of aquaporins in transport of water (3)

Answer 23

1. Aquaporins are tetramers of water channels with hydrophilic R-groups
2. Hydrophilic R-groups attract polar H2O by hydrogen bonds
3. H2O molecules bidrectionally pass through each channel in single file

Question 24

B2.1

5 Point Explanation of Function of Endocytosis and Exocytosis

Answer 24

1. Endocytosis - formation of vesicles by inward pinching of membrane
2. Exocytosis - fusion of vesicles with membrane
3. Possible due to strength and fluidity of fluid mosaic membrane
4. Energy needed in form of ATP to transport vesicles
5. Eg. phagocytosis; and synaptic transmission

Question 25

# B2.2 Advantage of separating nuclei and cytoplasm

Answer 25

- Separation of transcription and translation allows post-transcriptional modification, leading to more chemical diversity

Question 26

# B2.2 3 Adaptations of mitochondria

Answer 26

- Double membrane with small intermembrane space - Large surface area of cristae - Compartmentalisation of enzymes and substrates of Krebs cycle in matrix

Question 27

# B2.2 3 Adaptations of chloroplasts

Answer 27

- Small volume of fluid inside thylakoids - Large surface area of thylakoid membrane - Compartmentalisation of enzymes and substrates of Calvin cycle in stroma

Question 28

# B2.2 4 Point Explanation of Significance of Compartmentalisation

Answer 28

* Organelles have specific function * Compartmentalisation separates incompatible reactions * Compartmentalisation allows correct concentration of metabolites * eg. hydrolytic enzymes in lysosomes and phagocytic vacuoles are acidic. Compartmentalisation separates the enzymes from neutral cytoplasm to prevent them from denaturing/ hydrolysing essential cellular components

Question 29

# B2.2 3 Functions of Nuclear Membrane

Answer 29

* Protect DNA from reactions in cytoplasm * Inner membrane controls transport of transcription factors through nuclear pores * Separates transcription and translation, post-transcriptional modification creates protein variants

Question 30

# B2.2 2 Point Explanation of Function of Nuclear Pore

Answer 30

1. Protein-lined channel in nuclear envelope 2. Regulate transport of folded proteins, transcription factors and ribosomal components

Question 31

# B2.2 [Kognity] 3 components of Golgi apparatus

Answer 31

- cis: receive proteins from rER - medial: modify proteins - trans: package proteins into vesicles for transport

Question 32

# B2.2 [exam question] 6 Adaptations of Organelles

Answer 32

* Nuclear pore allows mRNA to travel for translation * Free ribosomes synthesise proteins for intracellular use * rER ribosomes synthesise proteins for extracellular use * Folded mitochondrial cristae surface area for oxidative phosphorylation * Folded chloroplast membrane increases surface area for light-dependent reaction * Range of pigments absorbs light for photosynthesis

Question 33

# B2.2 [exam question] 3 Point Explanation for Polysome Function

Answer 33

1. Polysomes are ribosomes translating same mRNA 2. Polysomes simultaneously produce multiples copies of same protein 3. Cell needs multiple copies of particular protein

Question 34

# B2.2 Role of clathrin in vesicle formation (3)

Answer 34

1. As the membrane invaginates, clathrin polymerises into a clathrin-coated pit 2. Brings together cytoskeleton for budding and scission of vesicles/endosomes 3. Clathrin coat is hydrolysed and reused

Question 35

# B2.3 [exam question] 4 Point Explanation for Effect of Size on Heat Loss

Answer 35

* large organisms have low SA:V ratio * limited heat loss by radiation * small organisms have high SA:V ration * significant heat loss by radiation

Question 36

# B2.3 5 Properties of Stem Cells

Answer 36

* Undifferentiated * Capable of self-renewal * Found in all multicellular organisms * Only few adult cells retain stem cell properties * Potency: Unipotent, multipotent, pluripotent, totipotent

Question 37

# B2.3 5 Point Explanation of Morphogen Function

Answer 37

1. Variation in cell-signalling morphogen concentration in cells of an early embryo 1. Morphogens diffuse out from the morphogen-producing cell, producing a gradient 1. Developing cells regulate gene expression based on their distance from the cell 1. Gene expression determines the direction and extent of growth of tissue 1. Eg. length of digits, location of nose

Question 38

# B2.2 2 Examples of stem cell niches in adults

Answer 38

- Bone marrow: stem cells differentiate by haematopoeisis, and are maintained by supportive cells - Hair follicles: bulge stem cells proliferate into new hair cells | Bulge stem cells are the name for stem cells in hair follicles

Question 39

# B2.2 4 Adaptions to raise SA:V ratio with examples

Answer 39

- Small size -- prokaryotes - Flattening -- simple squamous epithelium of PCT and alveolar membranes - Microvilli -- enterocytes have about 600 microvilli - Invaginations -- mitochondrial cristae, microvilli

Question 40

# B2.3 Adaptation of Type I Pneumocytes

Answer 40

* **Squamous** -- reduced diffusion distance * Tight junctions -- prevent tissue fluid leaking into alveolar air space | You only need the bolded one, but for me it makes sense to mention both.

Question 41

# B2.3 Adaptation of Type II Pneumocytes

Answer 41

- Cuboidal -- contain many organelles - **Lamellar bodies** -- secrete surfactant, which reduces surface tension to prevent alveoli from collapsing | You only need the bolded one, but for me it makes sense to mention both.

Question 42

# B2.3 4 Adaptations of Cardiac Muscle

Answer 42

* Contractile myofibrils/sarcomeres -- allows contraction * Branching (by gap junctions at intercalated discs) -- synchronisation of cardiomyocytes as the electrical impulse passes through efficiently * Single nucleus -- synchronisation of cardiomyoctes * Many mitochondria -- respiration for energy

Question 43

# B2.3 4 Adaptations of Skeletal Muscle

Answer 43

- Many contractile myofibrils/sarcomeres -- allow large extent of voluntary movement - Unbranched -- enables precise control of voluntary movement - Multinucleated syncitia -- more protein synthesis and repair - Many mitochondria - respiration for energy

Question 44

# B2.3 3 Adaptaions of Ova

Answer 44

* Large cytoplasm - nutrition for zygote development * Cortical granules - prevent polyspermy via cortical reaction * Moved by cilia in fallopian tube instead of independently - conserve energy

Question 45

# B2.3 3 Adaptations of Sperm

Answer 45

* Middle piece with mitochondria - energy to travel * Acrosome - digestive enzymes facilitate acrosomal reaction * Streamlined + flagellum - swim through fluid

Question 46

# B3.1 4 Adaptations of mammalian lungs for gas exchange

Answer 46

- Surfactant - Branched network of bronchioles - Extensive capillary beds - High surface area of alveoli

Question 47

# B3.1 5 Steps of inhalation

Answer 47

1. Diaphragm contracts 2. External intercostal contracts and internal intercostal muscles relax 3. Ribcage moves up and out 4. Thoracic volume increases, pressure decreases 5. Air moves down into the lungs down the pressure gradient

Question 48

# B3.1 Factors affecting lung capacity (5)

Answer 48

- Age - Body size - Biological sex - Respiratory disease - Levels of physical activity

Question 49

# B3.1 Explain why HbF has higher oxygen affinity than HbA (3)

Answer 49

1. 2,3-BPG competes with oxygen 2. Gamma peptides have higher oxygen affinity than beta peptides 3. HbF has higher oxygen affinity than HbA at all oxygen partial pressures

Question 50

# B3.1 Bohr Shift Explanation (5)

Answer 50

1. Bohr shift is due to increased CO2 pp 2. Dissolved CO2 forms H2CO3 (or from lactic acid) 3. H2CO3 changes conformation of haemoglobin to dissociate more O2 4. Haemoglobin unloads more O2 at respiring tissues and loads more at oxygen-containing tissues 5. Bohr shift is more significant in HbA than HbF (it is more of a limiting factor in HbA)

Question 51

# B3.1 5 Properties of Gas Exchange Surfaces

Answer 51

- High surface area - Permeability - Thin tissue layer (short diffusion distance) - Moist surfaces dissolve gas (eg. surfactant) - Steep concentration gradient maintained

Question 52

# B3.1 3 Plant Adaptations for Gas Exchange

Answer 52

- Thin and flat leaves - large surface area for gas diffusion and for light - Hydrophobic waxy cuticle - reduces water loss - Air pockets in spongy mesophyll- maintain concentration gradient for CO2 and O2

Question 53

# B3.1 5 Regions of Spirometry Graph

Answer 53

- Inspiratory Reserve Volume = maximum additional volume of air that can be inhaled - Tidal Volume = fluctuation in volume of normal breathing - Expiratory Reserve Volume = maximum additional volume of air that can be exhaled - Forced Vital Capacity = total air that can be exhaled - Residual Volume = volume of air in lung which cannot be exhaled

Question 54

# B3.1 Cooperative binding of O2 to haemoglobin (4)

Answer 54

1. At low partial pressure, there are few successful collision of O2 with haem binding sties 2. When one oxygen binds, conformational changes assist binding of second and third oxygen 3. At high partial pressure, haemoglobin is highly saturated, there are few successful collisions 4. Haemoglobin loads oxygen from cells with high partial pressures and unloads into cells with low partial pressure

Question 55

# B3.2 4 Adaptations of capillaries for gas exchange

Answer 55

- Capillary branching - Narrow diameter - Capillaary walls made of flat endothelial cells - Fenestrations where need for transport is especially high (glomerulus)

Question 56

# B3.2 3 Adaptations of arteries

Answer 56

- Thick wall of elastin accommodates change in volume of blood - Thick wall of elastin reduces fluctuations in blood pressure - Smooth muscle reduces fluctuations in blood pressure by vasodilation and vasoconstriction

Question 57

# B3.2 3 Adaptations of veins

Answer 57

- Large lumen to account for low pressure - One-way valves maintain unidirectional bloodflow - Flexible walls allow skeletal muscle to compress veins, forcing blood along the vein

Question 58

# B3.2 Cardiac cycle (8)

Answer 58

1. SA node initiates contraction 2. Electrical impulse spreads out across atria, causing atrial systole 3. Non-conducting fibres between atria and ventricles prevent electrical impulse from spreading to ventricles 4. Electrical impulse reaches AV node and travels down Purkinje fibres 5. Ventricular systole occurs when Bundles of His are stimulated 6. Delay prevents simultaenous contraction of atria and ventricles 7. The heart chambers refill with blood during the refractory period 8. Medulla oblongata controls the heart rate

Question 59

# B3.2 Evapotranspiration process (4)

Answer 59

1. Transpiration is the loss of water from leaves through stomata 2. Evaporation of water vapour from stomata in leaves generates a negative pressure, drawing water upwards. 2. Due to the hydrogen bonding between polar H2O molecules, water moves up in a continuous column. 3. Adhesion of water to the xylem lignin walls also maintains the continuous stream. Adhesion additionally narrows the xylem diameter to assist with maintaining water transport.

Question 60

# B3.2 Root pressure generation (4)

Answer 60

1. Abiotic factors do not favour evapotranspiration 2. Active transport of mineral ions into root hair cells 3. Increases solute concentration reduces water potential, causing water to move in by osmosis. 4. Movement of water into the xylem generates positive hydrostatic pressure potential.

Question 61

# B3.2 4 Adaptation of Xylems

Answer 61

* Lignin - strength and waterproofness * Pit cells - movement of water between adjacent cells in xylem * Lumen has no cytoplasm - maximise water transport capacity * Absent or incomplete cell walls - unimpeded water flow

Question 62

# B3,2 Formation and Reuptake of tissue fluid (7)

Answer 62

1. Tissue fluid is a mixture of water and solutes 2. Hydrostatic pressure forces fluid out of fenestrations 3. Hydrostatic pressure is higher than osmotic pressure at the arteriole end 4. Water and glucose move into intercellular space by ultrafiltration, CO2 and waste moves into interstitial space 5. Hydrostatic pressure decreases along the capillary, and osmosis of water occurs at the venule end 6. Tissue fluid is returned to the blood plasma 7. Tissue fluid is returned to blood circulation or is redirected to lymph nodes

Question 63

# B3.2 3 Adaptations of Lymph Vessels

Answer 63

- Thin endothelial cells - Small gaps between cells allow transport - Pressure maintains unidirectional flow

Question 64

# B3.2 Advantage of double circulatory system (3)

Answer 64

1. Steeper concentration gradients 1. More efficient O2 delivery and CO2 removal 1. Supplies higher metabolic rates

Question 65

# B3.2 8 Step Process of Translocation

Answer 65

1. Bidirectional movement from source to sink 2. Sucrose is produced in leaves by photosynthesis 3. Sucrose is actively transported by the apoplast route 4. Surcrose is loaded into companion cells 5. High concentrations of solutes at the source cause uptake of water by osmosis 6. Water provides hydrostatic pressure for mass flow 7. Sucrose is unloaded / stored / used at sink 8. lowers pressure at sink / creates pressure differential / water re-entry to xylem

Question 66

# B3.2 4 Adaptations of Phloem

Answer 66

- Perforation in sieve plates - sap flows freely - Mitochondria in companion cells - active transport out of sources and into sinks - Plasmodesmata - allows transport between sieve tube elments and companion cells - Little cytoplasm and organelles in sieve tubes and anucleate - maximise phloem sap capacity

Question 67

# B3.3 5 Regions of Sarcomeres

Answer 67

* M line - organises myosin * Z disc - organises actin * H zone - myosin only * I band - actin only * A band - myosin and actin present

Question 68

# B3.3 10 Step Process of Sliding Filament Model

Answer 68

1. Action potential travels across rough sacroplasmic reticulum 2. Voltage gated Ca channels open, Ca efflux 3. Ca binding to troponin causes conformational change 4. Leaving of troponin removes tropomyosin 5. ATP hydrolysis causes myosin head to change angle, storing chemical energy as potential energy 6. Myosin forms cross-bridge with actin 7. ATP and Pi release causes power stroke towards M-line 8. Sarcomere contracts (8-10 nm) 9. ATP attaches to myosin, cross-bridge breaks 10. Repeated ATP hydrolysis supplies energy for repeated sarcomere contraction

Question 69

# B3,3 4 Functions of Titin

Answer 69

- helps the sarcomere return to its original length - adds to force of contraction - prevents overstretching, provides passive resistance to maintain structural integrity and health of muscle - holds each myosin filament in the correct position between 6 actin filaments

Question 70

# B3.3 Role of antagonistic muscle pairs (8)

Answer 70

1. Titin is a large mechanical molecular spring 1. Agonist contracts, antagonist relaxes 1. Titin is arranged in the centre of the sarcomere 1. Agonist titin is extended when antagonist sarcomeres contract 1. Antagonistic pairs are needed as muscles can exert force only during contraction 1. Titin recoils to return sarcomeres to original length, adding to the force of contraction 1. Titins stabilises the poistion of the myosin filament 1. Titin prevents overstretching

Question 71

# B3.3 5 Components of Synovial Joints

Answer 71

* Synovial Fluid - reduces friction, nourishes articular hyaline cartilage * Joint Capsule - seals synovial fluid, prevents disolocation * Articular Cartilage - reduce friction, absorb shock * Ligaments - prevents dislocation * Tendons - medium between muscle and bone

Question 72

# B3.3 4 Reasons for Locomotion

Answer 72

* Foraging * Escaping danger * Mate selection * Migration

Question 73

# B3.3 10 Adaptation of Dolphins

Answer 73

* Streamlined body shape, flippers, flukes, dorsal fin, smooth skin, even distribution of blubber - reduce drag * Blubber around organs, low SA:V ratio - reduce heat loss * Flippers - steering * Fluke - propel dolphin * Dorsal fin - prevents rolling over * Low density blubber - buoyancy * Blowhole - periodic breathing * Separated mouth and lungs - prevent water entering lungs * Large lungs, high alveoli capillary exposure, high myoglobin, high blood volume, high erythrocyte count, high haemoglobin concentration - oxygen storage and gas exchange * Blowhole - whistles and clicks as communication

Question 74

# B4.1 6 Adaptations of Marram Grass

Answer 74

* Rolled leaves with hairs * Stomata are located on the inside of the leaf * Stomata are surrounded by hairs * The inner epidermis is highly folded * Deep root system * Rhizomes (underground stems)

Question 75

# B4.1 3 Adaptations of Mangrove Plants

Answer 75

* Pneumatophores - oxygen absorption * Stilt roots - adventitious roots stabilise the tree * Propagation - underground stems act as roots

Question 76

# B4.1 Adaptations of 5 Plants to Abiotic Conditions

Answer 76

* Ferns grow large, thin leaves with high chlorophyll content. * Cacti have a thick waxy epidermis to reflect sunlight and reduce transpiration. * Tomatoes have heat shock proteins to protect against high temperatures. * Rice plants can close the stomata during droughts to reduce water loss. * Legumes have symbiotic relationships with nitrogen-fixing bacteria to gain a constant supply of nitrogen.

Question 77

# B4.1 Adaptations of 5 Animals to Abiotic Conditions

Answer 77

* Polar bears and penguins have thick fur for insulation. * Camels and kangaroo rats store water in the body. * Nocturnal animals (eg. bats, owls) avoid diurnal predators. * Herbivores have specialized teeth to digest plant tissue. * Bats and ground squirrels hibernate to conserve energy.

Question 78

# B4.1 5 Limiting Factors of Coral Reef Growth

Answer 78

* Temperature 23 - 29 C * pH 8.0 - 8.4 * Water clarity * Water salinity 30-37 ppt * Water depth 2 - 45 m

Question 79

# B4.1 Temperature, Precipitation, Sunlight, and Seasonal Variation in: Tundra Taiga Temperate Forest Grassland Tropical Forest Hot Desert

Answer 79

Tundra * -30 - 10 * 100 - 500 * High Moderate * Varied Taiga * -20 - 10 * 400 - 900 * Low Moderate * Varied Temperate Forest * 5 - 20 * 500 - 1500 * Moderate * Varied Grassland * 10 - 25 * 250 - 1000 * High * Varied Tropical Forest * 20 - 30 * 1500 - 2500 * High * Constant Hot Desert * 20 - 40 * 50 - 250 * High * Constant | Biomes are ecosystems with similar communities.

Question 80

# B4.1 3 Adaptations of Camels

Answer 80

- Thick skin and osmotic cells - Fluctuating internal body temperature - Fat-storing humps

Question 81

# B4.1 5 Adaptations of Cacti

Answer 81

- Thick waxy cuticle and epidermis - Spikes - Deep stoma, only opens at night - Large stems - Shallow roots

Question 82

# B4.1 4 Adaptations of Scorpions

Answer 82

- Slow metabolism - Water-absorbing exoskeleton - Venom and hard exoskeleton - Excretion system produces semi-solid guanine

Question 83

# B4.1 3 Adaptations of Kangaroo Rats

Answer 83

- Seed diet - Large hind legs - Nasal passage specializes in water reabsorption

Question 84

# B4.1 3 Adaptations of Pitcher Plants

Answer 84

- Bright colours and scents - Waxy internal rim - Large superior lip

Question 85

# B4.1 2 Adaptations of Flying Lizards

Answer 85

- Streamlined limbs - Patagium (elongation of thoracic limbs)

Question 86

# B4.1 3 Adaptations of Gibbons

Answer 86

- Hook-shaped hands, long arms - Long legs - Wide shoulder joints

Question 87

# B4.1 Adaptation of Orchid Mantis

Answer 87

- Camouflage against orchids

Question 88

# B4.2 Dentition and Diet in Paranthropus robustus, Homo florensis, and Homo sapiens

Answer 88

Paranthropus robustus - Large teeth with thick enamel - Wide face with large posterior chewing muscles - Mostly plant diet Homo florensis - Large flat teeth aligned anteriorly - Marks of wearing on teeth - Mostly plant diet with more meat Homo sapiens - 4 incisors, 2 canine, 4 premolars, 4 (+2) molars - Small teeth - Omnivorous diet

Question 89

# B4.2 6 Plant adaptations to resist herbivory

Answer 89

* Phytochemicals * Thick, rigid leaves with thorns and trichomes. * Aerial roots * Epiphyte behaviour (eg. orchids, strangler figs) * Large leaf surface area (shrub layer) * Camouflage

Question 90

# B4.2 2 Herbivore adaptations for feeding on plants

Answer 90

* Strong mandibles, large teeth with thick enamel layer and tooth growth. Diastema. * Insect stylets (proboscis in aphids)

Question 91

# B4.2 4 Prey adaptations for resisting predation

Answer 91

* Large field of view, small area of binocular vision, large ears * Camouflage * Defence mechanisms * Collaborative grouping behaviour

Question 92

# B4.2 4 Predator adaptations for catching prey

Answer 92

* Sharp teeth (esp. canines) and claws. * Aggressive mimicry * Sensitive hearing and olfactory organs, night vision * Toxins or venoms.

Question 93

# B4.2 3 Adaptations of plants for harvesting light (+ examples)

Answer 93

- Aerial roots - Lianas - Epiphytes - Orchids - (being a) Herb Layer Plant - Wildflowers

Question 94

# B4.2 4 Properties of Herbivore Teeth

Answer 94

Incisor - Long, flat Diastema Pre-molar - Large, flat Molar - Large, flat

Question 95

# B4.2 4 Properties of Omnivore Teeth

Answer 95

Incisor - Sharp Canine - Pointed Pre-molar - Large, flat Molar - Large, flat

Question 96

# B4.2 4 Properties of Carnivore Teeth

Answer 96

Incisor - Sharp Canine - Long, sharp Pre-molar - Sharp Molar - Large, flat